PIC16LF1782T-E/ML_技术文档

PIC16(L)F1782/3

28-Pin 8-Bit Advanced Analog Flash Microcontroller

High-Performance RISC CPU:

Extreme Low-Power Management

PIC16LF1782/3 with XLP:

• Only 49 Instructions

• Sleep mode: 50 nA @ 1.8V, typical

• Watchdog Timer: 500 nA @ 1.8V, typical

• Timer1 Oscillator: 500 nA @ 32 kHz

• Operating Current:

• Operating Speed:

- DC – 32 MHz clock input

- DC – 125 ns instruction cycle

• Interrupt Capability with Automatic Context

Saving

- 8 A @ 32 kHz, 1.8V, typical

- 32 A/MHz @ 1.8V, typical

• 16-Level Deep Hardware Stack with optional

Overflow/Underflow Reset

Analog Peripheral Features:

• Direct, Indirect and Relative Addressing modes:

• Two full 16-bit File Select Registers (FSRs)

- FSRs can read program and data memory

• Analog-to-Digital Converter (ADC):

- Fully differential 12-bit converter

- Up to 75 ksps conversion rate

- 11 single-ended channels

Memory Features:

- 5 differential channels

• Up to 4 KW Flash Program Memory:

- Self-programmable under software control

- Programmable code protection

- Programmable write protection

• 256 Bytes of Data EEPROM

- Positive and negative reference selection

• 8-bit Digital-to-Analog Converter (DAC):

- Output available externally

- Positive and negative reference selection

- Internal connections to comparators, op amps,

Fixed Voltage Reference (FVR) and ADC

• Up to 512 Bytes of RAM

• Three High-Speed Comparators:

- 50 ns response time @ VDD = 5V

- Rail-to-rail inputs

High Performance PWM Controller:

• Two Programmable Switch Mode Controller

(PSMC) modules:

- Software selectable hysteresis

- Internal connection to op amps, FVR and DAC

• Two Operational Amplifiers:

- Digital and/or analog feedback control of

PWM frequency and pulse begin/end times

- 16-bit Period, Duty Cycle and Phase

- 16 ns clock resolution

- Rail-to-rail inputs/outputs

- High/Low selectable Gain Bandwidth Product

- Internal connection to DAC and FVR

• Fixed Voltage Reference (FVR):

- Supports Single PWM, Complementary,

Push-Pull and 3-phase modes of operation

- Dead-band control with 8-bit counter

- Auto-shutdown and restart

- Leading and falling edge blanking

- Burst mode

-

1.024V, 2.048V and 4.096V output levels

- Internal connection to ADC, comparators and

DAC

I/O Features:

• 25 I/O Pins and 1 Input-only Pin:

• High current sink/source for LED drivers

• Individually programmable interrupt-on-change pins

• Individually programmable weak pull-ups

• Individual input level selection

• Individually programmable slew rate control

• Individually programmable open drain outputs

 2011-2014 Microchip Technology Inc.

DS40001579E-page 1

PIC16(L)F1782/3

Digital Peripheral Features:

General Microcontroller Features:

• Timer0: 8-Bit Timer/Counter with 8-Bit

Programmable Prescaler

• Power-Saving Sleep mode

• Power-on Reset (POR)

• Enhanced Timer1:

• Power-up Timer (PWRT)

- 16-bit timer/counter with prescaler

- External Gate Input mode

• Oscillator Start-up Timer (OST)

• Brown-out Reset (BOR) with Selectable Trip Point

• Extended Watchdog Timer (WDT)

- Dedicated low-power 32 kHz oscillator driver

• Timer2: 8-Bit Timer/Counter with 8-Bit Period

Register, Prescaler and Postscaler

• In-Circuit Serial Programming^TM(ICSP^TM

)

• In-Circuit Debug (ICD)

• Two Capture/Compare/PWM modules (CCP):

- 16-bit capture, maximum resolution 12.5 ns

- 16-bit compare, max resolution 31.25 ns

- 10-bit PWM, max frequency 32 kHz

• Enhanced Low-Voltage Programming (LVP)

• Operating Voltage Range:

- 1.8V to 3.6V (PIC16LF1782/3)

- 2.3V to 5.5V (PIC16F1782/3)

• Master Synchronous Serial Port (SSP) with SPI

and I²C^TMwith:

- 7-bit address masking

- SMBus/PMBus^TMcompatibility

• Enhanced Universal Synchronous Asynchronous

Receiver Transmitter (EUSART):

- RS-232, RS-485 and LIN compatible

- Auto-baud detect

- Auto-wake-up on start

Oscillator Features:

• Operate up to 32 MHz from Precision Internal

Oscillator:

- Factory calibrated to ±1%, typical

- Software selectable frequency range from

32 MHz to 31 kHz

• 31 kHz Low-Power Internal Oscillator

• 32.768 kHz Timer1 Oscillator:

- Available as system clock

- Low-power RTC

• External Oscillator Block with:

- 4 crystal/resonator modes up to 32 MHz

using 4x PLL

- 3 external clock modes up to 32 MHz

• 4x Phase-Locked Loop (PLL)

• Fail-Safe Clock Monitor:

- Detect and recover from external oscillator

failure

• Two-Speed Start-up:

- Minimize latency between code execution

and external oscillator start-up

DS40001579E-page 2

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

PIC16(L)F178X Family Types

Device

PIC12(L)F1782

PIC16(L)F1783

PIC16(L)F1784

PIC16(L)F1786

PIC16(L)F1787

PIC16(L)F1788

PIC16(L)F1789

(1)

(2)

2048

4096

8192

256

256 25 11

512 25 11

512 36 15

3

4

2

3

2

3

2

3

1/0

1/3

2/1

2

3

4

2

3

1

I

Y

256 1024 25 11

256 1024 36 15

(3) 16384 256 2048 25 11

(3) 16384 256 2048 36 15

Note 1: I - Debugging, Integrated on Chip; H - Debugging, available using Debug Header.

2: One pin is input-only.

Data Sheet Index: (Unshaded devices are described in this document.)

1: DS40001579

2: DS40001637

3: DS40001675

PIC16(L)F1782/3 Data Sheet, 28-Pin Flash, 8-bit Advanced Analog MCUs.

PIC16(L)F1784/6/7 Data Sheet, 28/40/44-Pin Flash, 8-bit Advanced Analog MCUs.

PIC16(L)F1788/9 Data Sheet, 28/40/44-Pin Flash, 8-bit Advanced Analog MCUs.

Note:

For other small form-factor package availability and marking information, please visit

http://www.microchip.com/packaging or contact your local sales office.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 3

PIC16(L)F1782/3

Pin Diagram – 28-Pin SPDIP, SOIC, SSOP

1

28

27

26

25

24

23

RB7/ICSPDAT

RB6/ICSPCLK

RB5

VPP/MCLR/RE3

2

RA0

3

RA1

4

RB4

RB3

RB2

RA2

5

RA3

6

RA4

7

22

21

RB1

RB0

RA5

8

VSS

20

19

18

17

16

15

9

VDD

VSS

RA7

10

11

12

RA6

RC0

RC1

RC2

RC3

RC7

RC6

RC5

RC4

13

14

Note:

See Table 1 for the location of all peripheral functions.

Pin Diagram – 28-Pin QFN, UQFN

1

2

3

4

5

6

7

21

20

19

18

17 VDD

16

15

RB3

RB2

RB1

RB0

RA2

RA3

RA4

RA5

VSS

RA7

RA6

PIC16(L)F1782/3

VSS

RC7

Note:

See Table 1 for the location of all peripheral functions.

DS40001579E-page 4

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

PIN ALLOCATION TABLE

TABLE 1:

28-PIN ALLOCATION TABLE (PIC16(L)F1782/3)

RA0

RA1

RA2

2

3

4

27 AN0

28 AN1

—

C1IN0-

C2IN0-

C3IN0-

—

IOC

Y

—

C1IN1- OPA1OUT

C2IN1-

C3IN1-

1

AN2

VREF-

C1IN0+

C2IN0+

C3IN0+

—

DACOUT1

DACVREF-

RA3

RA4

RA5

5

6

7

2

3

4

7

AN3

—

VREF+

—

C1IN1+

C1OUT

—

DACVREF+

—

T0CKI

—

IOC

Y

—

OPA1IN+

OPA1IN-

—

AN4

—

C2OUT

C2OUT⁽¹⁾

SS

—

RA6 10

—

OSC2/

CLKOUT

RA7

9

6

—

CCP1⁽¹⁾

—

IOC

Y

OSC1/

CLKIN

PSMC1CLK

PSMC2CLK

RB0 21 18 AN12

RB1 22 19 AN10

C2IN1+

INT/

IOC

—

PSMC1IN

PSMC2IN

C1IN3- OPA2OUT

C2IN3-

—

IOC

—

C3IN3-

RB2 23 20 AN8

RB3 24 21 AN9

—

OPA2IN-

OPA2IN+

—

CCP2⁽¹⁾

—

IOC

Y

CLKR

—

C1IN2-

C2IN2-

C3IN2-

RB4 25 22 AN11

RB5 26 23 AN13

—

C3IN1+

C3OUT

—

T1G

—

IOC

Y

—

SDO⁽¹⁾IOC

SDI⁽¹⁾

IOC

RB6 27 24

—

TX⁽¹⁾

ICSPCLK

CK⁽¹⁾SDA⁽¹⁾

RB7 28 25

—

DACOUT2

—

RX⁽¹⁾SCK⁽¹⁾IOC

Y

ICSPDAT

—

DT⁽¹⁾

—

SCL⁽¹⁾

—

RC0 11

RC1 12

8

9

T1OSO

T1CKI

PSMC1A

IOC

—

T1OSI

—

PSMC1B

PSMC1C

PSMC1D

CCP2

CCP1

—

IOC

Y

—

RC2 13 10

RC3 14 11

—

SCK

SCL

RC4 15 12

—

PSMC1E

—

SDI

SDA

IOC

Y

—

RC5 16 13

RC6 17 14

—

PSMC1F

PSMC2A

—

SDO

—

IOC

Y

—

TX

CK

RC7 18 15

—

PSMC2B

—

RX

DT

—

IOC

Y

—

RE3

1

26

—

MCLR/

VPP

VDD 20 17

—

VDD

VSS

VSS 8, 5,

19 16

Note 1:

Alternate pin function selected with the APFCON1 (Register 13-1) register.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 5

PIC16(L)F1782/3

Table of Contents

1.0 Device Overview .......................................................................................................................................................................... 7

2.0 Enhanced Mid-Range CPU ........................................................................................................................................................ 13

3.0 Memory Organization................................................................................................................................................................. 15

4.0 Device Configuration .................................................................................................................................................................. 40

5.0 Resets ........................................................................................................................................................................................ 46

6.0 Oscillator Module (with Fail-Safe Clock Monitor) ....................................................................................................................... 54

7.0 Reference Clock Module ............................................................................................................................................................ 72

8.0 Interrupts .................................................................................................................................................................................... 75

9.0 Power-Down Mode (Sleep) ........................................................................................................................................................ 88

10.0 Low Dropout (LDO) Voltage Regulator ...................................................................................................................................... 92

11.0 Watchdog Timer (WDT) ............................................................................................................................................................. 93

12.0 Data EEPROM and Flash Program Memory Control................................................................................................................. 97

13.0 I/O Ports ................................................................................................................................................................................... 110

14.0 Interrupt-On-Change ................................................................................................................................................................ 132

15.0 Fixed Voltage Reference (FVR) ............................................................................................................................................... 136

16.0 Temperature Indicator Module ................................................................................................................................................. 139

17.0 Analog-to-Digital Converter (ADC) Module .............................................................................................................................. 141

18.0 Operational Amplifier (OPA) Modules ...................................................................................................................................... 156

19.0 Digital-to-Analog Converter (DAC) Module .............................................................................................................................. 159

20.0 Comparator Module.................................................................................................................................................................. 164

21.0 Timer0 Module ......................................................................................................................................................................... 173

22.0 Timer1 Module with Gate Control............................................................................................................................................. 176

23.0 Timer2 Module ......................................................................................................................................................................... 187

24.0 Programmable Switch Mode Control (PSMC).......................................................................................................................... 191

25.0 Capture/Compare/PWM Modules ............................................................................................................................................ 247

26.0 Master Synchronous Serial Port (MSSP) Module .................................................................................................................... 257

27.0 Enhanced Universal Synchronous Asynchronous Receiver Transmitter (EUSART)............................................................... 311

28.0 In-Circuit Serial Programming™ (ICSP™) ............................................................................................................................... 340

29.0 Instruction Set Summary.......................................................................................................................................................... 342

30.0 Electrical Specifications............................................................................................................................................................ 356

31.0 DC and AC Characteristics Graphs and Charts....................................................................................................................... 389

32.0 Development Support............................................................................................................................................................... 413

33.0 Packaging Information.............................................................................................................................................................. 418

The Microchip Web Site..................................................................................................................................................................... 432

Customer Change Notification Service .............................................................................................................................................. 432

Customer Support.............................................................................................................................................................................. 432

Product Identification System............................................................................................................................................................. 433

DS40001579E-page 6

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

1.0

DEVICE OVERVIEW

The PIC16(L)F1782/3 are described within this data

sheet. The block diagram of these devices are shown in

Figure 1-1. The available peripherals are shown in

Table 1-1, and the pin out descriptions are shown in

Table 1-2.

TABLE 1-1:

DEVICE PERIPHERAL SUMMARY

Peripheral

Analog-to-Digital Converter (ADC)

Fixed Voltage Reference (FVR)

Reference Clock Module

●

Temperature Indicator

Capture/Compare/PWM (CCP/ECCP) Modules

CCP1

●

CCP2

CCP3

Comparators

C1

C2

C3

C4

●

Digital-to-Analog Converter (DAC)

(8-bit DAC) D1

(5-bit DAC) D2

(5-bit DAC) D3

(5-bit DAC) D4

●

Enhanced Universal Synchronous/Asynchronous Receiver/Transmitter (EUSART)

EUSART

MSSP

●

Master Synchronous Serial Ports

Op Amp

●

Op Amp 1

Op Amp 2

Op Amp 3

●

Programmable Switch Mode Controller (PSMC)

PSMC1

●

PSMC2

PSMC3

PSMC4

Timers

Timer0

Timer1

Timer2

●

 2011-2014 Microchip Technology Inc.

DS40001579E-page 7

PIC16(L)F1782/3

FIGURE 1-1:

PIC16(L)F1782/3 BLOCK DIAGRAM

Program

Flash Memory

RAM

PORTA

PORTB

PORTC

PORTE

CLKOUT

CLKIN

Timing

Generation

HFINTOSC/

LFINTOSC

Oscillator

CPU

Figure 2-1

MCLR

Op Amps

PSMCs

Timer0

Timer1

Timer2

MSSP

Comparators

Temp.

Indicator

ADC

12-Bit

FVR

DAC

CCPs

EUSART

Note 1:

See applicable chapters for more information on peripherals.

DS40001579E-page 8

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 1-2:

PIC16(L)F1782/3 PINOUT DESCRIPTION

Input Output

Function

Name

Description

Type

RA0/AN0/C1IN0-/C2IN0-/C3IN0-

RA0

AN0

TTL/ST CMOS General purpose I/O.

AN

—

A/D Channel 0 input.

Comparator C1 negative input.

Comparator C2 negative input.

Comparator C3 negative input.

C1IN0-

C2IN0-

C3IN0-

RA1

RA1/AN1/C1IN1-/C2IN1-/

C3IN1-/OPA1OUT

TTL/ST CMOS General purpose I/O.

AN1

AN

—

A/D Channel 1 input.

C1IN1-

C2IN1-

C3IN1-

OPA1OUT

RA2

Comparator C1 negative input.

Comparator C2 negative input.

Comparator C3 negative input.

Operational Amplifier 1 output.

—

AN

RA2/AN2/C1IN0+/C2IN0+/

C3IN0+/DACOUT1/VREF-/

DACVREF-

TTL/ST CMOS General purpose I/O.

AN2

AN

—

A/D Channel 2 input.

C1IN0+

C2IN0+

C3IN0+

DACOUT1

VREF-

Comparator C1 positive input.

—

Comparator C2 positive input.

—

Comparator C3 positive input.

AN

—

Digital-to-Analog Converter output.

A/D Negative Voltage Reference input.

Digital-to-Analog Converter negative reference.

AN

DACVREF-

RA3

RA3/AN3/VREF+/C1IN1+/

DACVREF+

TTL/ST CMOS General purpose I/O.

AN3

AN

—

A/D Channel 3 input.

VREF+

C1IN1+

DACVREF+

RA4

A/D Voltage Reference input.

Comparator C1 positive input.

Digital-to-Analog Converter positive reference.

RA4/C1OUT/OPA1IN+/T0CKI

TTL/ST CMOS General purpose I/O.

C1OUT

OPA1IN+

T0CKI

RA5

—

AN

ST

CMOS Comparator C1 output.

—

Operational Amplifier 1 non-inverting input.

Timer0 clock input.

(1)

RA5/AN4/C2OUT /OP1INA-/

TTL/ST CMOS General purpose I/O.

SS

AN4

AN

—

A/D Channel 4 input.

C2OUT

OPA1IN-

SS

CMOS Comparator C2 output.

AN

ST

—

Operational Amplifier 1 inverting input.

Slave Select input.

RA6/C2OUT/OSC2/CLKOUT

RA6

TTL/ST CMOS General purpose I/O.

C2OUT

OSC2

CLKOUT

RA7

—

CMOS Comparator C2 output.

XTAL Crystal/Resonator (LP, XT, HS modes).

CMOS FOSC/4 output.

RA7/PSMC1CLK/

TTL/ST CMOS General purpose I/O.

PSMC2CLK/OSC1/CLKIN

ST

—

PSMC1 clock input.

PSMC2 clock input.

PSMC1CLK

PSMC2CLK

OSC1

ST

—

st

XTAL Crystal/Resonator (LP, XT, HS modes).

External clock input (EC mode).

OD = Open Drain

CLKIN

—

Legend: AN = Analog input or output CMOS= CMOS compatible input or output

2

TTL = TTL compatible input ST

HV = High Voltage

= Schmitt Trigger input with CMOS levels I C™ = Schmitt Trigger input with I C

levels

XTAL = Crystal

Note 1: Pin functions can be assigned to one of two locations via software. See Register 13-1.

2: All pins have Interrupt-on-Change functionality.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 9

PIC16(L)F1782/3

TABLE 1-2:

PIC16(L)F1782/3 PINOUT DESCRIPTION (CONTINUED)

Input Output

Type Type

Name

Function

Description

RB0/AN12/C2IN1+/PSMC1IN/

PSMC2IN/CCP1 /INT

RB0

AN12

C2IN1+

PSMC1IN

PSMC2IN

CCP1

INT

TTL/ST CMOS General purpose I/O.

(1)

AN

ST

—

A/D Channel 12 input.

Comparator C2 positive input.

PSMC1 Event Trigger input.

PSMC2 Event Trigger input.

CMOS Capture/Compare/PWM1.

External interrupt.

—

RB1/AN10/C1IN3-/C2IN3-/

C3IN3-/OPA2OUT

RB1

TTL/ST CMOS General purpose I/O.

AN10

C1IN3-

C2IN3-

C3IN3-

OPA2OUT

RB2

AN

—

A/D Channel 10 input.

Comparator C1 negative input.

Comparator C2 negative input.

Comparator C3 negative input.

Operational Amplifier 2 output.

—

AN

RB2/AN8/OPA2IN-/CLKR

RB3/AN9/C1IN2-/C2IN2-/

TTL/ST CMOS General purpose I/O.

AN8

AN

—

A/D Channel 8 input.

OPA2IN-

CLKR

RB3

Operational Amplifier 2 inverting input.

Clock output.

CMOS

TTL/ST CMOS General purpose I/O.

(1)

C3IN2-/OPA2IN+/CCP2

AN9

AN

ST

—

A/D Channel 9 input.

Comparator C1 negative input.

Comparator C2 negative input.

Comparator C3 negative input.

Operational Amplifier 2 non-inverting input.

C1IN2-

C2IN2-

C3IN2-

OPA2IN+

CCP2

RB4

CMOS Capture/Compare/PWM2.

RB4/AN11/C3IN1+

TTL/ST CMOS General purpose I/O.

AN11

AN

—

A/D Channel 11 input.

C3IN1+

RB5

Comparator C3 positive input.

(1)

RB5/AN13/C3OUT/T1G/SDO

TTL/ST CMOS General purpose I/O.

AN13

C3OUT

T1G

AN

—

A/D Channel 13 input.

CMOS Comparator C3 output.

Timer1 gate input.

CMOS SPI data output.

ST

—

SDO

(1)

RB6/TX /CK /SDI /SDA

ICSPCLK

/

RB6

TTL/ST CMOS General purpose I/O.

TX

—

ST

CMOS USART asynchronous transmit.

CMOS USART synchronous clock.

CK

SDI

—

OD

—

SPI data input.

2

SDA

I C

I C™ data input/output.

ICSPCLK

ST

Serial Programming Clock.

Legend: AN = Analog input or output CMOS= CMOS compatible input or output

OD = Open Drain

2

TTL = TTL compatible input ST

HV = High Voltage

= Schmitt Trigger input with CMOS levels I C™ = Schmitt Trigger input with I C

levels

XTAL = Crystal

Note 1: Pin functions can be assigned to one of two locations via software. See Register 13-1.

2: All pins have Interrupt-on-Change functionality.

DS40001579E-page 10

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 1-2:

PIC16(L)F1782/3 PINOUT DESCRIPTION (CONTINUED)

Input Output

Type Type

Name

Function

Description

(1)

RB7/DACOUT2/RX /DT

/

RB7

DACOUT2

RX

TTL/ST CMOS General purpose I/O.

(1)

SCK /SCL /ICSPDAT

—

ST

AN

—

Voltage Reference output.

USART asynchronous input.

DT

CMOS USART synchronous data.

SCK

CMOS SPI clock.

2

SCL

I C

OD

I C™ clock.

ICSPDAT

RC0

ST

CMOS ICSP™ Data I/O.

RC0/T1OSO/T1CKI/PSMC1A

TTL/ST CMOS General purpose I/O.

T1OSO

T1CKI

PSMC1A

RC1

XTAL

ST

XTAL Timer1 oscillator connection.

Timer1 clock input.

CMOS PSMC1 output A.

—

(1)

RC1/T1OSI/PSMC1B/CCP2

TTL/ST CMOS General purpose I/O.

T1OSI

PSMC1B

CCP2

RC2

XTAL

—

XTAL Timer1 oscillator connection.

CMOS PSMC1 output B.

ST

CMOS Capture/Compare/PWM2.

(1)

RC2/PSMC1C/CCP1

TTL/ST CMOS General purpose I/O.

PSMC1C

CCP1

RC3

—

CMOS PSMC1 output C.

ST

CMOS Capture/Compare/PWM1.

(1)

RC3/PSMC1D/SCK /SCL

TTL/ST CMOS General purpose I/O.

PSMC1D

SCK

—

CMOS PSMC1 output D.

ST

CMOS SPI clock.

2

SCL

I C

OD

I C™ clock.

(1)

RC4/PSMC1E/SDI /SDA

RC4

TTL/ST CMOS General purpose I/O.

PSMC1E

SDI

—

CMOS PSMC1 output E.

ST

—

SPI data input.

2

SDA

I C

OD

I C™ data input/output.

(1)

RC5/PSMC1F/SDO

RC5

TTL/ST CMOS General purpose I/O.

PSMC1F

SDO

—

CMOS PSMC1 output F.

CMOS SPI data output.

(1)

RC6/PSMC2A/TX /CK

RC6

TTL/ST CMOS General purpose I/O.

PSMC2A

TX

—

CMOS PSMC2 output A.

CMOS USART asynchronous transmit.

CMOS USART synchronous clock.

CK

ST

(1)

RC7/PSMC2B/RX /DT

RC7

TTL/ST CMOS General purpose I/O.

PSMC2B

RX

—

ST

CMOS PSMC2 output B.

—

USART asynchronous input.

DT

ST

CMOS USART synchronous data.

RE3

TTL/ST

ST

—

General purpose input.

Master Clear with internal pull-up.

Programming voltage.

Positive supply.

RE3/MCLR/VPP

MCLR

VPP

HV

VDD

VSS

VDD

Power

VSS

Ground reference.

Legend: AN = Analog input or output CMOS= CMOS compatible input or output

OD = Open Drain

2

TTL = TTL compatible input ST

HV = High Voltage

= Schmitt Trigger input with CMOS levels I C™ = Schmitt Trigger input with I C

levels

XTAL = Crystal

Note 1: Pin functions can be assigned to one of two locations via software. See Register 13-1.

2: All pins have Interrupt-on-Change functionality.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 11

PIC16(L)F1782/3

Relative addressing modes are available. Two File

Select Registers (FSRs) provide the ability to read

program and data memory.

2.0

ENHANCED MID-RANGE CPU

This family of devices contain an enhanced mid-range

8-bit CPU core. The CPU has 49 instructions. Interrupt

capability includes automatic context saving. The

hardware stack is 16 levels deep and has Overflow and

Underflow Reset capability. Direct, Indirect, and

• Automatic Interrupt Context Saving

• 16-level Stack with Overflow and Underflow

• File Select Registers

• Instruction Set

FIGURE 2-1:

CORE BLOCK DIAGRAM

15

Configuration

15

8

Data Bus

Program Counter

Flash

Program

Memory

186-LLeevveellSStatacckk

(153-bit)

RAM

Program

Bus

14

RAM Addr

Program Memory

Read (PMR)

12

Addr MUX

IInnssttrruuccttiioonnRreegg

Indirect

Addr

7

Direct Addr

12

5

BSR Reg

FSR reg

15

FSR0 Reg

reg

FSR1 Reg

FSR reg

15

SSTTAATTUUSSRreegg

8

3

MUX

Power-up

Timer

Oscillator

Instruction

DDeeccooddeea&nd

Control

Start-up Timer

ALU

Power-on

Reset

OSC1/CLKIN

8

Timing

Generation

Watchdog

Timer

W reg

OSC2/CLKOUT

Brown-out

Reset

Internal

Oscillator

Block

VDD

VSS

DS40001579E-page 12

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

2.1

Automatic Interrupt Context

Saving

During interrupts, certain registers are automatically

saved in shadow registers and restored when returning

from the interrupt. This saves stack space and user

code. See 8.5 “Automatic Context Saving”, for more

information.

2.2

16-level Stack with Overflow and

Underflow

These devices have an external stack memory 15 bits

wide and 16 words deep. A Stack Overflow or Under-

flow will set the appropriate bit (STKOVF or STKUNF)

in the PCON register, and if enabled will cause a soft-

ware Reset. See Section 3.5 “Stack” for more details.

2.3

File Select Registers

There are two 16-bit File Select Registers (FSR). FSRs

can access all file registers and program memory,

which allows one Data Pointer for all memory. When an

FSR points to program memory, there is one additional

instruction cycle in instructions using INDF to allow the

data to be fetched. General purpose memory can now

also be addressed linearly, providing the ability to

access contiguous data larger than 80 bytes. There are

also new instructions to support the FSRs. See

Section 3.6 “Indirect Addressing” for more details.

2.4

Instruction Set

There are 49 instructions for the enhanced mid-range

CPU to support the features of the CPU. See

Section 29.0 “Instruction Set Summary” for more

details.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 13

PIC16(L)F1782/3

The following features are associated with access and

control of program memory and data memory:

3.0

MEMORY ORGANIZATION

These devices contain the following types of memory:

• PCL and PCLATH

• Stack

• Program Memory

- Configuration Words

- Device ID

• Indirect Addressing

- User ID

3.1

Program Memory Organization

- Flash Program Memory

• Data Memory

The enhanced mid-range core has a 15-bit program

counter capable of addressing a 32K x 14 program

memory space. Table 3-1 shows the memory sizes

implemented for the PIC16(L)F1782/3 family. Accessing

a location above these boundaries will cause a

wrap-around within the implemented memory space.

The Reset vector is at 0000h and the interrupt vector is

at 0004h (see Figures 3-1 and 3-2).

- Core Registers

- Special Function Registers

- General Purpose RAM

- Common RAM

• Data EEPROM memory⁽¹⁾

Note 1: The Data EEPROM Memory and the

method to access Flash memory through

the EECON registers is described in

Section 12.0 “Data EEPROM and Flash

Program Memory Control”.

TABLE 3-1:

DEVICE SIZES AND ADDRESSES

Device

Program Memory Space (Words)

Last Program Memory Address

PIC16(L)F1782

PIC16(L)F1783

2,048

4,096

07FFh

0FFFh

DS40001579E-page 14

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 3-1:

PROGRAM MEMORY MAP

AND STACK FOR

FIGURE 3-2:

PROGRAM MEMORY MAP

AND STACK FOR

PIC16(L)F1782

PIC16(L)F1783

PC<14:0>

15

CALL, CALLW

RETURN, RETLW

Interrupt, RETFIE

CALL, CALLW

15

RETURN, RETLW

Interrupt, RETFIE

Stack Level 0

Stack Level 1

Stack Level 15

Reset Vector

Stack Level 15

Reset Vector

0000h

Interrupt Vector

Page 0

Interrupt Vector

Page 0

0004h

0005h

0004h

0005h

On-chip

Program

Memory

On-chip

Program

Memory

07FFh

0800h

07FFh

0800h

Rollover to Page 0

Wraps to Page 0

Page 1

0FFFh

1000h

Rollover to Page 0

Wraps to Page 0

Rollover to Page 0

Rollover to Page 1

7FFFh

 2011-2014 Microchip Technology Inc.

DS40001579E-page 15

PIC16(L)F1782/3

3.1.1

READING PROGRAM MEMORY AS

DATA

EXAMPLE 3-2:

ACCESSING PROGRAM

MEMORY VIA FSR

constants

There are two methods of accessing constants in

program memory. The first method is to use tables of

RETLW instructions. The second method is to set an

FSR to point to the program memory.

RETLW DATA0

RETLW DATA1

RETLW DATA2

RETLW DATA3

my_function

;Index0 data

;Index1 data

3.1.1.1

RETLWInstruction

;… LOTS OF CODE…

MOVLW

MOVWF

MOVLW

MOVWF

MOVIW

LOW constants

FSR1L

HIGH constants

FSR1H

0[FSR1]

The RETLWinstruction can be used to provide access

to tables of constants. The recommended way to create

such a table is shown in Example 3-1.

EXAMPLE 3-1:

RETLWINSTRUCTION

;THE PROGRAM MEMORY IS IN W

constants

BRW

;Add Index in W to

;program counter to

;select data

RETLW DATA0

RETLW DATA1

RETLW DATA2

RETLW DATA3

;Index0 data

;Index1 data

my_function

;… LOTS OF CODE…

MOVLW DATA_INDEX

call constants

;… THE CONSTANT IS IN W

The BRW instruction makes this type of table very

simple to implement. If your code must remain portable

with previous generations of microcontrollers, then the

BRWinstruction is not available so the older table read

method must be used.

3.1.1.2

Indirect Read with FSR

The program memory can be accessed as data by

setting bit 7 of the FSRxH register and reading the

matching INDFx register. The MOVIW instruction will

place the lower 8 bits of the addressed word in the W

register. Writes to the program memory cannot be

performed via the INDF registers. Instructions that

access the program memory via the FSR require one

extra instruction cycle to complete. Example 3-2

demonstrates accessing the program memory via an

FSR.

The high directive will set bit<7> if a label points to a

location in program memory.

DS40001579E-page 16

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

3.2.1

CORE REGISTERS

3.2

Data Memory Organization

The core registers contain the registers that directly

affect the basic operation. The core registers occupy

the first 12 addresses of every data memory bank

(addresses x00h/x08h through x0Bh/x8Bh). These

registers are listed below in Table 3-2. For detailed

information, see Table 3-7.

The data memory is partitioned in 32 memory banks

with 128 bytes in a bank. Each bank consists of

(Figure 3-3):

• 12 core registers

• 20 Special Function Registers (SFR)

• Up to 80 bytes of General Purpose RAM (GPR)

• 16 bytes of common RAM

TABLE 3-2:

CORE REGISTERS

The active bank is selected by writing the bank number

into the Bank Select Register (BSR). Unimplemented

memory will read as ‘0’. All data memory can be

accessed either directly (via instructions that use the

file registers) or indirectly via the two File Select

Registers (FSR). See Section 3.6 “Indirect

Addressing” for more information.

Addresses

BANKx

x00h or x80h

x01h or x81h

x02h or x82h

x03h or x83h

x04h or x84h

x05h or x85h

x06h or x86h

x07h or x87h

x08h or x88h

x09h or x89h

INDF0

INDF1

PCL

STATUS

FSR0L

FSR0H

FSR1L

FSR1H

BSR

Data memory uses a 12-bit address. The upper 5 bits

of the address define the Bank address and the lower

7 bits select the registers/RAM in that bank.

WREG

PCLATH

INTCON

x0Ah or x8Ah

x0Bh or x8Bh

 2011-2014 Microchip Technology Inc.

DS40001579E-page 17

PIC16(L)F1782/3

For example, CLRF STATUSwill clear the upper three

bits and set the Z bit. This leaves the STATUS register

as ‘000u u1uu’ (where u= unchanged).

3.2.1.1

STATUS Register

The STATUS register, shown in Register 3-1, contains:

• the arithmetic status of the ALU

• the Reset status

It is recommended, therefore, that only BCF, BSF,

SWAPF and MOVWF instructions are used to alter the

STATUS register, because these instructions do not

affect any Status bits. For other instructions not

affecting any Status bits (Refer to Section 29.0

“Instruction Set Summary”).

The STATUS register can be the destination for any

instruction, like any other register. If the STATUS

register is the destination for an instruction that affects

the Z, DC or C bits, then the write to these three bits is

disabled. These bits are set or cleared according to the

device logic. Furthermore, the TO and PD bits are not

writable. Therefore, the result of an instruction with the

STATUS register as destination may be different than

intended.

Note:

The C and DC bits operate as Borrow and

Digit Borrow out bits, respectively, in

subtraction.

3.3

Register Definitions: Status

REGISTER 3-1:

STATUS: STATUS REGISTER

U-0

—

U-0

—

R-1/q

TO

R-1/q

PD

R/W-0/u

Z

R/W-0/u

DC⁽¹⁾

R/W-0/u

C⁽¹⁾

—

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

q = Value depends on condition

bit 7-5

bit 4

Unimplemented: Read as ‘0’

TO: Time-Out bit

1= After power-up, CLRWDTinstruction or SLEEPinstruction

0= A WDT time-out occurred

bit 3

bit 2

bit 1

bit 0

PD: Power-Down bit

1= After power-up or by the CLRWDTinstruction

0= By execution of the SLEEPinstruction

Z: Zero bit

1= The result of an arithmetic or logic operation is zero

0= The result of an arithmetic or logic operation is not zero

DC: Digit Carry/Digit Borrow bit (ADDWF, ADDLW, SUBLW, SUBWFinstructions)⁽¹⁾

1= A carry-out from the 4th low-order bit of the result occurred

0= No carry-out from the 4th low-order bit of the result

C: Carry/Borrow bit⁽¹⁾(ADDWF, ADDLW, SUBLW, SUBWF instructions)⁽¹⁾

1= A carry-out from the Most Significant bit of the result occurred

0= No carry-out from the Most Significant bit of the result occurred

Note 1: For Borrow, the polarity is reversed. A subtraction is executed by adding the two’s complement of the

second operand.

DS40001579E-page 18

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

3.3.1

SPECIAL FUNCTION REGISTER

FIGURE 3-3:

BANKED MEMORY

PARTITIONING

The Special Function Registers are registers used by

the application to control the desired operation of

peripheral functions in the device. The Special Function

Registers occupy the 20 bytes after the core registers of

every data memory bank (addresses x0Ch/x8Ch

through x1Fh/x9Fh). The registers associated with the

operation of the peripherals are described in the

appropriate peripheral chapter of this data sheet.

Memory Region

7-bit Bank Offset

00h

Core Registers

(12 bytes)

0Bh

0Ch

3.3.2

GENERAL PURPOSE RAM

Special Function Registers

(20 bytes maximum)

There are up to 80 bytes of GPR in each data memory

bank. The Special Function Registers occupy the 20

bytes after the core registers of every data memory

bank (addresses x0Ch/x8Ch through x1Fh/x9Fh).

1Fh

20h

3.3.2.1

Linear Access to GPR

The general purpose RAM can be accessed in a

non-banked method via the FSRs. This can simplify

access to large memory structures. See Section 3.6.2

“Linear Data Memory” for more information.

General Purpose RAM

(80 bytes maximum)

3.3.3

COMMON RAM

There are 16 bytes of common RAM accessible from all

banks.

6Fh

70h

Common RAM

(16 bytes)

7Fh

 2011-2014 Microchip Technology Inc.

DS40001579E-page 19

PIC16(L)F1782/3

TABLE 3-5:

PIC16(L)F1782/3 MEMORY

MAP (BANK 16 DETAILS)

TABLE 3-6:

PIC16(L)F1782/3 MEMORY

MAP (BANK 31 DETAILS)

BANK 16

BANK 31

PSMC1CON

PSMC1MDL

PSMC1SYNC

PSMC1CLK

PSMC1OEN

PSMC1POL

PSMC1BLNK

PSMC1REBS

PSMC1FEBS

PSMC1PHS

PSMC1DCS

PSMC1PRS

PSMC1ASDC

PSMC1ASDD

PSMC1ASDS

PSMC1INT

PSMC2CON

PSMC2MDL

PSMC2SYNC

PSMC2CLK

PSMC2OEN

PSMC2POL

PSMC2BLNK

PSMC2REBS

PSMC2FEBS

PSMC2PHS

PSMC2DCS

PSMC2PRS

PSMC2ASDC

PSMC2ASDD

PSMC2ASDS

PSMC2INT

811h

812h

813h

814h

815h

816h

817h

818h

819h

81Ah

81Bh

81Ch

81Dh

81Eh

81Fh

820h

821h

822h

823h

824h

825h

826h

827h

828h

829h

82Ah

82Bh

82Ch

82Dh

82Eh

82Fh

830h

831h

832h

833h

834h

835h

836h

837h

838h

839h

83Ah

83Bh

83Ch

83Dh

83Eh

83Fh

840h

841h

842h

843h

844h

845h

846h

847h

848h

849h

84Ah

84Bh

84Ch

84Dh

84Eh

84Fh

840h

F8Ch

Unimplemented

Read as ‘0’

FE3h

FE4h

FE5h

FE6h

FE7h

FE8h

FE9h

FEAh

FEBh

FECh

FEDh

FEEh

FEFh

STATUS_SHAD

WREG_SHAD

BSR_SHAD

PCLATH_SHAD

FSR0L_SHAD

FSR0H_SHAD

FSR1L_SHAD

FSR1H_SHAD

—

STKPTR

TOSL

TOSH

PSMC1PHL

PSMC1PHH

PSMC1DCL

PSMC1DCH

PSMC1PRL

PSMC1PRH

PSMC1TMRL

PSMC1TMRH

PSMC1DBR

PSMC1DBF

PSMC1BLKR

PSMC1BLKF

PSMC1FFA

PSMC1STR0

PSMC1STR1

—

PSMC2PHL

PSMC2PHH

PSMC2DCL

PSMC2DCH

PSMC2PRL

PSMC2PRH

PSMC2TMRL

PSMC2TMRH

PSMC2DBR

PSMC2DBF

PSMC2BLKR

PSMC2BLKF

PSMC1FFA

PSMC2STR0

PSMC2STR1

Unimplemented

Read as ‘0’

86Fh

Legend:

= Unimplemented data memory locations, read as ‘0’.

Legend:

= Unimplemented data memory locations, read as ‘0’.

DS40001579E-page 22

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

3.3.5

CORE FUNCTION REGISTERS

SUMMARY

The Core Function registers listed in Table 3-7 can be

addressed from any Bank.

TABLE 3-7:

CORE FUNCTION REGISTERS SUMMARY

Value on

POR, BOR other Resets

Value on all

Addr

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Bank 0-31

x00h or

x80h

Addressing this location uses contents of FSR0H/FSR0L to address data memory

(not a physical register)

INDF0

xxxx xxxx uuuu uuuu

0000 0000 0000 0000

---1 1000 ---q quuu

0000 0000 uuuu uuuu

0000 0000 0000 0000

0000 0000 uuuu uuuu

0000 0000 0000 0000

---0 0000 ---0 0000

0000 0000 uuuu uuuu

-000 0000 -000 0000

0000 0000 0000 0000

x01h or

x81h

Addressing this location uses contents of FSR1H/FSR1L to address data memory

(not a physical register)

INDF1

PCL

x02h or

x82h

Program Counter (PC) Least Significant Byte

x03h or

x83h

STATUS

FSR0L

FSR0H

FSR1L

FSR1H

BSR

—

TO

PD

Z

DC

C

x04h or

x84h

Indirect Data Memory Address 0 Low Pointer

Indirect Data Memory Address 0 High Pointer

Indirect Data Memory Address 1 Low Pointer

Indirect Data Memory Address 1 High Pointer

x05h or

x85h

x06h or

x86h

x07h or

x87h

x08h or

x88h

—

BSR4

BSR3

BSR2

BSR1

INTF

BSR0

IOCIF

x09h or

x89h

WREG

PCLATH

INTCON

Working Register

x0Ahor

x8Ah

—

Write Buffer for the upper 7 bits of the Program Counter

PEIE TMR0IE INTE IOCIE TMR0IF

x0Bhor

x8Bh

GIE

Legend:

x= unknown, u= unchanged, q= value depends on condition, - = unimplemented, read as ‘0’, r= reserved.

Shaded locations are unimplemented, read as ‘0’.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 23

PIC16(L)F1782/3

TABLE 3-8:

SPECIAL FUNCTION REGISTER SUMMARY

Value on

all other

Resets

Value on

POR, BOR

Addr

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Bank 0

00Ch PORTA

00Dh PORTB

00Eh PORTC

PORTA Data Latch when written: PORTA pins when read

PORTB Data Latch when written: PORTB pins when read

PORTC Data Latch when written: PORTC pins when read

Unimplemented

xxxx xxxx uuuu uuuu

00Fh

—

010h PORTE

011h PIR1

012h PIR2

—

TMR1GIF

OSFIF

—

RE3

—

CCP1IF

—

---- x--- ---- u---

0000 0000 0000 0000

0000 0-00 0000 0-00

ADIF

C2IF

RCIF

C1IF

TXIF

EEIF

SSP1IF

BCL1IF

TMR2IF

C3IF

TMR1IF

CCP2IF

013h

—

Unimplemented

—

014h PIR4

—

PSMC2TIF

PSMC1TIF

—

PSMC2SIF PSMC1SIF --00 --00 --00 --00

xxxx xxxx uuuu uuuu

015h TMR0

016h TMR1L

017h TMR1H

018h T1CON

019h T1GCON

Timer0 Module Register

Holding Register for the Least Significant Byte of the 16-bit TMR1 Register

Holding Register for the Most Significant Byte of the 16-bit TMR1 Register

xxxx xxxx uuuu uuuu

TMR1CS1

TMR1GE

TMR1CS0

T1GPOL

T1CKPS1

T1GTM

T1CKPS0

T1GSPM

T1OSCEN

T1SYNC

T1GVAL

—

TMR1ON 0000 00-0 uuuu uu-u

T1GGO/

DONE

T1GSS<1:0>

0000 0x00 uuuu uxuu

016h TMR2

017h PR2

018h T2CON

01Dh

Holding Register for the Least Significant Byte of the 16-bit TMR2 Register

Holding Register for the Most Significant Byte of the 16-bit TMR2 Register

xxxx xxxx uuuu uuuu

-000 0000 -000 0000

—

T2OUTPS<3:0>

TMR2ON

T2CKPS<1:0>

to

—

Unimplemented

—

01Fh

Bank 1

08Ch TRISA

08Dh TRISB

08Eh TRISC

PORTA Data Direction Register

PORTB Data Direction Register

PORTC Data Direction Register

Unimplemented

1111 1111 1111 1111

08Fh

—

(2)

090h TRISE

091h PIE1

092h PIE2

—

TMR1GIE

OSEIE

Unimplemented

—

CCP1IE

—

---- 1--- ---- 1---

0000 0000 0000 0000

0000 0-00 0000 0-00

ADIE

C2IE

RCIE

C1IE

TXIE

EEIE

SSP1IE

BCL1IE

TMR2IE

C3IE

TMR1IE

CCP2IE

093h

—

094h PIE4

—

INTEDG

STKUNF

—

PSMC2TIE

TMR0CS

—

PSMC1TIE

TMR0SE

RWDT

—

PSA

—

RI

PSMC2SIE PSMC1SIE --00 --00 --00 --00

095h OPTION_REG

096h PCON

WPUEN

STKOVF

—

PS<2:0>

POR

1111 1111 1111 1111

00-1 11qq qq-q qquu

RMCLR

BOR

097h WDTCON

098h OSCTUNE

099h OSCCON

09Ah OSCSTAT

09Bh ADRESL

09Ch ADRESH

09Dh ADCON0

09Eh ADCON1

09Fh ADCON2

WDTPS<4:0>

SWDTEN --01 0110 --01 0110

—

TUN<5:0>

--00 0000 --00 0000

SPLLEN

T1OSCR

IRCF<3:0>

—

SCS<1:0>

0011 1-00 0011 1-00

00q0 --00 qqqq --0q

xxxx xxxx uuuu uuuu

0000 0000 0000 0000

0000 -000 0000 -000

000- -000 000- -000

PLLR

OSTS

HFIOFR

HFIOFL

MFIOFR

LFIOFR

HFIOFS

A/D Result Register Low

A/D Result Register High

ADRMD

CHS<4:0>

GO/DONE

ADON

ADFM

ADCS<2:0>

—

ADNREF

ADPREF<1:0>

TRIGSEL<3:0>

CHSN<3:0>

Legend:

x= unknown, u= unchanged, q= value depends on condition, - = unimplemented, read as ‘0’, r= reserved.

Shaded locations are unimplemented, read as ‘0’.

These registers can be addressed from any bank.

Unimplemented, read as ‘1’.

Note 1:

2:

3:

PIC16F1782/3 only.

DS40001579E-page 24

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 3-8:

SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)

Value on

all other

Resets

Value on

POR, BOR

Addr

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Bank 2

10Ch LATA

10Dh LATB

10Eh LATC

PORTA Data Latch

xxxx xxxx uuuu uuuu

PORTB Data Latch

PORTC Data Latch

Unimplemented

10Fh

110h

—

Unimplemented

111h CM1CON0

112h CM1CON1

113h CM2CON0

114h CM2CON1

115h CMOUT

116h BORCON

117h FVRCON

118h DACCON0

119h DACCON1

11Ah

C1ON

C1INTP

C2ON

C1OUT

C1OE

C2OE

C1POL

C1PCH<2:0>

C2POL

C1ZLF

C2ZLF

C1SP

C2SP

C1HYS

C1NCH<2:0>

C2HYS

C1SYNC 0000 0100 0000 0100

0000 0000 0000 0000

C1INTN

C2OUT

C2INTN

—

C2SYNC 0000 0100 0000 0100

0000 0000 0000 0000

C2INTP

—

C2PCH<2:0>

—

C2NCH<2:0>

MC2OUT

—

MC3OUT

—

MC1OUT ---- -000 ---- -000

BORRDY 1x-- ---q uu-- ---u

SBOREN

FVREN

DACEN

BORFS

FVRRDY

—

TSEN

DACOE1

TSRNG

DACOE2

CDAFVR<1:0>

DACPSS<1:0>

ADFVR<1:0>

0q00 0000 0q00 0000

DACNSS 0-00 00-0 0-00 00-0

0000 0000 0000 0000

—

DACR<7:0>

to

—

Unimplemented

—

11Ch

11Dh APFCON

11Eh CM3CON0

11Fh CM3CON1

Bank 3

C2OUTSEL CC1PSEL

SDOSEL

C3OE

SCKSEL

C3POL

SDISEL

TXSEL

C3SP

RXSEL

C3HYS

CCP2SEL 0000 0000 0000 0000

C3SYNC 0000 0100 0000 0100

0000 0000 0000 0000

C3ON

C3OUT

C3INTN

C3ZLF

C3INTP

C3PCH<2:0>

C3NCH<2:0>

18Ch ANSELA

18Dh ANSELB

18Eh

ANSA7

—

ANSA5

ANSB5

ANSA4

ANSB4

ANSA3

ANSB3

ANSA2

ANSB2

ANSA1

ANSB1

ANSA0

ANSB0

1-11 1111 1-11 1111

--11 1111 --11 1111

to

—

Unimplemented

—

190h

191h EEADRL

192h EEADRH

193h EEDATL

194h EEDATH

195h EECON1

196h EECON2

197h VREGCON⁽³⁾

EEPROM / Program Memory Address Register Low Byte

0000 0000 0000 0000

1000 0000 1000 0000

xxxx xxxx uuuu uuuu

--xx xxxx --uu uuuu

0000 x000 0000 q000

0000 0000 0000 0000

(2)

—

EEPROM / Program Memory Address Register High Byte

EEPROM / Program Memory Read Data Register Low Byte

—

EEPROM / Program Memory Read Data Register High Byte

EEPGD

CFGS

LWLO

FREE

—

WRERR

WREN

WR

RD

EEPROM / Program Memory Control Register 2

—

VREGPM

Reserved ---- --01 ---- --01

198h

—

Unimplemented

—

199h RCREG

19Ah TXREG

19Bh SPBRG

19Ch SPBRGH

19Dh RCSTA

19Eh TXSTA

19Fh BAUDCON

USART Receive Data Register

USART Transmit Data Register

0000 0000 0000 0000

0000 0010 0000 0010

01-0 0-00 01-0 0-00

BRG<7:0>

BRG<15:8>

SPEN

CSRC

RX9

TX9

SREN

TXEN

—

CREN

ADDEN

SENDB

BRG16

FERR

BRGH

—

OERR

TRMT

WUE

RX9D

TX9D

SYNC

SCKP

ABDOVF

RCIDL

ABDEN

Legend:

x= unknown, u= unchanged, q= value depends on condition, - = unimplemented, read as ‘0’, r= reserved.

Shaded locations are unimplemented, read as ‘0’.

These registers can be addressed from any bank.

Unimplemented, read as ‘1’.

Note 1:

2:

3:

PIC16F1782/3 only.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 25

PIC16(L)F1782/3

TABLE 3-8:

SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)

Value on

all other

Resets

Value on

POR, BOR

Addr

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Bank 4

20Ch WPUA

20Dh WPUB

20Eh WPUC

WPUA7

WPUB7

WPUA6

WPUB6

WPUC6

WPUA5

WPUB5

WPUC5

WPUA4

WPUB4

WPUC4

WPUA3

WPUB3

WPUC3

WPUA2

WPUB2

WPUC2

WPUA1

WPUB1

WPUC1

WPUA0

WPUB0

WPUC0

1111 1111 1111 1111

WPUC7

20Fh

—

Unimplemented

—

210h WPUE

—

WPUE3

—

---- 1--- ---- 1---

xxxx xxxx uuuu uuuu

0000 0000 0000 0000

211h SSP1BUF

212h SSP1ADD

Synchronous Serial Port Receive Buffer/Transmit Register

ADD<7:0>

MSK<7:0>

213h SSP1MSK

214h SSP1STAT

215h SSP1CON1

216h SSP1CON2

217h SSP1CON3

218h

1111 1111 1111 1111

0000 0000 0000 0000

SMP

WCOL

GCEN

ACKTIM

CKE

SSPOV

ACKSTAT

PCIE

D/A

P

S

R/W

UA

BF

SSPEN

ACKDT

SCIE

CKP

ACKEN

BOEN

SSPM<3:0>

RCEN

PEN

RSEN

AHEN

SEN

SDAHT

SBCDE

DHEN

—

21Fh

—

Unimplemented

—

Bank 5

28Ch ODCONA

28Dh ODCONB

28Eh ODCONC

Open Drain Control for PORTA

Open Drain Control for PORTB

Open Drain Control for PORTC

Unimplemented

0000 0000 0000 0000

28Fh

290h

—

Unimplemented

291h CCPR1L

292h CCPR1H

293h CCP1CON

294h

Capture/Compare/PWM Register 1 (LSB)

Capture/Compare/PWM Register 1 (MSB)

xxxx xxxx uuuu uuuu

--00 0000 --00 0000

—

DC1B<1:0>

CCP1M<3:0>

—

Unimplemented

—

297h

298h CCPR2L

299h CCPR2H

29Ah CCP2CON

29Bh

Capture/Compare/PWM Register 2 (LSB)

Capture/Compare/PWM Register 2 (MSB)

xxxx xxxx uuuu uuuu

--00 0000 --00 0000

—

DC2B<1:0>

CCP2M<3:0>

—

Unimplemented

—

29Fh

Bank 6

30Ch SLRCONA

30Dh SLRCONB

30Eh SLRCONC

30Fh

Slew Rate Control for PORTA

Slew Rate Control for PORTB

Slew Rate Control for PORTC

0000 0000 0000 0000

—

Unimplemented

—

31Fh

Legend:

x= unknown, u= unchanged, q= value depends on condition, - = unimplemented, read as ‘0’, r= reserved.

Shaded locations are unimplemented, read as ‘0’.

These registers can be addressed from any bank.

Unimplemented, read as ‘1’.

Note 1:

2:

3:

PIC16F1782/3 only.

DS40001579E-page 26

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 3-8:

SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)

Value on

all other

Resets

Value on

POR, BOR

Addr

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Bank 7

38Ch INLVLA

38Dh INLVLB

38Eh INLVLC

Input Type Control for PORTA

Input Type Control for PORTB

Input Type Control for PORTC

Unimplemented

0000 0000 0000 0000

1111 1111 1111 1111

38Fh

—

390h INLVLE

391h IOCAP

392h IOCAN

393h IOCAF

394h IOCBP

395h IOCBN

396h IOCBF

397h IOCCP

398h IOCCN

399h IOCCF

39Ah

—

INLVLE3

—

---- 1--- ---- 1---

0000 0000 0000 0000

IOCAP<7:0>

IOCAN<7:0>

IOCAF<7:0>

IOCBP<7:0>

IOCBN<7:0>

IOCBF<7:0>

IOCCP<7:0>

IOCCN<7:0>

IOCCF<7:0>

—

Unimplemented

—

39Ch

39Dh IOCEP

39Eh IOCEN

39Fh IOCEF

Bank 8-9

—

IOCEP3

IOCEN3

IOCEF3

—

---- 0--- ---- 0---

—

40Ch

or

41Fh

and

48Ch

or

—

Unimplemented

—

49Fh

Bank 10

50Ch

—

Unimplemented

—

510h

511h OPA1CON

512h

513h OPA2CON

OPA1EN

Unimplemented

OPA2EN

OPA1SP

OPA2SP

—

OPA1PCH<1:0>

00-- --00 00-- --00

—

OPA2PCH<1:0>

00-- --00 00-- --00

514h

—

Unimplemented

CLKREN

—

519h

51Ah CLKRCON

51Bh

—

51Fh

CLKROE

CLKRSLR

CLKRDC<1:0>

CLKRDIV<2:0>

0011 0000 0011 0000

—

Unimplemented

—

Legend:

x= unknown, u= unchanged, q= value depends on condition, - = unimplemented, read as ‘0’, r= reserved.

Shaded locations are unimplemented, read as ‘0’.

These registers can be addressed from any bank.

Unimplemented, read as ‘1’.

Note 1:

2:

3:

PIC16F1782/3 only.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 27

PIC16(L)F1782/3

TABLE 3-8:

SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)

Value on

all other

Resets

Value on

POR, BOR

Addr

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Bank 11-15

x0Ch

or

x8Ch

to

—

Unimplemented

—

x6Fh

or

xEFh

Legend:

x= unknown, u= unchanged, q= value depends on condition, - = unimplemented, read as ‘0’, r= reserved.

Shaded locations are unimplemented, read as ‘0’.

These registers can be addressed from any bank.

Unimplemented, read as ‘1’.

Note 1:

2:

3:

PIC16F1782/3 only.

DS40001579E-page 28

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 3-8:

SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)

Value on

all other

Resets

Value on

POR, BOR

Addr

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Bank 16

80Ch

—

810h

—

Unimplemented

PSMC1EN

—

811h PSMC1CON

812h PSMC1MDL

813h PSMC1SYNC

814h PSMC1CLK

815h PSMC1OEN

816h PSMC1POL

817h PSMC1BLNK

818h PSMC1REBS

819h PSMC1FEBS

81Ah PSMC1PHS

81Bh PSMC1DCS

81Ch PSMC1PRS

81Dh PSMC1ASDC

81Eh PSMC1ASDL

81Fh PSMC1ASDS

820h PSMC1INT

821h PSMC1PHL

822h PSMC1PHH

823h PSMC1DCL

PSMC1LD PSMC1DBFE PSMC1DBRE

P1MODE<3:0>

P1MSRC<3:0>

P1SYNC<1:0>

P1CSRC<1:0>

0000 0000 0000 0000

000- 0000 000- 0000

---- --00 ---- --00

--00 --00 --00 --00

--00 0000 --00 0000

-000 0000 -000 0000

--00 --00 --00 --00

0--- 000- 0--- 000-

0--- 0000 0--- 0000

P1MDLEN P1MDLPOL P1MDLBIT

—

P1CPRE<1:0>

—

P1OEC

P1POLC

—

P1OEF

P1OEE

P1OED

P1POLD

—

P1OEB

P1POLB

P1OEA

—

P1INPOL

P1POLF

P1POLE

P1POLA

—

P1FEBM<1:0>

P1REBM<1:0>

P1REBIN

P1FEBIN

P1PHSIN

P1DCSIN

P1PRSIN

P1ASE

—

P1REBSC3 P1REBSC2 P1REBSC1

P1FEBSC3 P1FEBSC2 P1FEBSC1

—

P1PHSC3

P1DCSC3

P1PRSC3

—

P1PHSC2

P1DCSC2

P1PRSC2

—

P1PHSC1

P1DCSC1

P1PRSC1

—

P1PHST

P1DCST

P1PRST

—

P1ASDEN

—

P1ARSEN

P1ASDLF

—

P1ASDOV 000- ---0 000- ---0

P1ASDLA --00 0000 --00 0000

P1ASDLE

—

P1ASDLD

P1ASDLC

P1ASDLB

P1ASDSIN

P1TOVIE

—

P1ASDSC3 P1ASDSC2 P1ASDSC1

P1TOVIF P1TPHIF P1TDCIF

—

0--- 000- 0--- 000-

P1TPHIE

P1TDCIE

P1TPRIE

P1TPRIF 0000 0000 0000 0000

0000 0000 0000 0000

0000 0001 0000 0001

0000 0000 0000 0000

---- 0000 ---- 0000

Phase Low Count

Phase High Count

Duty Cycle Low Count

824h PSMC1DCH Duty Cycle High Count

825h PSMC1PRL

826h PSMC1PRH

Period Low Count

Period High Count

827h PSMC1TMRL Time base Low Counter

828h PSMC1TMRH Time base High Counter

829h PSMC1DBR

82Ah PSMC1DBF

rising Edge Dead-band Counter

Falling Edge Dead-band Counter

82Bh PSMC1BLKR rising Edge Blanking Counter

82Ch PSMC1BLKF Falling Edge Blanking Counter

82Dh PSMC1FFA

82Eh PSMC1STR0

82Fh PSMC1STR1

—

P1STRF

—

P1STRE

—

Fractional Frequency Adjust Register

P1STRD

—

P1STRC

—

P1STRB

P1STRA

P1HSMEN 0--- --00 0--- --00

--00 0001 --00 0001

P1SYNC

Unimplemented

P1LSMEN

830h

—

Legend:

x= unknown, u= unchanged, q= value depends on condition, - = unimplemented, read as ‘0’, r= reserved.

Shaded locations are unimplemented, read as ‘0’.

These registers can be addressed from any bank.

Unimplemented, read as ‘1’.

Note 1:

2:

3:

PIC16F1782/3 only.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 29

PIC16(L)F1782/3

TABLE 3-8:

SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)

Value on

all other

Resets

Value on

POR, BOR

Addr

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Bank 16 (Continued)

831h PSMC2CON

832h PSMC2MDL

833h PSMC2SYNC

834h PSMC2CLK

835h PSMC2OEN

836h PSMC2POL

837h PSMC2BLNK

838h PSMC2REBS

839h PSMC2FEBS

83Ah PSMC2PHS

83Bh PSMC2DCS

83Ch PSMC2PRS

83Dh PSMC2ASDC

83Eh PSMC2ASDL

83Fh PSMC2ASDS

840h PSMC2INT

841h PSMC2PHL

842h PSMC2PHH

843h PSMC2DCL

PSMC2EN

PSMC2LD PSMC2DBFE PSMC2DBRE

P2MODE<3:0>

P2MSRC<3:0>

P2SYNC<1:0>

P2CSRC<1:0>

0000 0000 0000 0000

000- 0000 000- 0000

---- --00 ---- --00

--00 --00 --00 --00

---- --00 ---- --00

-0-- --00 -0-- --00

--00 --00 --00 --00

0--- 000- 0--- 000-

0--- 0000 0--- 0000

P2MDLEN P2MDLPOL P2MDLBIT

—

P2CPRE<1:0>

—

P2OEB

P2POLB

P2OEA

—

P2INPOL

P2POLA

—

P2FEBM<1:0>

P2REBM<1:0>

P2REBIN

P2FEBIN

P2PHSIN

P2DCSIN

P2PRSIN

P2ASE

—

P2REBSC3 P2REBSC2 P2REBSC1

P2FEBSC3 P2FEBSC2 P2FEBSC1

—

P2PHSC3

P2DCSC3

P2PRSC3

—

P2PHSC2

P2DCSC2

P2PRSC2

—

P2PHSC1

P2DCSC1

P2PRSC1

—

P2PHST

—

P2DCST 0--- 0000 0--- 0000

P2PRST 0--- 0000 0--- 0000

—

P2ASDEN

—

P2ARSEN

P2ASDLF

—

P2ASDOV 000- ---0 000- ---0

P2ASDLA --00 0000 --00 0000

P2ASDLE

—

P2ASDLD

P2ASDLC

P2ASDLB

P2ASDSIN

P2TOVIE

—

P2ASDSC3 P2ASDSC2 P2ASDSC1

P2TOVIF P2TPHIF P2TDCIF

—

0--- 000- 0--- 000-

P2TPHIE

P2TDCIE

P2TPRIE

P2TPRIF 0000 0000 0000 0000

0000 0000 0000 0000

0000 0001 0000 0001

0000 0000 0000 0000

---- 0000 ---- 0000

Phase Low Count

Phase High Count

Duty Cycle Low Count

844h PSMC2DCH Duty Cycle High Count

845h PSMC2PRL

846h PSMC2PRH

Period Low Count

Period High Count

847h PSMC2TMRL Time base Low Counter

848h PSMC2TMRH Time base High Counter

849h PSMC2DBR

84Ah PSMC2DBF

rising Edge Dead-band Counter

Falling Edge Dead-band Counter

84Bh PSMC2BLKR rising Edge Blanking Counter

84Ch PSMC2BLKF Falling Edge Blanking Counter

84Dh PSMC2FFA

84Eh PSMC2STR0

84Fh PSMC2STR1

850h

—

Fractional Frequency Adjust Register

—

P2STRB

P2STRA

---- --01 ---- --01

P2SYNC

P2LSMEN

P2HSMEN 0--- --00 0--- --00

—

86Fh

—

Unimplemented

—

Bank 17-30

x0Ch

or

x8Ch

to

—

Unimplemented

x1Fh

or

x9Fh

Legend:

x= unknown, u= unchanged, q= value depends on condition, - = unimplemented, read as ‘0’, r= reserved.

Shaded locations are unimplemented, read as ‘0’.

These registers can be addressed from any bank.

Unimplemented, read as ‘1’.

Note 1:

2:

3:

PIC16F1782/3 only.

DS40001579E-page 30

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 3-8:

SPECIAL FUNCTION REGISTER SUMMARY (CONTINUED)

Value on

all other

Resets

Value on

POR, BOR

Addr

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Bank 31

F8Ch

to

FE3h

—

Unimplemented

—

FE4h STATUS_

SHAD

—

Z

DC

C

---- -xxx ---- -uuu

FE5h WREG_SHAD Working Register Shadow

xxxx xxxx uuuu uuuu

---x xxxx ---u uuuu

-xxx xxxx uuuu uuuu

FE6h BSR_SHAD

—

Bank Select Register Shadow

FE7h PCLATH_

SHAD

Program Counter Latch High Register Shadow

FE8h FSR0L_SHAD Indirect Data Memory Address 0 Low Pointer Shadow

xxxx xxxx uuuu uuuu

FE9h FSR0H_

SHAD

Indirect Data Memory Address 0 High Pointer Shadow

FEAh FSR1L_SHAD Indirect Data Memory Address 1 Low Pointer Shadow

xxxx xxxx uuuu uuuu

FEBh FSR1H_

SHAD

Indirect Data Memory Address 1 High Pointer Shadow

FECh

FEDh

FEEh

—

Unimplemented

—

Current Stack Pointer

---1 1111 ---1 1111

xxxx xxxx uuuu uuuu

-xxx xxxx -uuu uuuu

STKPTR

TOSL

TOSH

Top of Stack Low byte

Top of Stack High byte

FEFh

—

Legend:

x= unknown, u= unchanged, q= value depends on condition, - = unimplemented, read as ‘0’, r= reserved.

Shaded locations are unimplemented, read as ‘0’.

These registers can be addressed from any bank.

Unimplemented, read as ‘1’.

Note 1:

2:

3:

PIC16F1782/3 only.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 31

PIC16(L)F1782/3

3.4.3

COMPUTED FUNCTION CALLS

3.4

PCL and PCLATH

A computed function CALLallows programs to maintain

tables of functions and provide another way to execute

state machines or look-up tables. When performing a

table read using a computed function CALL, care

should be exercised if the table location crosses a PCL

memory boundary (each 256-byte block).

The Program Counter (PC) is 15 bits wide. The low byte

comes from the PCL register, which is a readable and

writable register. The high byte (PC<14:8>) is not directly

readable or writable and comes from PCLATH. On any

Reset, the PC is cleared. Figure 3-4 shows the five

situations for the loading of the PC.

If using the CALLinstruction, the PCH<2:0> and PCL

registers are loaded with the operand of the CALL

instruction. PCH<6:3> is loaded with PCLATH<6:3>.

FIGURE 3-4:

LOADING OF PC IN

DIFFERENT SITUATIONS

The CALLW instruction enables computed calls by

combining PCLATH and W to form the destination

address. A computed CALLW is accomplished by

loading the W register with the desired address and

executing CALLW. The PCL register is loaded with the

value of W and PCH is loaded with PCLATH.

14

0

Instruction with

PCL as

Destination

PCH

PCL

PC

8

7

6

0

ALU Result

PCLATH

14

0

PCH

PCL

3.4.4

BRANCHING

GOTO, CALL

PC

The branching instructions add an offset to the PC.

This allows relocatable code and code that crosses

page boundaries. There are two forms of branching,

BRW and BRA. The PC will have incremented to fetch

the next instruction in both cases. When using either

branching instruction, a PCL memory boundary may be

crossed.

4

11

6

0

PCLATH

OPCODE <10:0>

14

0

PCH

PCL

CALLW

PC

7

8

6

W

PCLATH

If using BRW, load the W register with the desired

unsigned address and execute BRW. The entire PC will

be loaded with the address PC + 1 + W.

14

0

PCH

PCL

BRW

PC

If using BRA, the entire PC will be loaded with PC + 1 +,

the signed value of the operand of the BRAinstruction.

15

PC + W

14

PCL

BRA

PC

15

PC + OPCODE <8:0>

3.4.1

MODIFYING PCL

Executing any instruction with the PCL register as the

destination simultaneously causes the Program

Counter PC<14:8> bits (PCH) to be replaced by the

contents of the PCLATH register. This allows the entire

contents of the program counter to be changed by

writing the desired upper 7 bits to the PCLATH register.

When the lower 8 bits are written to the PCL register, all

15 bits of the program counter will change to the values

contained in the PCLATH register and those being

written to the PCL register.

3.4.2

COMPUTED GOTO

A computed GOTOis accomplished by adding an offset to

the program counter (ADDWF PCL). When performing a

table read using a computed GOTOmethod, care should

be exercised if the table location crosses a PCL memory

boundary (each 256-byte block). Refer to Application

Note AN556, “Implementing a Table Read” (DS00556).

DS40001579E-page 32

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

3.5.1

ACCESSING THE STACK

3.5

Stack

The stack is available through the TOSH, TOSL and

STKPTR registers. STKPTR is the current value of the

Stack Pointer. TOSH:TOSL register pair points to the

TOP of the stack. Both registers are read/writable. TOS

is split into TOSH and TOSL due to the 15-bit size of the

PC. To access the stack, adjust the value of STKPTR,

which will position TOSH:TOSL, then read/write to

TOSH:TOSL. STKPTR is 5 bits to allow detection of

overflow and underflow.

All devices have a 16-level x 15-bit wide hardware

stack (refer to Figures 3-1 and 3-2). The stack space is

not part of either program or data space. The PC is

PUSHed onto the stack when CALLor CALLWinstruc-

tions are executed or an interrupt causes a branch. The

stack is POPed in the event of a RETURN, RETLWor a

RETFIEinstruction execution. PCLATH is not affected

by a PUSH or POP operation.

The stack operates as a circular buffer if the STVREN

bit is programmed to ‘0‘ (Configuration Words). This

means that after the stack has been PUSHed sixteen

times, the seventeenth PUSH overwrites the value that

was stored from the first PUSH. The eighteenth PUSH

overwrites the second PUSH (and so on). The

STKOVF and STKUNF flag bits will be set on an Over-

flow/Underflow, regardless of whether the Reset is

enabled.

Note:

Care should be taken when modifying the

STKPTR while interrupts are enabled.

During normal program operation, CALL, CALLW and

interrupts will increment STKPTR while RETLW,

RETURN, and RETFIEwill decrement STKPTR. At any

time, STKPTR can be inspected to see how much

stack is left. The STKPTR always points at the currently

used place on the stack. Therefore, a CALLor CALLW

will increment the STKPTR and then write the PC, and

a return will unload the PC and then decrement the

STKPTR.

Note:

There are no instructions/mnemonics

called PUSH or POP. These are actions

that occur from the execution of the CALL,

CALLW, RETURN, RETLW and RETFIE

instructions or the vectoring to an interrupt

address.

Reference Figure 3-5 through Figure 3-8 for examples

of accessing the stack.

FIGURE 3-5:

ACCESSING THE STACK EXAMPLE 1

Stack Reset Disabled

(STVREN = 0)

TOSH:TOSL

0x0F

0x0E

0x0D

0x0C

0x0B

0x0A

0x09

0x08

0x07

0x06

0x05

0x04

0x03

0x02

0x01

0x00

0x1F

STKPTR = 0x1F

Initial Stack Configuration:

After Reset, the stack is empty. The

empty stack is initialized so the Stack

Pointer is pointing at 0x1F. If the Stack

Overflow/Underflow Reset is enabled, the

TOSH/TOSL registers will return ‘0’. If

the Stack Overflow/Underflow Reset is

disabled, the TOSH/TOSL registers will

return the contents of stack address 0x0F.

Stack Reset Enabled

STKPTR = 0x1F

TOSH:TOSL

0x0000

(STVREN = 1)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 33

PIC16(L)F1782/3

FIGURE 3-6:

ACCESSING THE STACK EXAMPLE 2

0x0F

0x0E

0x0D

0x0C

0x0B

0x0A

0x09

0x08

0x07

0x06

0x05

0x04

0x03

0x02

0x01

0x00

This figure shows the stack configuration

after the first CALLor a single interrupt.

If a RETURN instruction is executed, the

return address will be placed in the

Program Counter and the Stack Pointer

decremented to the empty state (0x1F).

TOSH:TOSL

Return Address

STKPTR = 0x00

FIGURE 3-7:

ACCESSING THE STACK EXAMPLE 3

0x0F

0x0E

0x0D

0x0C

0x0B

0x0A

0x09

0x08

0x07

After seven CALLs or six CALLs and an

interrupt, the stack looks like the figure

on the left. A series of RETURNinstructions

will repeatedly place the return addresses

into the Program Counter and pop the stack.

STKPTR = 0x06

TOSH:TOSL

0x06

0x05

0x04

0x03

0x02

0x01

0x00

Return Address

DS40001579E-page 34

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 3-8:

ACCESSING THE STACK EXAMPLE 4

0x0F

0x0E

0x0D

0x0C

0x0B

0x0A

0x09

0x08

0x07

0x06

0x05

0x04

0x03

0x02

0x01

0x00

Return Address

When the stack is full, the next CALLor

an interrupt will set the Stack Pointer to

0x10. This is identical to address 0x00

so the stack will wrap and overwrite the

return address at 0x00. If the Stack

Overflow/Underflow Reset is enabled, a

Reset will occur and location 0x00 will

not be overwritten.

TOSH:TOSL

STKPTR = 0x10

3.5.2

OVERFLOW/UNDERFLOW RESET

If the STVREN bit in Configuration Words is

programmed to ‘1’, the device will be reset if the stack

is PUSHed beyond the sixteenth level or POPed

beyond the first level, setting the appropriate bits

(STKOVF or STKUNF, respectively) in the PCON

register.

3.6

Indirect Addressing

The INDFn registers are not physical registers. Any

instruction that accesses an INDFn register actually

accesses the register at the address specified by the

File Select Registers (FSR). If the FSRn address

specifies one of the two INDFn registers, the read will

return ‘0’ and the write will not occur (though Status bits

may be affected). The FSRn register value is created

by the pair FSRnH and FSRnL.

The FSR registers form a 16-bit address that allows an

addressing space with 65536 locations. These locations

are divided into three memory regions:

• Traditional Data Memory

• Linear Data Memory

• Program Flash Memory

 2011-2014 Microchip Technology Inc.

DS40001579E-page 35

PIC16(L)F1782/3

FIGURE 3-9:

INDIRECT ADDRESSING

0x0000

Traditional

Data Memory

0x0FFF

0x1000

0x1FFF

0x2000

Reserved

Linear

Data Memory

0x29AF

0x29B0

Reserved

0x0000

FSR

Address

Range

0x7FFF

0x8000

Program

Flash Memory

0xFFFF

0x7FFF

Note:

Not all memory regions are completely implemented. Consult device memory tables for memory limits.

DS40001579E-page 36

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

3.6.1

TRADITIONAL DATA MEMORY

The traditional data memory is a region from FSR

address 0x000 to FSR address 0xFFF. The addresses

correspond to the absolute addresses of all SFR, GPR

and common registers.

FIGURE 3-10:

TRADITIONAL DATA MEMORY MAP

Direct Addressing

From Opcode

Indirect Addressing

4

BSR

6

7

FSRxH

0

7

FSRxL

0

Location Select

Bank Select

Location Select

00000 00001 00010

11111

0x00

0x7F

Bank 0 Bank 1 Bank 2

Bank 31

 2011-2014 Microchip Technology Inc.

DS40001579E-page 37

PIC16(L)F1782/3

3.6.2

LINEAR DATA MEMORY

3.6.3

PROGRAM FLASH MEMORY

The linear data memory is the region from FSR

address 0x2000 to FSR address 0x29AF. This region is

a virtual region that points back to the 80-byte blocks of

GPR memory in all the banks.

To make constant data access easier, the entire

program Flash memory is mapped to the upper half of

the FSR address space. When the MSB of FSRnH is

set, the lower 15 bits are the address in program

memory which will be accessed through INDF. Only the

lower 8 bits of each memory location is accessible via

INDF. Writing to the program Flash memory cannot be

accomplished via the FSR/INDF interface. All

instructions that access program Flash memory via the

FSR/INDF interface will require one additional

instruction cycle to complete.

Unimplemented memory reads as 0x00. Use of the

linear data memory region allows buffers to be larger

than 80 bytes because incrementing the FSR beyond

one bank will go directly to the GPR memory of the next

bank.

The 16 bytes of common memory are not included in

the linear data memory region.

FIGURE 3-12:

PROGRAM FLASH

MEMORY MAP

FIGURE 3-11:

LINEAR DATA MEMORY

MAP

7

0

FSRnH

FSRnL

7

1

7

0

FSRnH

FSRnL

0

0 1

Location Select

0x8000

0x0000

Location Select

0x2000

0x020

Bank 0

0x06F

0x0A0

Bank 1

0x0EF

0x120

Program

Flash

Memory

(low 8

bits)

Bank 2

0x16F

0xF20

Bank 30

0x7FFF

0xFFFF

0xF6F

0x29AF

DS40001579E-page 38

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

4.0

DEVICE CONFIGURATION

Device configuration consists of Configuration Words,

Code Protection and Device ID.

4.1

Configuration Words

There are several Configuration Word bits that allow

different oscillator and memory protection options.

These are implemented as Configuration Word 1 at

8007h and Configuration Word 2 at 8008h.

Note:

The DEBUG bit in Configuration Words is

managed automatically by device

development tools including debuggers

and programmers. For normal device

operation, this bit should be maintained as

a ‘1’.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 39

PIC16(L)F1782/3

4.2

Register Definitions: Configuration Words

REGISTER 4-1:

CONFIG1: CONFIGURATION WORD 1

R/P-1

IESO

R/P-1

CPD

FCMEN

CLKOUTEN

BOREN<1:0>

bit 13

bit 8

R/P-1

CP

R/P-1

bit 0

MCLRE

PWRTE

WDTE<1:0>

FOSC<2:0>

bit 7

Legend:

R = Readable bit

P = Programmable bit

‘1’ = Bit is set

U = Unimplemented bit, read as ‘1’

‘0’ = Bit is cleared

-n = Value when blank or after Bulk Erase

bit 13

bit 12

bit 11

FCMEN: Fail-Safe Clock Monitor Enable bit

1= Fail-Safe Clock Monitor and internal/external switchover are both enabled.

0= Fail-Safe Clock Monitor is disabled

IESO: Internal External Switchover bit

1= Internal/External Switchover mode is enabled

0= Internal/External Switchover mode is disabled

CLKOUTEN: Clock Out Enable bit

If FOSC configuration bits are set to LP, XT, HS modes:

This bit is ignored, CLKOUT function is disabled. Oscillator function on the CLKOUT pin.

All other FOSC modes:

1= CLKOUT function is disabled. I/O function on the CLKOUT pin.

0= CLKOUT function is enabled on the CLKOUT pin

bit 10-9

BOREN<1:0>: Brown-out Reset Enable bits

11= BOR enabled

10= BOR enabled during operation and disabled in Sleep

01= BOR controlled by SBOREN bit of the BORCON register

00= BOR disabled

bit 8

bit 7

bit 6

CPD: Data Code Protection bit⁽¹⁾

1= Data memory code protection is disabled

0= Data memory code protection is enabled

CP: Code Protection bit

1= Program memory code protection is disabled

0= Program memory code protection is enabled

MCLRE: MCLR/VPP Pin Function Select bit

If LVP bit = 1:

This bit is ignored.

If LVP bit = 0:

1= MCLR/VPP pin function is MCLR; Weak pull-up enabled.

0= MCLR/VPP pin function is digital input; MCLR internally disabled; Weak pull-up under control of

WPUE3 bit.

bit 5

PWRTE: Power-up Timer Enable bit

1= PWRT disabled

0= PWRT enabled

bit 4-3

WDTE<1:0>: Watchdog Timer Enable bit

11= WDT enabled

10= WDT enabled while running and disabled in Sleep

01= WDT controlled by the SWDTEN bit in the WDTCON register

00= WDT disabled

DS40001579E-page 40

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 4-1:

CONFIG1: CONFIGURATION WORD 1 (CONTINUED)

bit 2-0

FOSC<2:0>: Oscillator Selection bits

111= ECH: External Clock, High-Power mode (4-20 MHz): device clock supplied to CLKIN pin

110= ECM: External Clock, Medium-Power mode (0.5-4 MHz): device clock supplied to CLKIN pin

101= ECL: External Clock, Low-Power mode (0-0.5 MHz): device clock supplied to CLKIN pin

100= INTOSC oscillator: I/O function on CLKIN pin

011= EXTRC oscillator: External RC circuit connected to CLKIN pin

010= HS oscillator: High-speed crystal/resonator connected between OSC1 and OSC2 pins

001= XT oscillator: Crystal/resonator connected between OSC1 and OSC2 pins

000= LP oscillator: Low-power crystal connected between OSC1 and OSC2 pins

Note 1: The entire data EEPROM will be erased when the code protection is turned off during an erase.Once the

Data Code Protection bit is enabled, (CPD = 0), the Bulk Erase Program Memory Command (through

ICSP) can disable the Data Code Protection (CPD =1). When a Bulk Erase Program Memory Command

is executed, the entire Program Flash Memory, Data EEPROM and configuration memory will be erased.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 41

PIC16(L)F1782/3

REGISTER 4-2:

CONFIG2: CONFIGURATION WORD 2

R/P-1

LVP

R/P-1

DEBUG

LPBOR

BORV

STVREN

PLLEN

bit 13

bit 8

U-1

—

U-1

—

R/P-1

U-1

—

U-1

—

U-1

—

R/P-1

WRT<1:0>

VCAPEN

bit 7

bit 0

Legend:

R = Readable bit

‘0’ = Bit is cleared

P = Programmable bit

‘1’ = Bit is set

U = Unimplemented bit, read as ‘1’

-n = Value when blank or after Bulk Erase

(1)

bit 13

bit 12

bit 11

bit 10

bit 9

LVP: Low-Voltage Programming Enable bit

1= Low-voltage programming enabled

0= High-voltage on MCLR must be used for programming

(3)

DEBUG: In-Circuit Debugger Mode bit

1= In-Circuit Debugger disabled, ICSPCLK and ICSPDAT are general purpose I/O pins

0= In-Circuit Debugger enabled, ICSPCLK and ICSPDAT are dedicated to the debugger

LPBOR: Low-Power BOR Enable bit

1= Low-Power Brown-out Reset is disabled

0= Low-Power Brown-out Reset is enabled

(4)

BORV: Brown-out Reset Voltage Selection bit

1= Brown-out Reset voltage (VBOR), low trip point selected.

0= Brown-out Reset voltage (VBOR), high trip point selected.

STVREN: Stack Overflow/Underflow Reset Enable bit

1= Stack Overflow or Underflow will cause a Reset

0= Stack Overflow or Underflow will not cause a Reset

bit 8

PLLEN: PLL Enable bit

1= 4xPLL enabled

0= 4xPLL disabled

bit 7-6

bit 5

Unimplemented: Read as ‘1’

(2)

VCAPEN: Voltage Regulator Capacitor Enable bit

1= VCAP functionality is disabled on RA6

0= VCAP functionality is enabled on RA6

bit 4-2

bit 1-0

Unimplemented: Read as ‘1’

WRT<1:0>: Flash Memory Self-Write Protection bits

2 kW Flash memory (PIC16(L)F1782 only):

11= Write protection off

10= 000h to 1FFh write-protected, 200h to 7FFh may be modified by EECON control

01= 000h to 3FFh write-protected, 400h to 7FFh may be modified by EECON control

00= 000h to 7FFh write-protected, no addresses may be modified by EECON control

4 kW Flash memory (PIC16(L)F1783 only):

11= Write protection off

10= 000h to 1FFh write-protected, 200h to FFFh may be modified by EECON control

01= 000h to 7FFh write-protected, 800h to FFFh may be modified by EECON control

00= 000h to FFFh write-protected, no addresses may be modified by EECON control

Note 1: The LVP bit cannot be programmed to ‘0’ when Programming mode is entered via LVP.

2: Not implemented on “LF” devices.

3: The DEBUG bit in Configuration Words is managed automatically by device development tools including debuggers

and programmers. For normal device operation, this bit should be maintained as a '1'.

4: See VBOR parameter for specific trip point voltages.

DS40001579E-page 42

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

4.3

Code Protection

Code protection allows the device to be protected from

unauthorized access. Program memory protection and

data EEPROM protection are controlled independently.

Internal access to the program memory and data

EEPROM are unaffected by any code protection

setting.

4.3.1

PROGRAM MEMORY PROTECTION

The entire program memory space is protected from

external reads and writes by the CP bit in Configuration

Words. When CP = 0, external reads and writes of

program memory are inhibited and a read will return all

‘0’s. The CPU can continue to read program memory,

regardless of the protection bit settings. Writing the

program memory is dependent upon the write

protection

setting.

See

Section 4.4

“Write

Protection” for more information.

4.3.2

DATA EEPROM PROTECTION

The entire data EEPROM is protected from external

reads and writes by the CPD bit. When CPD = 0,

external reads and writes of data EEPROM are

inhibited. The CPU can continue to read and write data

EEPROM regardless of the protection bit settings.

4.4

Write Protection

Write protection allows the device to be protected from

unintended self-writes. Applications, such as

bootloader software, can be protected while allowing

other regions of the program memory to be modified.

The WRT<1:0> bits in Configuration Words define the

size of the program memory block that is protected.

4.5

User ID

Four memory locations (8000h-8003h) are designated

as ID locations where the user can store checksum or

other code identification numbers. These locations are

readable and writable during normal execution. See

Section 12.5 “User ID, Device ID and Configuration

Word Access”for more information on accessing

these memory locations. For more information on

checksum calculation, see the “PIC16(L)F178X

Memory Programming Specification” (DS41457).

 2011-2014 Microchip Technology Inc.

DS40001579E-page 43

PIC16(L)F1782/3

4.6

Device ID and Revision ID

The memory location 8006h is where the Device ID and

Revision ID are stored. The upper nine bits hold the

Device ID. The lower five bits hold the Revision ID. See

Section 12.5 “User ID, Device ID and Configuration

Word Access” for more information on accessing

these memory locations.

Development tools, such as device programmers and

debuggers, may be used to read the Device ID and

Revision ID.

4.7

Register Definitions: Device and Revision

REGISTER 4-3:

DEVID: DEVICE ID REGISTER

R

DEV<8:3>

bit 13

bit 8

bit 0

R

DEV<2:0>

REV<4:0>

bit 7

Legend:

R = Readable bit

‘1’ = Bit is set

‘0’ = Bit is cleared

bit 13-5

DEV<8:0>: Device ID bits

DEVICEID<13:0> Values

Device

DEV<8:0>

REV<4:0>

PIC16F1782

PIC16LF1782

PIC16F1783

PIC16LF1783

10 1010 000

10 1010 101

10 1010 001

10 1010 110

x xxxx

bit 4-0

REV<4:0>: Revision ID bits

These bits are used to identify the revision (see Table under DEV<8:0> above).

DS40001579E-page 44

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

A simplified block diagram of the On-Chip Reset Circuit

is shown in Figure 5-1.

5.0

RESETS

There are multiple ways to reset this device:

• Power-On Reset (POR)

• Brown-Out Reset (BOR)

• Low-Power Brown-Out Reset (LPBOR)

• MCLR Reset

• WDT Reset

• RESETinstruction

• Stack Overflow

• Stack Underflow

• Programming mode exit

To allow VDD to stabilize, an optional Power-up Timer

can be enabled to extend the Reset time after a BOR

or POR event.

FIGURE 5-1:

SIMPLIFIED BLOCK DIAGRAM OF ON-CHIP RESET CIRCUIT

ICSP™ Programming Mode

Exit

RESETInstruction

Stack

Pointer

MCLRE

Sleep

WDT

Time-out

Device

Reset

Power-on

Reset

VDD

Brown-out

Reset

PWRT

R

Done

LPBOR

Reset

PWRTE

LFINTOSC

BOR

Active⁽¹⁾

Note 1: See Table 5-1 for BOR active conditions.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 45

PIC16(L)F1782/3

5.1

Power-On Reset (POR)

5.2

Brown-Out Reset (BOR)

The POR circuit holds the device in Reset until VDD has

reached an acceptable level for minimum operation.

Slow rising VDD, fast operating speeds or analog

performance may require greater than minimum VDD.

The PWRT, BOR or MCLR features can be used to

extend the start-up period until all device operation

conditions have been met.

The BOR circuit holds the device in Reset when VDD

reaches a selectable minimum level. Between the

POR and BOR, complete voltage range coverage for

execution protection can be implemented.

The Brown-out Reset module has four operating

modes controlled by the BOREN<1:0> bits in Configu-

ration Words. The four operating modes are:

• BOR is always on

5.1.1

POWER-UP TIMER (PWRT)

• BOR is off when in Sleep

• BOR is controlled by software

• BOR is always off

The Power-up Timer provides a nominal 64 ms

time-out on POR or Brown-out Reset.

The device is held in Reset as long as PWRT is active.

The PWRT delay allows additional time for the VDD to

rise to an acceptable level. The Power-up Timer is

enabled by clearing the PWRTE bit in Configuration

Words.

Refer to Table 5-1 for more information.

The Brown-out Reset voltage level is selectable by

configuring the BORV bit in Configuration Words.

A VDD noise rejection filter prevents the BOR from

triggering on small events. If VDD falls below VBOR for

a duration greater than parameter TBORDC, the device

will reset. See Figure 5-2 for more information.

The Power-up Timer starts after the release of the POR

and BOR.

For additional information, refer to Application Note

AN607, “Power-up Trouble Shooting” (DS00607).

TABLE 5-1:

BOREN<1:0>

11

BOR OPERATING MODES

Instruction Execution upon:

Release of POR or Wake-up from Sleep

SBOREN

Device Mode

BOR Mode

X

Awake

Sleep

X

Active

Waits for BOR ready⁽¹⁾(BORRDY = 1)

10

Waits for BOR ready (BORRDY = 1)

Waits for BOR ready⁽¹⁾(BORRDY = 1)

Begins immediately (BORRDY = x)

Disabled

Active

1

0

X

01

00

X

Disabled

X

Note 1: In these specific cases, “Release of POR” and “Wake-up from Sleep”, there is no delay in start-up. The BOR

ready flag, (BORRDY = 1), will be set before the CPU is ready to execute instructions because the BOR

circuit is forced on by the BOREN<1:0> bits.

5.2.1

BOR IS ALWAYS ON

5.2.3

BOR CONTROLLED BY SOFTWARE

When the BOREN bits of Configuration Words are

programmed to ‘11’, the BOR is always on. The device

start-up will be delayed until the BOR is ready and VDD

is higher than the BOR threshold.

When the BOREN bits of Configuration Words are

programmed to ‘01’, the BOR is controlled by the

SBOREN bit of the BORCON register. The device

start-up is not delayed by the BOR ready condition or

the VDD level.

BOR protection is active during Sleep. The BOR does

not delay wake-up from Sleep.

BOR protection begins as soon as the BOR circuit is

ready. The status of the BOR circuit is reflected in the

BORRDY bit of the BORCON register.

5.2.2

BOR IS OFF IN SLEEP

When the BOREN bits of Configuration Words are

programmed to ‘10’, the BOR is on, except in Sleep.

The device start-up will be delayed until the BOR is

ready and VDD is higher than the BOR threshold.

BOR protection is unchanged by Sleep.

BOR protection is not active during Sleep. The device

wake-up will be delayed until the BOR is ready.

DS40001579E-page 46

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 5-2:

BROWN-OUT SITUATIONS

VDD

VBOR

Internal

Reset

(1)

TPWRT

VDD

VBOR

Internal

Reset

< TPWRT

(1)

TPWRT

VDD

VBOR

Internal

Reset

(1)

TPWRT

Note 1: TPWRT delay only if PWRTE bit is programmed to ‘0’.

5.3

Register Definitions: BOR Control

REGISTER 5-1:

BORCON: BROWN-OUT RESET CONTROL REGISTER

R/W-1/u

SBOREN

bit 7

R/W-0/u

BORFS

U-0

—

U-0

—

U-0

—

U-0

—

U-0

—

R-q/u

BORRDY

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

u = Bit is unchanged

‘1’ = Bit is set

-n/n = Value at POR and BOR/Value at all other Resets

q = Value depends on condition

bit 7

bit 6

SBOREN: Software Brown-out Reset Enable bit

If BOREN <1:0> in Configuration Words  01:

SBOREN is read/write, but has no effect on the BOR.

If BOREN <1:0> in Configuration Words = 01:

1= BOR Enabled

0= BOR Disabled

(1)

BORFS: Brown-out Reset Fast Start bit

If BOREN<1:0> = 11 (Always on) or BOREN<1:0> = 00 (Always off)

BORFS is Read/Write, but has no effect.

If BOREN <1:0> = 10 (Disabled in Sleep) or BOREN<1:0> = 01 (Under software control):

1= Band gap is forced on always (covers sleep/wake-up/operating cases)

0= Band gap operates normally, and may turn off

bit 5-1

bit 0

Unimplemented: Read as ‘0’

BORRDY: Brown-out Reset Circuit Ready Status bit

1= The Brown-out Reset circuit is active

0= The Brown-out Reset circuit is inactive

Note 1: BOREN<1:0> bits are located in Configuration Words.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 47

PIC16(L)F1782/3

5.4

Low-Power Brown-Out Reset

(LPBOR)

5.6

Watchdog Timer (WDT) Reset

The Watchdog Timer generates a Reset if the firmware

does not issue a CLRWDTinstruction within the time-out

period. The TO and PD bits in the STATUS register are

changed to indicate the WDT Reset. See Section 11.0

“Watchdog Timer (WDT)” for more information.

The Low-Power Brown-Out Reset (LPBOR) is an

essential part of the Reset subsystem. Refer to

Figure 5-1 to see how the BOR interacts with other

modules.

The LPBOR is used to monitor the external VDD pin.

When too low of a voltage is detected, the device is

held in Reset. When this occurs, a register bit (BOR) is

changed to indicate that a BOR Reset has occurred.

The same bit is set for both the BOR and the LPBOR.

Refer to Register 5-2.

5.7

RESETInstruction

A RESETinstruction will cause a device Reset. The RI

bit in the PCON register will be set to ‘0’. See Table 5-4

for default conditions after a RESET instruction has

occurred.

5.4.1

ENABLING LPBOR

5.8

Stack Overflow/Underflow Reset

The LPBOR is controlled by the LPBOR bit of

Configuration Words. When the device is erased, the

LPBOR module defaults to disabled.

The device can reset when the Stack Overflows or

Underflows. The STKOVF or STKUNF bits of the PCON

register indicate the Reset condition. These Resets are

enabled by setting the STVREN bit in Configuration

Words. See Section 5.8 “Stack Overflow/Underflow

Reset” for more information.

5.4.1.1

LPBOR Module Output

The output of the LPBOR module is a signal indicating

whether or not a Reset is to be asserted. This signal is

OR’d together with the Reset signal of the BOR mod-

ule to provide the generic BOR signal, which goes to

the PCON register and to the power control block.

5.9

Programming Mode Exit

Upon exit of Programming mode, the device will

behave as if a POR had just occurred.

5.5

MCLR

5.10 Power-Up Timer

The MCLR is an optional external input that can reset

the device. The MCLR function is controlled by the

MCLRE bit of Configuration Words and the LVP bit of

Configuration Words (Table 5-2).

The Power-up Timer optionally delays device execution

after a BOR or POR event. This timer is typically used to

allow VDD to stabilize before allowing the device to start

running.

TABLE 5-2:

MCLRE

MCLR CONFIGURATION

The Power-up Timer is controlled by the PWRTE bit of

Configuration Words.

LVP

MCLR

0

1

x

0

1

Disabled

Enabled

5.11 Start-up Sequence

Upon the release of a POR or BOR, the following must

occur before the device will begin executing:

1. Power-up Timer runs to completion (if enabled).

5.5.1

MCLR ENABLED

2. Oscillator start-up timer runs to completion (if

required for oscillator source).

When MCLR is enabled and the pin is held low, the

device is held in Reset. The MCLR pin is connected to

VDD through an internal weak pull-up.

3. MCLR must be released (if enabled).

The total time-out will vary based on oscillator configu-

ration and Power-up Timer configuration. See

Section 6.0 “Oscillator Module (with Fail-Safe

Clock Monitor)” for more information.

The device has a noise filter in the MCLR Reset path.

The filter will detect and ignore small pulses.

Note:

A Reset does not drive the MCLR pin low.

The Power-up Timer and oscillator start-up timer run

independently of MCLR Reset. If MCLR is kept low

long enough, the Power-up Timer and oscillator

start-up timer will expire. Upon bringing MCLR high, the

device will begin execution immediately (see

Figure 5-3). This is useful for testing purposes or to

synchronize more than one device operating in parallel.

5.5.2

MCLR DISABLED

When MCLR is disabled, the pin functions as a general

purpose input and the internal weak pull-up is under

software control. See Section 13.9 “PORTE

Registers” for more information.

DS40001579E-page 48

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 5-3:

RESET START-UP SEQUENCE

VDD

Internal POR

TPWRT

Power-up Timer

MCLR

TMCLR

Internal RESET

Oscillator Modes

External Crystal

TOST

Oscillator Start-up Timer

Oscillator

FOSC

Internal Oscillator

Oscillator

FOSC

External Clock (EC)

CLKIN

FOSC

 2011-2014 Microchip Technology Inc.

DS40001579E-page 49

PIC16(L)F1782/3

5.12 Determining the Cause of a Reset

Upon any Reset, multiple bits in the STATUS and

PCON register are updated to indicate the cause of the

Reset. Table 5-3 and Table 5-4 show the Reset

conditions of these registers.

TABLE 5-3:

RESET STATUS BITS AND THEIR SIGNIFICANCE

STKOVF STKUNF RWDT RMCLR

RI

POR

BOR

TO

PD

Condition

Power-on Reset

0

u

1

u

0

u

1

u

0

u

1

u

0

u

1

u

0

u

0

u

x

0

u

1

0

x

1

0

1

u

1

u

1

x

0

1

u

0

u

0

u

Illegal, TO is set on POR

Illegal, PD is set on POR

Brown-out Reset

WDT Reset

WDT Wake-up from Sleep

Interrupt Wake-up from Sleep

MCLR Reset during normal operation

MCLR Reset during Sleep

RESETInstruction Executed

Stack Overflow Reset (STVREN = 1)

Stack Underflow Reset (STVREN = 1)

TABLE 5-4:

RESET CONDITION FOR SPECIAL REGISTERS

Program

STATUS

Register

PCON

Register

Condition

Counter

Power-on Reset

0000h

---1 1000

---u uuuu

00-- 110x

uu-- 0uuu

MCLR Reset during normal operation

0000h

MCLR Reset during Sleep

WDT Reset

0000h

---1 0uuu

---0 uuuu

---0 0uuu

---1 1uuu

---1 0uuu

---u uuuu

uu-- 0uuu

uu-- uuuu

00-- 11u0

uu-- uuuu

uu-- u0uu

1u-- uuuu

u1-- uuuu

WDT Wake-up from Sleep

Brown-out Reset

PC + 1

0000h

Interrupt Wake-up from Sleep

RESETInstruction Executed

Stack Overflow Reset (STVREN = 1)

Stack Underflow Reset (STVREN = 1)

PC + 1⁽¹⁾

0000h

Legend: u= unchanged, x= unknown, -= unimplemented bit, reads as ‘0’.

Note 1: When the wake-up is due to an interrupt and Global Enable bit (GIE) is set, the return address is pushed on

the stack and PC is loaded with the interrupt vector (0004h) after execution of PC + 1.

DS40001579E-page 50

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

The PCON register bits are shown in Register 5-2.

5.13 Power Control (PCON) Register

The Power Control (PCON) register contains flag bits

to differentiate between a:

• Power-on Reset (POR)

• Brown-out Reset (BOR)

• Reset Instruction Reset (RI)

• MCLR Reset (RMCLR)

• Watchdog Timer Reset (RWDT)

• Stack Underflow Reset (STKUNF)

• Stack Overflow Reset (STKOVF)

5.14 Register Definitions: Power Control

REGISTER 5-2:

PCON: POWER CONTROL REGISTER

R/W/HS-0/q R/W/HS-0/q

U-0

—

R/W/HC-1/q R/W/HC-1/q R/W/HC-1/q R/W/HC-q/u R/W/HC-q/u

STKOVF

bit 7

STKUNF

RWDT

RMCLR

RI

POR

BOR

bit 0

Legend:

HC = Bit is cleared by hardware

HS = Bit is set by hardware

U = Unimplemented bit, read as ‘0’

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

-m/n = Value at POR and BOR/Value at all other Resets

q = Value depends on condition

bit 7

bit 6

STKOVF: Stack Overflow Flag bit

1= A Stack Overflow occurred

0= A Stack Overflow has not occurred or cleared by firmware

STKUNF: Stack Underflow Flag bit

1= A Stack Underflow occurred

0= A Stack Underflow has not occurred or cleared by firmware

bit 5

bit 4

Unimplemented: Read as ‘0’

RWDT: Watchdog Timer Reset Flag bit

1= A Watchdog Timer Reset has not occurred or set to ‘1’ by firmware

0= A Watchdog Timer Reset has occurred (cleared by hardware)

bit 3

bit 2

bit 1

bit 0

RMCLR: MCLR Reset Flag bit

1= A MCLR Reset has not occurred or set to ‘1’ by firmware

0= A MCLR Reset has occurred (cleared by hardware)

RI: RESETInstruction Flag bit

1= A RESETinstruction has not been executed or set to ‘1’ by firmware

0= A RESETinstruction has been executed (cleared by hardware)

POR: Power-on Reset Status bit

1= No Power-on Reset occurred

0= A Power-on Reset occurred (must be set in software after a Power-on Reset occurs)

BOR: Brown-out Reset Status bit

1= No Brown-out Reset occurred

0= A Brown-out Reset occurred (must be set in software after a Power-on Reset or Brown-out Reset

occurs)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 51

PIC16(L)F1782/3

TABLE 5-5:

Name

SUMMARY OF REGISTERS ASSOCIATED WITH RESETS

Register

on Page

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

BORCON SBOREN BORFS

—

RWDT

TO

—

RMCLR

PD

—

RI

Z

—

POR

DC

BORRDY

BOR

47

51

18

94

PCON

STKOVF STKUNF

STATUS

WDTCON

—

C

WDTPS<4:0>

SWDTEN

Legend: — = unimplemented location, read as ‘0’. Shaded cells are not used by Resets.

DS40001579E-page 52

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

The oscillator module can be configured in one of eight

clock modes.

6.0

6.1

OSCILLATOR MODULE (WITH

FAIL-SAFE CLOCK MONITOR)

1. ECL – External Clock Low-Power mode

(0 MHz to 0.5 MHz)

Overview

2. ECM – External Clock Medium-Power mode

(0.5 MHz to 4 MHz)

The oscillator module has a wide variety of clock

sources and selection features that allow it to be used

in a wide range of applications while maximizing perfor-

mance and minimizing power consumption. Figure 6-1

illustrates a block diagram of the oscillator module.

3. ECH – External Clock High-Power mode

(4 MHz to 32 MHz)

4. LP – 32 kHz Low-Power Crystal mode.

5. XT – Medium Gain Crystal or Ceramic Resonator

Oscillator mode (up to 4 MHz)

Clock sources can be supplied from external oscillators,

quartz crystal resonators, ceramic resonators and

Resistor-Capacitor (RC) circuits. In addition, the system

clock source can be supplied from one of two internal

oscillators and PLL circuits, with a choice of speeds

selectable via software. Additional clock features

include:

6. HS – High Gain Crystal or Ceramic Resonator

mode (4 MHz to 20 MHz)

7. RC – External Resistor-Capacitor (RC).

8. INTOSC – Internal oscillator (31 kHz to 32 MHz).

Clock Source modes are selected by the FOSC<2:0>

bits in the Configuration Words. The FOSC bits

determine the type of oscillator that will be used when

the device is first powered.

• Selectable system clock source between external

or internal sources via software.

• Two-Speed Start-up mode, which minimizes

latency between external oscillator start-up and

code execution.

The EC clock mode relies on an external logic level

signal as the device clock source. The LP, XT, and HS

clock modes require an external crystal or resonator to

be connected to the device. Each mode is optimized for

a different frequency range. The RC clock mode

requires an external resistor and capacitor to set the

oscillator frequency.

• Fail-Safe Clock Monitor (FSCM) designed to

detect a failure of the external clock source (LP,

XT, HS, EC or RC modes) and switch

automatically to the internal oscillator.

• Oscillator Start-up Timer (OST) ensures stability

of crystal oscillator sources

The INTOSC internal oscillator block produces low,

medium, and high-frequency clock sources,

designated LFINTOSC, MFINTOSC and HFINTOSC.

(see Internal Oscillator Block, Figure 6-1). A wide

selection of device clock frequencies may be derived

from these three clock sources.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 53

PIC16(L)F1782/3

FIGURE 6-1:

SIMPLIFIED PIC^®MCU CLOCK SOURCE BLOCK DIAGRAM

Timer1

Oscillator

Timer1 Clock Source Option

for other modules

T1OSO

T1OSI

T1OSCEN

Enable

Oscillator

T1OSC

01

External

LP, XT, HS, RC, EC

Oscillator

OSC2

OSC1

0

Sleep

10

1

Sleep

FOSC

PSMCMUX

÷ 2

00

01

00

PRIMUX

To CPU and

Peripherals

0

1

4 x PLL

PLLMUX

INTOSC

IRCF<3:0>

1X

16 MHz

8 MHz

1111

Internal

Oscillator

Block

4 MHz

2 MHz

SCS<1:0>

1 MHz

HFPLL

PSMC 64 MHz

500 kHz

250 kHz

125 kHz

62.5 kHz

31.25 kHz

16 MHz

(HFINTOSC)

500 kHz

Source

500 kHz

(MFINTOSC)

31 kHz

Source

31 kHz

0000

31 kHz (LFINTOSC)

WDT, PWRT, Fail-Safe Clock Monitor

Two-Speed Start-up and other modules

PLLEN or

SPLLEN

SCS FOSC<2:0>

PRIMUX

PSMCMUX

PLLMUX

0

1

0

1

0

X

1

0

1

10

01

10

00

XX

=100

=00

≠100

(1)

1

≠00

XXX

X

Note 1: This selection should not be made when the PSMC is using the 64 MHz clock option.

DS40001579E-page 54

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

The Oscillator Start-up Timer (OST) is disabled when

EC mode is selected. Therefore, there is no delay in

operation after a Power-on Reset (POR) or wake-up

from Sleep. Because the PIC^®MCU design is fully

static, stopping the external clock input will have the

effect of halting the device while leaving all data intact.

Upon restarting the external clock, the device will

resume operation as if no time had elapsed.

6.2

Clock Source Types

Clock sources can be classified as external or internal.

External clock sources rely on external circuitry for the

clock source to function. Examples are: oscillator

modules (EC mode), quartz crystal resonators or

ceramic resonators (LP, XT and HS modes) and

Resistor-Capacitor (RC) mode circuits.

Internal clock sources are contained within the

oscillator module. The internal oscillator block has two

internal oscillators and a dedicated Phase-Lock Loop

(HFPLL) that are used to generate three internal

system clock sources: the 16 MHz High-Frequency

Internal Oscillator (HFINTOSC), 500 kHz (MFINTOSC)

and the 31 kHz Low-Frequency Internal Oscillator

(LFINTOSC).

FIGURE 6-2:

EXTERNAL CLOCK (EC)

MODE OPERATION

OSC1/CLKIN

PIC^®MCU

Clock from

Ext. System

OSC2/CLKOUT

(1)

FOSC/4 or

The system clock can be selected between external or

internal clock sources via the System Clock Select

(SCS) bits in the OSCCON register. See Section 6.3

“Clock Switching” for additional information.

I/O

Note 1: Output depends upon CLKOUTEN bit of the

Configuration Words.

6.2.1

EXTERNAL CLOCK SOURCES

6.2.1.2

LP, XT, HS Modes

An external clock source can be used as the device

system clock by performing one of the following

actions:

The LP, XT and HS modes support the use of quartz

crystal resonators or ceramic resonators connected to

OSC1 and OSC2 (Figure 6-3). The three modes select

a low, medium or high gain setting of the internal

inverter-amplifier to support various resonator types

and speed.

• Program the FOSC<2:0> bits in the Configuration

Words to select an external clock source that will

be used as the default system clock upon a

device Reset.

LP Oscillator mode selects the lowest gain setting of the

internal inverter-amplifier. LP mode current consumption

is the least of the three modes. This mode is designed to

drive only 32.768 kHz tuning-fork type crystals (watch

crystals).

• Write the SCS<1:0> bits in the OSCCON register

to switch the system clock source to:

- Timer1 oscillator during run-time, or

- An external clock source determined by the

value of the FOSC bits.

XT Oscillator mode selects the intermediate gain

setting of the internal inverter-amplifier. XT mode

current consumption is the medium of the three modes.

This mode is best suited to drive resonators with a

medium drive level specification.

See Section 6.3 “Clock Switching”for more informa-

tion.

6.2.1.1

EC Mode

The External Clock (EC) mode allows an externally

generated logic level signal to be the system clock

source. When operating in this mode, an external clock

source is connected to the OSC1 input.

OSC2/CLKOUT is available for general purpose I/O or

CLKOUT. Figure 6-2 shows the pin connections for EC

mode.

HS Oscillator mode selects the highest gain setting of the

internal inverter-amplifier. HS mode current consumption

is the highest of the three modes. This mode is best

suited for resonators that require a high drive setting.

Figure 6-3 and Figure 6-4 show typical circuits for

quartz crystal and ceramic resonators, respectively.

EC mode has three power modes to select from through

Configuration Words:

• High power, 4-32 MHz (FOSC = 111)

• Medium power, 0.5-4 MHz (FOSC = 110)

• Low power, 0-0.5 MHz (FOSC = 101)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 55

PIC16(L)F1782/3

FIGURE 6-3:

QUARTZ CRYSTAL

OPERATION (LP, XT OR

HS MODE)

FIGURE 6-4:

CERAMIC RESONATOR

OPERATION

(XT OR HS MODE)

PIC^®MCU

OSC1/CLKIN

C1

To Internal

Logic

To Internal

Logic

Quartz

Crystal

(2)

Sleep

RF

(3)

(2)

RP

RF

Sleep

OSC2/CLKOUT

(1)

C2

RS

OSC2/CLKOUT

(1)

C2

RS

Ceramic

Resonator

Note 1: A series resistor (RS) may be required for

quartz crystals with low drive level.

ceramic resonators with low drive level.

2: The value of RF varies with the Oscillator mode

selected (typically between 2 M to 10 M.

2: The value of RF varies with the Oscillator mode

selected (typically between 2 M to 10 M.

3: An additional parallel feedback resistor (RP)

may be required for proper ceramic resonator

operation.

Note 1: Quartz

crystal

characteristics

vary

according to type, package and

manufacturer. The user should consult the

manufacturer data sheets for specifications

and recommended application.

6.2.1.3

Oscillator Start-up Timer (OST)

If the oscillator module is configured for LP, XT or HS

modes, the Oscillator Start-up Timer (OST) counts

1024 oscillations from OSC1. This occurs following a

Power-on Reset (POR) and when the Power-up Timer

(PWRT) has expired (if configured), or a wake-up from

Sleep. During this time, the program counter does not

increment and program execution is suspended,

unless either FSCM or Two-Speed Start-Up are

enabled. In this case, code will continue to execute at

the selected INTOSC frequency while the OST is

counting. The OST ensures that the oscillator circuit,

using a quartz crystal resonator or ceramic resonator,

has started and is providing a stable system clock to

the oscillator module.

2: Always verify oscillator performance over

the VDD and temperature range that is

expected for the application.

3: For oscillator design assistance, reference

the following Microchip Applications Notes:

• AN826, “Crystal Oscillator Basics and

Crystal Selection for rfPIC^®and PIC^®

Devices” (DS00826)

• AN849, “Basic PIC^®Oscillator Design”

(DS00849)

• AN943, “Practical PIC^®Oscillator

Analysis and Design” (DS00943)

• AN949, “Making Your Oscillator Work”

(DS00949)

In order to minimize latency between external oscillator

start-up and code execution, the Two-Speed Clock

Start-up mode can be selected (see Section 6.4

“Two-Speed Clock Start-up Mode”).

DS40001579E-page 56

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

6.2.1.4

4x PLL

Note 1: Quartz

crystal

characteristics

vary

The oscillator module contains a 4x PLL that can be

used with both external and internal clock sources to

provide a system clock source. The input frequency for

the 4x PLL must fall within specifications. See the PLL

Clock Timing Specifications in Section 30.0

“Electrical Specifications”.

according to type, package and

manufacturer. The user should consult the

manufacturer data sheets for specifications

and recommended application.

2: Always verify oscillator performance over

the VDD and temperature range that is

expected for the application.

The 4x PLL may be enabled for use by one of two

methods:

3: For oscillator design assistance, reference

1. Program the PLLEN bit in Configuration Words

the following Microchip Applications Notes:

to a ‘1’.

• AN826, “Crystal Oscillator Basics and

Crystal Selection for rfPIC^®and PIC^®

Devices” (DS00826)

• AN849, “Basic PIC^®Oscillator Design”

2. Write the SPLLEN bit in the OSCCON register to

a ‘1’. If the PLLEN bit in Configuration Words is

programmed to a ‘1’, then the value of SPLLEN

is ignored.

(DS00849)

• AN943, “Practical PIC^®Oscillator

Analysis and Design” (DS00943)

6.2.1.5

TIMER1 Oscillator

The Timer1 oscillator is a separate crystal oscillator

that is associated with the Timer1 peripheral. It is opti-

mized for timekeeping operations with a 32.768 kHz

crystal connected between the T1OSO and T1OSI

device pins.

• AN949, “Making Your Oscillator Work”

(DS00949)

• TB097, “Interfacing a Micro Crystal

MS1V-T1K 32.768 kHz Tuning Fork

Crystal to a PIC16F690/SS” (DS91097)

The Timer1 oscillator can be used as an alternate

system clock source and can be selected during

run-time using clock switching. Refer to Section 6.3

“Clock Switching” for more information.

• AN1288, “Design Practices for

Low-Power External Oscillators”

(DS01288)

FIGURE 6-5:

QUARTZ CRYSTAL

OPERATION (TIMER1

OSCILLATOR)

PIC^®MCU

T1OSI

C1

To Internal

Logic

32.768 kHz

Quartz

Crystal

T1OSO

C2

 2011-2014 Microchip Technology Inc.

DS40001579E-page 57

PIC16(L)F1782/3

6.2.1.6

External RC Mode

6.2.2

INTERNAL CLOCK SOURCES

The external Resistor-Capacitor (RC) modes support

the use of an external RC circuit. This allows the

designer maximum flexibility in frequency choice while

keeping costs to a minimum when clock accuracy is not

required.

The device may be configured to use the internal

oscillator block as the system clock by performing one

of the following actions:

• Program the FOSC<2:0> bits in Configuration

Words to select the INTOSC clock source, which

will be used as the default system clock upon a

device Reset.

The RC circuit connects to OSC1. OSC2/CLKOUT is

available for general purpose I/O or CLKOUT. The

function of the OSC2/CLKOUT pin is determined by the

CLKOUTEN bit in Configuration Words.

• Write the SCS<1:0> bits in the OSCCON register

to switch the system clock source to the internal

oscillator during run-time. See Section 6.3

“Clock Switching”for more information.

Figure 6-6 shows the external RC mode connections.

FIGURE 6-6:

EXTERNAL RC MODES

In INTOSC mode, OSC1/CLKIN is available for general

purpose I/O. OSC2/CLKOUT is available for general

purpose I/O or CLKOUT.

VDD

PIC^®MCU

The function of the OSC2/CLKOUT pin is determined

by the CLKOUTEN bit in Configuration Words.

REXT

OSC1/CLKIN

Internal

Clock

The internal oscillator block has two independent

oscillators and a dedicated Phase-Lock Loop, HFPLL

that can produce one of three internal system clock

sources.

CEXT

VSS

1. The HFINTOSC (High-Frequency Internal

Oscillator) is factory calibrated and operates at

16 MHz. The HFINTOSC source is generated

from the 500 kHz MFINTOSC source and the

dedicated Phase-Lock Loop, HFPLL. The

frequency of the HFINTOSC can be

user-adjusted via software using the OSCTUNE

register (Register 6-3).

OSC2/CLKOUT

(1)

FOSC/4 or I/O

Recommended values: 10 k  REXT  100 k, <3V

3 k  REXT  100 k, 3-5V

CEXT > 20 pF, 2-5V

Note 1: Output depends upon CLKOUTEN bit of the

Configuration Words.

2. The MFINTOSC (Medium-Frequency Internal

Oscillator) is factory calibrated and operates at

500 kHz. The frequency of the MFINTOSC can

be user-adjusted via software using the

OSCTUNE register (Register 6-3).

The RC oscillator frequency is a function of the supply

voltage, the resistor (REXT) and capacitor (CEXT) values

and the operating temperature. Other factors affecting

the oscillator frequency are:

3. The LFINTOSC (Low-Frequency Internal

Oscillator) is uncalibrated and operates at

31 kHz.

• threshold voltage variation

• component tolerances

• packaging variations in capacitance

The user also needs to take into account variation due

to tolerance of external RC components used.

DS40001579E-page 58

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

6.2.2.1

HFINTOSC

6.2.2.3

Internal Oscillator Frequency

Adjustment

The High-Frequency Internal Oscillator (HFINTOSC) is

a factory calibrated 16 MHz internal clock source. The

frequency of the HFINTOSC can be altered via

software using the OSCTUNE register (Register 6-3).

The 500 kHz internal oscillator is factory calibrated.

This internal oscillator can be adjusted in software by

writing to the OSCTUNE register (Register 6-3). Since

the HFINTOSC and MFINTOSC clock sources are

derived from the 500 kHz internal oscillator a change in

the OSCTUNE register value will apply to both.

The output of the HFINTOSC connects to a postscaler

and multiplexer (see Figure 6-1). One of multiple

frequencies derived from the HFINTOSC can be

selected via software using the IRCF<3:0> bits of the

OSCCON register. See Section 6.2.2.7 “Internal

Oscillator Clock Switch Timing” for more information.

The default value of the OSCTUNE register is ‘0’. The

value is a 6-bit two’s complement number. A value of

1Fh will provide an adjustment to the maximum

frequency. A value of 20h will provide an adjustment to

the minimum frequency.

The HFINTOSC is enabled by:

• Configure the IRCF<3:0> bits of the OSCCON

register for the desired HF frequency, and

When the OSCTUNE register is modified, the oscillator

frequency will begin shifting to the new frequency. Code

execution continues during this shift. There is no

indication that the shift has occurred.

• FOSC<2:0> = 100, or

• Set the System Clock Source (SCS) bits of the

OSCCON register to ‘1x’.

OSCTUNE does not affect the LFINTOSC frequency.

Operation of features that depend on the LFINTOSC

clock source frequency, such as the Power-up Timer

(PWRT), Watchdog Timer (WDT), Fail-Safe Clock

Monitor (FSCM) and peripherals, are not affected by the

change in frequency.

A fast startup oscillator allows internal circuits to power

up and stabilize before switching to HFINTOSC.

The High Frequency Internal Oscillator Ready bit

(HFIOFR) of the OSCSTAT register indicates when the

HFINTOSC is running.

The High Frequency Internal Oscillator Status Locked

bit (HFIOFL) of the OSCSTAT register indicates when

the HFINTOSC is running within 2% of its final value.

6.2.2.4

LFINTOSC

The Low-Frequency Internal Oscillator (LFINTOSC) is

an uncalibrated 31 kHz internal clock source.

The High Frequency Internal Oscillator Stable bit

(HFIOFS) of the OSCSTAT register indicates when the

HFINTOSC is running within 0.5% of its final value.

The output of the LFINTOSC connects to a multiplexer

(see Figure 6-1). Select 31 kHz, via software, using the

IRCF<3:0> bits of the OSCCON register. See

Section 6.2.2.7 “Internal Oscillator Clock Switch

Timing” for more information. The LFINTOSC is also

the frequency for the Power-up Timer (PWRT),

Watchdog Timer (WDT) and Fail-Safe Clock Monitor

(FSCM).

6.2.2.2

The

MFINTOSC

Medium-Frequency

Internal

Oscillator

(MFINTOSC) is a factory calibrated 500 kHz internal

clock source. The frequency of the MFINTOSC can be

altered via software using the OSCTUNE register

(Register 6-3).

The LFINTOSC is enabled by selecting 31 kHz

(IRCF<3:0> bits of the OSCCON register = 000) as the

system clock source (SCS bits of the OSCCON

register = 1x), or when any of the following are

enabled:

The output of the MFINTOSC connects to a postscaler

and multiplexer (see Figure 6-1). One of nine

frequencies derived from the MFINTOSC can be

selected via software using the IRCF<3:0> bits of the

OSCCON register. See Section 6.2.2.7 “Internal

Oscillator Clock Switch Timing” for more information.

• Configure the IRCF<3:0> bits of the OSCCON

register for the desired LF frequency, and

• FOSC<2:0> = 100, or

The MFINTOSC is enabled by:

• Set the System Clock Source (SCS) bits of the

OSCCON register to ‘1x’

• Configure the IRCF<3:0> bits of the OSCCON

register for the desired HF frequency, and

Peripherals that use the LFINTOSC are:

• FOSC<2:0> = 100, or

• Set the System Clock Source (SCS) bits of the

OSCCON register to ‘1x’

• Power-up Timer (PWRT)

• Watchdog Timer (WDT)

The Medium Frequency Internal Oscillator Ready bit

(MFIOFR) of the OSCSTAT register indicates when the

MFINTOSC is running.

• Fail-Safe Clock Monitor (FSCM)

The Low-Frequency Internal Oscillator Ready bit

(LFIOFR) of the OSCSTAT register indicates when the

LFINTOSC is running.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 59

PIC16(L)F1782/3

6.2.2.5

Internal Oscillator Frequency

Selection

6.2.2.6

32 MHz Internal Oscillator

Frequency Selection

The system clock speed can be selected via software

using the Internal Oscillator Frequency Select bits

IRCF<3:0> of the OSCCON register.

The Internal Oscillator Block can be used with the

4x PLL associated with the External Oscillator Block to

produce a 32 MHz internal system clock source. The

following settings are required to use the 32 MHz

internal clock source:

The output of the 16 MHz HFINTOSC, 500 kHz

MFINTOSC, and 31 kHz LFINTOSC connects to a

postscaler and multiplexer (see Figure 6-1). The

Internal Oscillator Frequency Select bits IRCF<3:0> of

the OSCCON register select the frequency output of the

internal oscillators. One of the following frequencies

can be selected via software:

• The FOSC bits in Configuration Words must be

set to use the INTOSC source as the device

system clock (FOSC<2:0> = 100).

• The SCS bits in the OSCCON register must be

cleared to use the clock determined by

FOSC<2:0> in Configuration Words

(SCS<1:0> = 00).

- 32 MHz (requires 4x PLL)

- 16 MHz

• The IRCF bits in the OSCCON register must be

set to the 8 MHz or 16 MHz HFINTOSC set to use

(IRCF<3:0> = 111x).

- 8 MHz

- 4 MHz

- 2 MHz

• The SPLLEN bit in the OSCCON register must be

set to enable the 4x PLL, or the PLLEN bit of the

Configuration Words must be programmed to a

‘1’.

- 1 MHz

- 500 kHz (default after Reset)

- 250 kHz

- 125 kHz

Note:

When using the PLLEN bit of the

Configuration Words, the 4x PLL cannot

be disabled by software and the SPLLEN

option will not be available.

- 62.5 kHz

- 31.25 kHz

- 31 kHz (LFINTOSC)

The 4x PLL is not available for use with the internal

oscillator when the SCS bits of the OSCCON register

are set to ‘1x’. The SCS bits must be set to ‘00’ to use

the 4x PLL with the internal oscillator.

Note:

Following any Reset, the IRCF<3:0> bits

of the OSCCON register are set to ‘0111’

and the frequency selection is set to

500 kHz. The user can modify the IRCF

bits to select a different frequency.

The IRCF<3:0> bits of the OSCCON register allow

duplicate selections for some frequencies. These dupli-

cate choices can offer system design trade-offs. Lower

power consumption can be obtained when changing

oscillator sources for a given frequency. Faster transi-

tion times can be obtained between frequency changes

that use the same oscillator source.

DS40001579E-page 60

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

6.2.2.7

Internal Oscillator Clock Switch

Timing

When switching between the HFINTOSC, MFINTOSC

and the LFINTOSC, the new oscillator may already be

shut down to save power (see Figure 6-7). If this is the

case, there is a delay after the IRCF<3:0> bits of the

OSCCON register are modified before the frequency

selection takes place. The OSCSTAT register will

reflect the current active status of the HFINTOSC,

MFINTOSC and LFINTOSC oscillators. The sequence

of a frequency selection is as follows:

1. IRCF<3:0> bits of the OSCCON register are

modified.

2. If the new clock is shut down, a clock start-up

delay is started.

3. Clock switch circuitry waits for a falling edge of

the current clock.

4. The current clock is held low and the clock

switch circuitry waits for a rising edge in the new

clock.

5. The new clock is now active.

6. The OSCSTAT register is updated as required.

7. Clock switch is complete.

See Figure 6-7 for more details.

If the internal oscillator speed is switched between two

clocks of the same source, there is no start-up delay

before the new frequency is selected. Clock switching

time delays are shown in Table 6-1.

Start-up delay specifications are located in the

oscillator tables of Section 30.0 “Electrical

Specifications”.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 61

PIC16(L)F1782/3

FIGURE 6-7:

INTERNAL OSCILLATOR SWITCH TIMING

HFINTOSC/

MFINTOSC

LFINTOSC (FSCM and WDT disabled)

HFINTOSC/

MFINTOSC

Start-up Time

2-cycle Sync

Running

LFINTOSC

0

0

IRCF <3:0>

System Clock

HFINTOSC/

MFINTOSC

LFINTOSC (Either FSCM or WDT enabled)

HFINTOSC/

MFINTOSC

2-cycle Sync

Running

LFINTOSC

IRCF <3:0>

0

0

System Clock

LFINTOSC

HFINTOSC/MFINTOSC

LFINTOSC turns off unless WDT or FSCM is enabled

Running

LFINTOSC

Start-up Time 2-cycle Sync

HFINTOSC/

MFINTOSC

= 0

 0

IRCF <3:0>

System Clock

DS40001579E-page 62

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

6.3.3

TIMER1 OSCILLATOR

6.3

Clock Switching

The Timer1 oscillator is a separate crystal oscillator

associated with the Timer1 peripheral. It is optimized

for timekeeping operations with a 32.768 kHz crystal

connected between the T1OSO and T1OSI device

pins.

The system clock source can be switched between

external and internal clock sources via software using

the System Clock Select (SCS) bits of the OSCCON

register. The following clock sources can be selected

using the SCS bits:

The Timer1 oscillator is enabled using the T1OSCEN

control bit in the T1CON register. See Section 22.0

“Timer1 Module with Gate Control” for more

information about the Timer1 peripheral.

• Default system oscillator determined by FOSC

bits in Configuration Words

• Timer1 32 kHz crystal oscillator

• Internal Oscillator Block (INTOSC)

6.3.4

TIMER1 OSCILLATOR READY

(T1OSCR) BIT

6.3.1

SYSTEM CLOCK SELECT (SCS)

BITS

The user must ensure that the Timer1 oscillator is

ready to be used before it is selected as a system clock

source. The Timer1 Oscillator Ready (T1OSCR) bit of

the OSCSTAT register indicates whether the Timer1

oscillator is ready to be used. After the T1OSCR bit is

set, the SCS bits can be configured to select the Timer1

oscillator.

The System Clock Select (SCS) bits of the OSCCON

register selects the system clock source that is used for

the CPU and peripherals.

• When the SCS bits of the OSCCON register = 00,

the system clock source is determined by the

value of the FOSC<2:0> bits in the Configuration

Words.

• When the SCS bits of the OSCCON register = 01,

the system clock source is the Timer1 oscillator.

• When the SCS bits of the OSCCON register = 1x,

the system clock source is chosen by the internal

oscillator frequency selected by the IRCF<3:0>

bits of the OSCCON register. After a Reset, the

SCS bits of the OSCCON register are always

cleared.

Note:

Any automatic clock switch, which may

occur from Two-Speed Start-up or

Fail-Safe Clock Monitor, does not update

the SCS bits of the OSCCON register. The

user can monitor the OSTS bit of the

OSCSTAT register to determine the current

system clock source.

When switching between clock sources, a delay is

required to allow the new clock to stabilize. These

oscillator delays are shown in Table 6-1.

6.3.2

OSCILLATOR START-UP TIMER

STATUS (OSTS) BIT

The Oscillator Start-up Timer Status (OSTS) bit of the

OSCSTAT register indicates whether the system clock

is running from the external clock source, as defined by

the FOSC<2:0> bits in the Configuration Words, or

from the internal clock source. In particular, OSTS

indicates that the Oscillator Start-up Timer (OST) has

timed out for LP, XT or HS modes. The OST does not

reflect the status of the Timer1 oscillator.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 63

PIC16(L)F1782/3

6.4.1

TWO-SPEED START-UP MODE

CONFIGURATION

6.4

Two-Speed Clock Start-up Mode

Two-Speed Start-up mode provides additional power

savings by minimizing the latency between external

oscillator start-up and code execution. In applications

that make heavy use of the Sleep mode, Two-Speed

Start-up will remove the external oscillator start-up

time from the time spent awake and can reduce the

overall power consumption of the device. This mode

allows the application to wake-up from Sleep, perform

a few instructions using the INTOSC internal oscillator

block as the clock source and go back to Sleep without

waiting for the external oscillator to become stable.

Two-Speed Start-up mode is configured by the

following settings:

• IESO (of the Configuration Words) = 1;

Internal/External Switchover bit (Two-Speed

Start-up mode enabled).

• SCS (of the OSCCON register) = 00.

• FOSC<2:0> bits in the Configuration Words

configured for LP, XT or HS mode.

Two-Speed Start-up mode is entered after:

• Power-on Reset (POR) and, if enabled, after

Power-up Timer (PWRT) has expired, or

Two-Speed Start-up provides benefits when the oscil-

lator module is configured for LP, XT or HS modes.

The Oscillator Start-up Timer (OST) is enabled for

these modes and must count 1024 oscillations before

the oscillator can be used as the system clock source.

• Wake-up from Sleep.

If the oscillator module is configured for any mode

other than LP, XT or HS mode, then Two-Speed

Start-up is disabled. This is because the external clock

oscillator does not require any stabilization time after

POR or an exit from Sleep.

If the OST count reaches 1024 before the device

enters Sleep mode, the OSTS bit of the OSCSTAT

register is set and program execution switches to the

external oscillator. However, the system may never

operate from the external oscillator if the time spent

awake is very short.

Note:

Executing a SLEEP instruction will abort

the oscillator start-up time and will cause

the OSTS bit of the OSCSTAT register to

remain clear.

TABLE 6-1:

Switch From

OSCILLATOR SWITCHING DELAYS

Switch To

Frequency

Oscillator Delay

LFINTOSC⁽¹⁾

MFINTOSC⁽¹⁾

HFINTOSC⁽¹⁾

31 kHz

31.25 kHz-500 kHz

31.25 kHz-16 MHz

Sleep/POR

Oscillator Warm-up Delay (TWARM)

Sleep/POR

LFINTOSC

EC, RC⁽¹⁾

DC – 32 MHz

2 cycles

1 cycle of each

Timer1 Oscillator

LP, XT, HS⁽¹⁾

Sleep/POR

32 kHz-20 MHz

1024 Clock Cycles (OST)

MFINTOSC⁽¹⁾

31.25 kHz-500 kHz

31.25 kHz-16 MHz

Any clock source

2 s (approx.)

HFINTOSC⁽¹⁾

Any clock source

PLL inactive

LFINTOSC⁽¹⁾

Timer1 Oscillator

PLL active

31 kHz

1 cycle of each

32 kHz

1024 Clock Cycles (OST)

2 ms (approx.)

16-32 MHz

Note 1: PLL inactive.

DS40001579E-page 64

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

6.4.2

TWO-SPEED START-UP

SEQUENCE

6.4.3

CHECKING TWO-SPEED CLOCK

STATUS

1. Wake-up from Power-on Reset or Sleep.

Checking the state of the OSTS bit of the OSCSTAT

register will confirm if the microcontroller is running

from the external clock source, as defined by the

FOSC<2:0> bits in the Configuration Words, or the

internal oscillator.

2. Instructions begin execution by the internal

oscillator at the frequency set in the IRCF<3:0>

bits of the OSCCON register.

3. OST enabled to count 1024 clock cycles.

4. OST timed out, wait for falling edge of the

internal oscillator.

5. OSTS is set.

6. System clock held low until the next falling edge

of new clock (LP, XT or HS mode).

7. System clock is switched to external clock

source.

FIGURE 6-8:

TWO-SPEED START-UP

INTOSC

TOST

OSC1

0

1

1022 1023

OSC2

Program Counter

PC - N

PC + 1

PC

System Clock

 2011-2014 Microchip Technology Inc.

DS40001579E-page 65

PIC16(L)F1782/3

6.5.3

FAIL-SAFE CONDITION CLEARING

6.5

Fail-Safe Clock Monitor

The Fail-Safe condition is cleared after a Reset,

executing a SLEEPinstruction or changing the SCS bits

of the OSCCON register. When the SCS bits are

changed, the OST is restarted. While the OST is

running, the device continues to operate from the

INTOSC selected in OSCCON. When the OST times

out, the Fail-Safe condition is cleared after successfully

switching to the external clock source. The OSFIF bit

should be cleared prior to switching to the external

clock source. If the Fail-Safe condition still exists, the

OSFIF flag will again become set by hardware.

The Fail-Safe Clock Monitor (FSCM) allows the device

to continue operating should the external oscillator fail.

The FSCM can detect oscillator failure any time after

the Oscillator Start-up Timer (OST) has expired. The

FSCM is enabled by setting the FCMEN bit in the

Configuration Words. The FSCM is applicable to all

external Oscillator modes (LP, XT, HS, EC, Timer1

Oscillator and RC).

FIGURE 6-9:

FSCM BLOCK DIAGRAM

Clock Monitor

Latch

6.5.4

RESET OR WAKE-UP FROM SLEEP

External

Clock

S

Q

The FSCM is designed to detect an oscillator failure

after the Oscillator Start-up Timer (OST) has expired.

The OST is used after waking up from Sleep and after

any type of Reset. The OST is not used with the EC or

RC Clock modes so that the FSCM will be active as

soon as the Reset or wake-up has completed. When

the FSCM is enabled, the Two-Speed Start-up is also

enabled. Therefore, the device will always be executing

code while the OST is operating.

LFINTOSC

Oscillator

÷ 64

R

Q

31 kHz

(~32 s)

488 Hz

(~2 ms)

Sample Clock

Clock

Failure

Detected

Note:

Due to the wide range of oscillator start-up

times, the Fail-Safe circuit is not active

during oscillator start-up (i.e., after exiting

Reset or Sleep). After an appropriate

amount of time, the user should check the

Status bits in the OSCSTAT register to

verify the oscillator start-up and that the

system clock switchover has successfully

completed.

6.5.1

FAIL-SAFE DETECTION

The FSCM module detects a failed oscillator by

comparing the external oscillator to the FSCM sample

clock. The sample clock is generated by dividing the

LFINTOSC by 64. See Figure 6-9. Inside the fail

detector block is a latch. The external clock sets the

latch on each falling edge of the external clock. The

sample clock clears the latch on each rising edge of the

sample clock. A failure is detected when an entire

half-cycle of the sample clock elapses before the

external clock goes low.

6.5.2

FAIL-SAFE OPERATION

When the external clock fails, the FSCM switches the

device clock to an internal clock source and sets the bit

flag OSFIF of the PIR2 register. Setting this flag will

generate an interrupt if the OSFIE bit of the PIE2

register is also set. The device firmware can then take

steps to mitigate the problems that may arise from a

failed clock. The system clock will continue to be

sourced from the internal clock source until the device

firmware successfully restarts the external oscillator

and switches back to external operation.

The internal clock source chosen by the FSCM is

determined by the IRCF<3:0> bits of the OSCCON

register. This allows the internal oscillator to be

configured before a failure occurs.

DS40001579E-page 66

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 6-10:

FSCM TIMING DIAGRAM

Sample Clock

Oscillator

Failure

System

Clock

Output

Clock Monitor Output

(Q)

Failure

Detected

OSCFIF

Test

Note:

The system clock is normally at a much higher frequency than the sample clock. The relative frequencies in

this example have been chosen for clarity.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 67

PIC16(L)F1782/3

6.6

Register Definitions: Oscillator Control

REGISTER 6-1:

OSCCON: OSCILLATOR CONTROL REGISTER

R/W-0/0 R/W-1/1 R/W-1/1 R/W-1/1

IRCF<3:0>

R/W-0/0

SPLLEN

bit 7

U-0

—

R/W-0/0

SCS<1:0>

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

SPLLEN: Software PLL Enable bit

If PLLEN in Configuration Words = 1:

SPLLEN bit is ignored. 4x PLL is always enabled (subject to oscillator requirements)

If PLLEN in Configuration Words = 0:

1= 4x PLL Is enabled

0 = 4x PLL is disabled

bit 6-3

IRCF<3:0>: Internal Oscillator Frequency Select bits

1111= 16 MHz HF or 32 MHz HF⁽²⁾

1110= 8 MHz or 32 MHz HF⁽²⁾

1101= 4 MHz HF

1100= 2 MHz HF

1011= 1 MHz HF

1010= 500 kHz HF⁽¹⁾

1001= 250 kHz HF⁽¹⁾

1000= 125 kHz HF⁽¹⁾

0111= 500 kHz MF (default upon Reset)

0110= 250 kHz MF

0101= 125 kHz MF

0100= 62.5 kHz MF

0011= 31.25 kHz HF⁽¹⁾

0010= 31.25 kHz MF

000x= 31 kHz LF

bit 2

Unimplemented: Read as ‘0’

bit 1-0

SCS<1:0>: System Clock Select bits

1x= Internal oscillator block

01= Timer1 oscillator

00= Clock determined by FOSC<2:0> in Configuration Words.

Note 1: Duplicate frequency derived from HFINTOSC.

2: 32 MHz when SPLLEN bit is set. Refer to Section 6.2.2.6 “32 MHz Internal Oscillator Frequency

Selection”.

DS40001579E-page 68

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 6-2:

OSCSTAT: OSCILLATOR STATUS REGISTER

R-1/q

T1OSCR

bit 7

R-0/q

PLLR

R-q/q

R-0/q

R-q/q

R-0/0

R-0/q

OSTS

HFIOFR

HFIOFL

MFIOFR

LFIOFR

HFIOFS

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

-n/n = Value at POR and BOR/Value at all other Resets

q = Conditional

bit 7

T1OSCR: Timer1 Oscillator Ready bit

If T1OSCEN = 1:

1= Timer1 oscillator is ready

0= Timer1 oscillator is not ready

If T1OSCEN = 0:

1 = Timer1 clock source is always ready

bit 6

bit 5

PLLR 4x PLL Ready bit

1= 4x PLL is ready

0= 4x PLL is not ready

OSTS: Oscillator Start-up Timer Status bit

1= Running from the clock defined by the FOSC<2:0> bits of the Configuration Words

0= Running from an internal oscillator (FOSC<2:0> = 100)

bit 4

bit 3

bit 2

bit 1

bit 0

HFIOFR: High-Frequency Internal Oscillator Ready bit

1= HFINTOSC is ready

0= HFINTOSC is not ready

HFIOFL: High-Frequency Internal Oscillator Locked bit

1= HFINTOSC is at least 2% accurate

0= HFINTOSC is not 2% accurate

MFIOFR: Medium-Frequency Internal Oscillator Ready bit

1= MFINTOSC is ready

0= MFINTOSC is not ready

LFIOFR: Low-Frequency Internal Oscillator Ready bit

1= LFINTOSC is ready

0= LFINTOSC is not ready

HFIOFS: High-Frequency Internal Oscillator Stable bit

1= HFINTOSC is at least 0.5% accurate

0= HFINTOSC is not 0.5% accurate

 2011-2014 Microchip Technology Inc.

DS40001579E-page 69

PIC16(L)F1782/3

REGISTER 6-3:

OSCTUNE: OSCILLATOR TUNING REGISTER

U-0

—

U-0

—

R/W-0/0

bit 0

TUN<5:0>

bit 7

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-6

bit 5-0

Unimplemented: Read as ‘0’

TUN<5:0>: Frequency Tuning bits

100000= Minimum frequency

•

111111=

000000= Oscillator module is running at the factory-calibrated frequency.

000001=

•

011110=

011111= Maximum frequency

TABLE 6-2:

SUMMARY OF REGISTERS ASSOCIATED WITH CLOCK SOURCES

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

OSCCON

OSCSTAT

OSCTUNE

PIE2

SPLLEN

T1OSCR

—

IRCF<3:0>

—

SCS<1:0>

68

69

PLLR

—

OSTS

HFIOFR

HFIOFL

MFIOFR

LFIOFR

HFIOFS

TUN<5:0>

70

OSEIE

OSFIF

C2IE

C2IF

C1IE

C1IF

EEIE

EEIF

BCL1IE

BCL1IF

—

C3IE

C3IF

—

CCP2IE

CCP2IF

81

PIR2

84

T1CON

TMR1CS<1:0>

T1CKPS<1:0>

T1OSCEN

T1SYNC

TMR1ON

183

Legend:

— = unimplemented location, read as ‘0’. Shaded cells are not used by clock sources.

TABLE 6-3:

SUMMARY OF CONFIGURATION WORD WITH CLOCK SOURCES

Register

on Page

Name

Bits

Bit -/7

Bit -/6

Bit 13/5

Bit 12/4

Bit 11/3

Bit 10/2

Bit 9/1

Bit 8/0

13:8

7:0

—

FCMEN

PWRTE

IESO

CLKOUTEN

BOREN<1:0>

FOSC<2:0>

CPD

CONFIG1

40

CP

MCLRE

WDTE<1:0>

Legend:

Note 1:

— = unimplemented location, read as ‘0’. Shaded cells are not used by clock sources.

PIC16F1782/3 only.

DS40001579E-page 70

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

7.3

Conflicts with the CLKR Pin

7.0

REFERENCE CLOCK MODULE

There are two cases when the reference clock output

signal cannot be output to the CLKR pin, if:

The reference clock module provides the ability to send

a divided clock to the clock output pin of the device

(CLKR). This module is available in all oscillator config-

urations and allows the user to select a greater range

of clock submultiples to drive external devices in the

application. The reference clock module includes the

following features:

• LP, XT or HS Oscillator mode is selected.

• CLKOUT function is enabled.

7.3.1

OSCILLATOR MODES

If LP, XT or HS oscillator modes are selected, the

OSC2/CLKR pin must be used as an oscillator input pin

and the CLKR output cannot be enabled. See

Section 6.2 “Clock Source Types”for more informa-

tion on different oscillator modes.

• System clock is the source

• Available in all oscillator configurations

• Programmable clock divider

• Output enable to a port pin

• Selectable duty cycle

7.3.2

CLKOUT FUNCTION

• Slew rate control

The CLKOUT function has a higher priority than the

reference clock module. Therefore, if the CLKOUT

function is enabled by the CLKOUTEN bit in Configura-

tion Words, FOSC/4 will always be output on the port

pin. Reference Section 4.0 “Device Configuration”

for more information.

The reference clock module is controlled by the

CLKRCON register (Register 7-1) and is enabled when

setting the CLKREN bit. To output the divided clock

signal to the CLKR port pin, the CLKROE bit must be

set. The CLKRDIV<2:0> bits enable the selection of

eight

different

clock

divider

options.

The

CLKRDC<1:0> bits can be used to modify the duty

cycle of the output clock⁽¹⁾. The CLKRSLR bit controls

slew rate limiting.

7.4

Operation During Sleep

As the reference clock module relies on the system

clock as its source, and the system clock is disabled in

Sleep, the module does not function in Sleep, even if

an external clock source or the Timer1 clock source is

configured as the system clock. The module outputs

will remain in their current state until the device exits

Sleep.

Note 1: If the base clock rate is selected without

a divider, the output clock will always

have a duty cycle equal to that of the

source clock, unless a 0% duty cycle is

selected. If the clock divider is set to base

clock/2, then 25% and 75% duty cycle

accuracy will be dependent upon the

source clock.

7.1

Slew Rate

The slew rate limitation on the output port pin can be

disabled. The slew rate limitation is removed by

clearing the CLKRSLR bit in the CLKRCON register.

7.2

Effects of a Reset

Upon any device Reset, the reference clock module is

disabled. The user’s firmware is responsible for

initializing the module before enabling the output. The

registers are reset to their default values.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 71

PIC16(L)F1782/3

7.5

Register Definition: Reference Clock Control

REGISTER 7-1:

CLKRCON: REFERENCE CLOCK CONTROL REGISTER

R/W-0/0

CLKREN

bit 7

R/W-0/0

R/W-1/1

R/W-0/0

CLKROE

CLKRSLR

CLKRDC<1:0>

CLKRDIV<2:0>

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

CLKREN: Reference Clock Module Enable bit

1= Reference clock module is enabled

0= Reference clock module is disabled

bit 6

CLKROE: Reference Clock Output Enable bit

1= Reference clock output is enabled on CLKR pin

0= Reference clock output disabled on CLKR pin

bit 5

CLKRSLR: Reference Clock Slew Rate Control Limiting Enable bit

1= Slew rate limiting is enabled

0= Slew rate limiting is disabled

bit 4-3

CLKRDC<1:0>: Reference Clock Duty Cycle bits

11= Clock outputs duty cycle of 75%

10= Clock outputs duty cycle of 50%

01= Clock outputs duty cycle of 25%

00= Clock outputs duty cycle of 0%

bit 2-0

CLKRDIV<2:0> Reference Clock Divider bits

111= Base clock value divided by 128

110= Base clock value divided by 64

101= Base clock value divided by 32

100= Base clock value divided by 16

011= Base clock value divided by 8

010= Base clock value divided by 4

001= Base clock value divided by 2⁽¹⁾

000= Base clock value⁽²⁾

Note 1: In this mode, the 25% and 75% duty cycle accuracy will be dependent on the source clock duty cycle.

2: In this mode, the duty cycle will always be equal to the source clock duty cycle, unless a duty cycle of 0%

is selected.

3: To route CLKR to pin, CLKOUTEN of Configuration Words = 1is required. CLKOUTEN of Configuration

Words = 0will result in FOSC/4. See Section 7.3 “Conflicts with the CLKR Pin” for details.

DS40001579E-page 72

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 7-1:

Name

SUMMARY OF REGISTERS ASSOCIATED WITH REFERENCE CLOCK SOURCES

Register

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

on Page

CLKRCON

CLKREN

CLKROE CLKRSLR

CLKRDC<1:0>

CLKRDIV<2:0>

72

Legend:

— = unimplemented locations read as ‘0’. Shaded cells are not used by reference clock sources.

TABLE 7-2:

SUMMARY OF CONFIGURATION WORD WITH REFERENCE CLOCK SOURCES

Register

on Page

Name

Bits

Bit -/7

Bit -/6

Bit 13/5

Bit 12/4

Bit 11/3

Bit 10/2

Bit 9/1

Bit 8/0

13:8

7:0

—

FCMEN

PWRTE

IESO

CLKOUTEN

BOREN<1:0>

FOSC<2:0>

CPD

CONFIG1

40

CP

MCLRE

WDTE1<:0>

Legend:

— = unimplemented locations read as ‘0’. Shaded cells are not used by reference clock sources.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 73

PIC16(L)F1782/3

8.0

INTERRUPTS

The interrupt feature allows certain events to preempt

normal program flow. Firmware is used to determine

the source of the interrupt and act accordingly. Some

interrupts can be configured to wake the MCU from

Sleep mode.

This chapter contains the following information for

Interrupts:

• Operation

• Interrupt Latency

• Interrupts During Sleep

• INT Pin

• Automatic Context Saving

Many peripherals produce interrupts. Refer to the

corresponding chapters for details.

A block diagram of the interrupt logic is shown in

Figure 8-1.

FIGURE 8-1:

INTERRUPT LOGIC

TMR0IF

TMR0IE

Wake-up

(If in Sleep mode)

INTF

INTE

Peripheral Interrupts

(TMR1IF) PIR1<0>

(TMR1IE) PIE1<0>

IOCIF

IOCIE

Interrupt

to CPU

PEIE

GIE

PIRn<7>

PIEn<7>

DS40001579E-page 74

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

8.1

Operation

8.2

Interrupt Latency

Interrupts are disabled upon any device Reset. They

are enabled by setting the following bits:

Interrupt latency is defined as the time from when the

interrupt event occurs to the time code execution at the

interrupt vector begins. The latency for synchronous

interrupts is three or four instruction cycles. For

asynchronous interrupts, the latency is three to five

instruction cycles, depending on when the interrupt

occurs. See Figure 8-2 and Figure 8.3 for more details.

• GIE bit of the INTCON register

• Interrupt Enable bit(s) for the specific interrupt

event(s)

• PEIE bit of the INTCON register (if the Interrupt

Enable bit of the interrupt event is contained in the

PIE1 or PIE2 registers)

The INTCON, PIR1 and PIR2 registers record individ-

ual interrupts via interrupt flag bits. Interrupt flag bits will

be set, regardless of the status of the GIE, PEIE and

individual interrupt enable bits.

The following events happen when an interrupt event

occurs while the GIE bit is set:

• Current prefetched instruction is flushed

• GIE bit is cleared

• Current Program Counter (PC) is pushed onto the

stack

• Critical registers are automatically saved to the

shadow registers (See “Section 8.5 “Automatic

Context Saving”.”)

• PC is loaded with the interrupt vector 0004h

The firmware within the Interrupt Service Routine (ISR)

should determine the source of the interrupt by polling

the interrupt flag bits. The interrupt flag bits must be

cleared before exiting the ISR to avoid repeated

interrupts. Because the GIE bit is cleared, any interrupt

that occurs while executing the ISR will be recorded

through its interrupt flag, but will not cause the

processor to redirect to the interrupt vector.

The RETFIE instruction exits the ISR by popping the

previous address from the stack, restoring the saved

context from the shadow registers and setting the GIE

bit.

For additional information on a specific interrupt’s

operation, refer to its peripheral chapter.

Note 1: Individual interrupt flag bits are set,

regardless of the state of any other

enable bits.

2: All interrupts will be ignored while the GIE

bit is cleared. Any interrupt occurring

while the GIE bit is clear will be serviced

when the GIE bit is set again.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 75

PIC16(L)F1782/3

FIGURE 8-2:

INTERRUPT LATENCY

OSC1

Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4

CLKR

Interrupt Sampled

during Q1

Interrupt

GIE

PC-1

PC

PC+1

0004h

0005h

PC

1 Cycle Instruction at PC

Execute

Inst(PC)

NOP

Inst(0004h)

Interrupt

GIE

PC+1/FSR

ADDR

New PC/

PC+1

PC-1

PC

0004h

0005h

PC

Execute

2 Cycle Instruction at PC

Inst(PC)

NOP

Inst(0004h)

Interrupt

GIE

PC-1

PC

FSR ADDR

INST(PC)

PC+1

PC+2

0004h

0005h

PC

Execute

3 Cycle Instruction at PC

NOP

Inst(0004h)

Inst(0005h)

Interrupt

GIE

PC-1

PC

FSR ADDR

INST(PC)

PC+1

PC+2

0004h

0005h

PC

NOP

Execute

3 Cycle Instruction at PC

NOP

Inst(0004h)

DS40001579E-page 76

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 8-3:

INT PIN INTERRUPT TIMING

Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4

OSC1

(3)

CLKOUT

(4)

INT pin

INTF

(1)

(2)

(5)

Interrupt Latency

GIE

INSTRUCTION FLOW

PC

PC + 1

—

0004h

0005h

PC

Inst (PC)

PC + 1

Instruction

Fetched

Inst (PC + 1)

Inst (0004h)

Inst (0005h)

Inst (0004h)

Instruction

Executed

Forced NOP

Inst (PC)

Inst (PC – 1)

Note 1: INTF flag is sampled here (every Q1).

2: Asynchronous interrupt latency = 3-5 TCY. Synchronous latency = 3-4 TCY, where TCY = instruction cycle time.

Latency is the same whether Inst (PC) is a single cycle or a 2-cycle instruction.

3: CLKOUT not available in all oscillator modes.

4: For minimum width of INT pulse, refer to AC specifications in Section 30.0 “Electrical Specifications””.

5: INTF is enabled to be set any time during the Q4-Q1 cycles.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 77

PIC16(L)F1782/3

8.3

Interrupts During Sleep

Some interrupts can be used to wake from Sleep. To

wake from Sleep, the peripheral must be able to

operate without the system clock. The interrupt source

must have the appropriate Interrupt Enable bit(s) set

prior to entering Sleep.

On waking from Sleep, if the GIE bit is also set, the

processor will branch to the interrupt vector. Otherwise,

the processor will continue executing instructions after

the SLEEPinstruction. The instruction directly after the

SLEEP instruction will always be executed before

branching to the ISR. Refer to Section 9.0

“Power-Down Mode (Sleep)” for more details.

8.4

INT Pin

The INT pin can be used to generate an asynchronous

edge-triggered interrupt. This interrupt is enabled by

setting the INTE bit of the INTCON register. The

INTEDG bit of the OPTION_REG register determines on

which edge the interrupt will occur. When the INTEDG

bit is set, the rising edge will cause the interrupt. When

the INTEDG bit is clear, the falling edge will cause the

interrupt. The INTF bit of the INTCON register will be set

when a valid edge appears on the INT pin. If the GIE and

INTE bits are also set, the processor will redirect

program execution to the interrupt vector.

8.5

Automatic Context Saving

Upon entering an interrupt, the return PC address is

saved on the stack. Additionally, the following registers

are automatically saved in the shadow registers:

• W register

• STATUS register (except for TO and PD)

• BSR register

• FSR registers

• PCLATH register

Upon exiting the Interrupt Service Routine, these regis-

ters are automatically restored. Any modifications to

these registers during the ISR will be lost. If modifica-

tions to any of these registers are desired, the corre-

sponding shadow register should be modified and the

value will be restored when exiting the ISR. The

shadow registers are available in Bank 31 and are

readable and writable. Depending on the user’s

application, other registers may also need to be saved.

DS40001579E-page 78

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

8.6

Register Definitions: Interrupt Control

REGISTER 8-1:

INTCON: INTERRUPT CONTROL REGISTER

R/W-0/0

GIE

R/W-0/0

PEIE

R/W-0/0

TMR0IE

R/W-0/0

INTE

R/W-0/0

IOCIE

R/W-0/0

TMR0IF

R/W-0/0

INTF

R-0/0

IOCIF⁽¹⁾

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

GIE: Global Interrupt Enable bit

1= Enables all active interrupts

0= Disables all interrupts

bit 6

bit 5

bit 4

bit 3

bit 2

bit 1

bit 0

PEIE: Peripheral Interrupt Enable bit

1= Enables all active peripheral interrupts

0= Disables all peripheral interrupts

TMR0IE: Timer0 Overflow Interrupt Enable bit

1= Enables the Timer0 interrupt

0= Disables the Timer0 interrupt

INTE: INT External Interrupt Enable bit

1= Enables the INT external interrupt

0= Disables the INT external interrupt

IOCIE: Interrupt-on-Change Enable bit

1= Enables the interrupt-on-change

0= Disables the interrupt-on-change

TMR0IF: Timer0 Overflow Interrupt Flag bit

1= TMR0 register has overflowed

0= TMR0 register did not overflow

INTF: INT External Interrupt Flag bit

1= The INT external interrupt occurred

0= The INT external interrupt did not occur

IOCIF: Interrupt-on-Change Interrupt Flag bit⁽¹⁾

1= When at least one of the interrupt-on-change pins changed state

0= None of the interrupt-on-change pins have changed state

Note 1: The IOCIF Flag bit is read-only and cleared when all the Interrupt-on-change flags in the IOCBF register

have been cleared by software.

Note:

Interrupt flag bits are set when an interrupt

condition occurs, regardless of the state of

its corresponding enable bit or the Global

Enable bit, GIE, of the INTCON register.

User software should ensure the

appropriate interrupt flag bits are clear

prior to enabling an interrupt.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 79

PIC16(L)F1782/3

REGISTER 8-2:

PIE1: PERIPHERAL INTERRUPT ENABLE REGISTER 1

R/W-0/0

TMR1GIE

bit 7

R/W-0/0

ADIE

R/W-0/0

RCIE

R/W-0/0

TXIE

R/W-0/0

SSP1IE

R/W-0/0

CCP1IE

R/W-0/0

TMR2IE

R/W-0/0

TMR1IE

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

bit 6

bit 5

bit 4

bit 3

bit 2

bit 1

bit 0

TMR1GIE: Timer1 Gate Interrupt Enable bit

1= Enables the Timer1 gate acquisition interrupt

0= Disables the Timer1 gate acquisition interrupt

ADIE: Analog-to-Digital Converter (ADC) Interrupt Enable bit

1= Enables the ADC interrupt

0= Disables the ADC interrupt

RCIE: USART Receive Interrupt Enable bit

1= Enables the USART receive interrupt

0= Disables the USART receive interrupt

TXIE: USART Transmit Interrupt Enable bit

1= Enables the USART transmit interrupt

0= Disables the USART transmit interrupt

SSP1IE: Synchronous Serial Port (MSSP) Interrupt Enable bit

1= Enables the MSSP interrupt

0= Disables the MSSP interrupt

CCP1IE: CCP1 Interrupt Enable bit

1= Enables the CCP1 interrupt

0= Disables the CCP1 interrupt

TMR2IE: TMR2 to PR2 Match Interrupt Enable bit

1= Enables the Timer2 to PR2 match interrupt

0= Disables the Timer2 to PR2 match interrupt

TMR1IE: Timer1 Overflow Interrupt Enable bit

1= Enables the Timer1 overflow interrupt

0= Disables the Timer1 overflow interrupt

Note:

Bit PEIE of the INTCON register must be

set to enable any peripheral interrupt.

DS40001579E-page 80

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 8-3:

PIE2: PERIPHERAL INTERRUPT ENABLE REGISTER 2

R/W-0/0

OSFIE

bit 7

R/W-0/0

C2IE

R/W-0/0

C1IE

R/W-0/0

EEIE

R/W-0/0

BCL1IE

U-0

—

R/W-0/0

C3IE

R/W-0/0

CCP2IE

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

bit 6

bit 5

bit 4

bit 3

OSFIE: Oscillator Fail Interrupt Enable bit

1= Enables the Oscillator Fail interrupt

0= Disables the Oscillator Fail interrupt

C2IE: Comparator C2 Interrupt Enable bit

1= Enables the Comparator C2 interrupt

0= Disables the Comparator C2 interrupt

C1IE: Comparator C1 Interrupt Enable bit

1= Enables the Comparator C1 interrupt

0= Disables the Comparator C1 interrupt

EEIE: EEPROM Write Completion Interrupt Enable bit

1= Enables the EEPROM Write Completion interrupt

0= Disables the EEPROM Write Completion interrupt

BCL1IE: MSSP Bus Collision Interrupt Enable bit

1= Enables the MSSP Bus Collision Interrupt

0= Disables the MSSP Bus Collision Interrupt

bit 2

bit 1

Unimplemented: Read as ‘0’

C3IE: Comparator C3 Interrupt Enable bit

1= Enables the Comparator C3 Interrupt

0= Disables the Comparator C3 Interrupt

bit 0

CCP2IE: CCP2 Interrupt Enable bit

1= Enables the CCP2 interrupt

0= Disables the CCP2 interrupt

Note:

Bit PEIE of the INTCON register must be

set to enable any peripheral interrupt.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 81

PIC16(L)F1782/3

REGISTER 8-4:

PIE4: PERIPHERAL INTERRUPT ENABLE REGISTER 4

U-0

—

U-0

—

R/W-0/0

U-0

—

U-0

—

R/W-0/0

PSMC2TIE PSMC1TIE

PSMC2SIE PSMC1SIE

bit 0

bit 7

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-6

bit 5

Unimplemented: Read as ‘0’

PSMC2TIE: PSMC2 Time Base Interrupt Enable bit

1= Enables PSMC2 time base generated interrupts

0= Disables PSMC2 time base generated interrupts

bit 4

PSMC1TIE: PSMC1 Time Base Interrupt Enable bit

1= Enables PSMC1 time base generated interrupts

0= Disables PSMC1 time base generated interrupts

bit 3-2

bit 1

Unimplemented: Read as ‘0’

PSMC2SIE: PSMC2 Auto-Shutdown Interrupt Enable bit

1= Enables PSMC2 auto-shutdown interrupts

0= Disables PSMC2 auto-shutdown interrupts

bit 0

PSMC1SIE: PSMC1 Auto-Shutdown Interrupt Enable bit

1= Enables PSMC1 auto-shutdown interrupts

0= Disables PSMC1 auto-shutdown interrupts

Note:

Bit PEIE of the INTCON register must be

set to enable any peripheral interrupt.

DS40001579E-page 82

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 8-5:

PIR1: PERIPHERAL INTERRUPT REQUEST REGISTER 1

R/W-0/0

TMR1GIF

bit 7

R/W-0/0

ADIF

R-0/0

RCIF

R-0/0

TXIF

R/W-0/0

SSP1IF

R/W-0/0

CCP1IF

R/W-0/0

TMR2IF

R/W-0/0

TMR1IF

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7

bit 6

bit 5

bit 4

bit 3

bit 2

bit 1

bit 0

TMR1GIF: Timer1 Gate Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

ADIF: ADC Converter Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

RCIF: USART Receive Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

TXIF: USART Transmit Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

SSP1IF: Synchronous Serial Port (MSSP) Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

CCP1IF: CCP1 Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

TMR2IF: Timer2 to PR2 Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

TMR1IF: Timer1 Overflow Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

Note:

Interrupt flag bits are set when an interrupt

condition occurs, regardless of the state of

its corresponding enable bit or the Global

Enable bit, GIE, of the INTCON register.

User software should ensure the

appropriate interrupt flag bits are clear

prior to enabling an interrupt.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 83

PIC16(L)F1782/3

REGISTER 8-6:

PIR2: PERIPHERAL INTERRUPT REQUEST REGISTER 2

R/W-0/0

OSFIF

R/W-0/0

C2IF

R/W-0/0

C1IF

R/W-0/0

EEIF

R/W-0/0

BCL1IF

U-0

—

R/W-0/0

C3IF

R/W-0/0

CCP2IF

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

bit 6

bit 5

bit 4

bit 3

OSFIF: Oscillator Fail Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

C2IF: Comparator C2 Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

C1IF: Comparator C1 Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

EEIF: EEPROM Write Completion Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

BCL1IF: MSSP Bus Collision Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

bit 2

bit 1

Unimplemented: Read as ‘0’

C3IF: Comparator C3 Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

bit 0

CCP2IF: CCP2 Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

Note:

Interrupt flag bits are set when an interrupt

condition occurs, regardless of the state of

its corresponding enable bit or the Global

Enable bit, GIE, of the INTCON register.

User software should ensure the

appropriate interrupt flag bits are clear

prior to enabling an interrupt.

DS40001579E-page 84

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 8-7:

PIR4: PERIPHERAL INTERRUPT REQUEST REGISTER 4

U-0

—

U-0

—

R/W-0/0

U-0

—

U-0

—

R/W-0/0

PSMC2TIF PSMC1TIF

PSMC2SIF PSMC1SIF

bit 0

bit 7

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-6

bit 5

Unimplemented: Read as ‘0’

PSMC2TIF: PSMC2 Time Base Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

bit 4

PSMC1TIF: PSMC1 Time Base Interrupt Flag bit

1= Interrupt is pending

0= Interrupt is not pending

bit 3-2

bit 1

Unimplemented: Read as ‘0’

PSMC2SIF: PSMC2 Auto-shutdown Flag bit

1= Interrupt is pending

0= Interrupt is not pending

bit 0

PSMC1SIF: PSMC1 Auto-shutdown Flag bit

1= Interrupt is pending

0= Interrupt is not pending

Note:

Interrupt flag bits are set when an interrupt

condition occurs, regardless of the state of

its corresponding enable bit or the Global

Enable bit, GIE, of the INTCON register.

User software should ensure the

appropriate interrupt flag bits are clear

prior to enabling an interrupt.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 85

PIC16(L)F1782/3

TABLE 8-1:

SUMMARY OF REGISTERS ASSOCIATED WITH INTERRUPTS

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

INTCON

OPTION_REG

PIE1

GIE

PEIE

INTEDG

ADIE

TMR0IE

TMR0CS

RCIE

INTE

TMR0SE

TXIE

IOCIE

PSA

TMR0IF

INTF

PS<2:0>

TMR2IE

C3IE

IOCIF

79

174

80

81

—

WPUEN

TMR1GIE

OSEIE

SSP1IE

BCL1IE

CCP1IE

—

TMR1IE

CCP2IE

PIE2

C2IE

C1IE

EEIE

—

Unimplemented

—

PIE4

—

PSMC2TIE PSMC1TIE

—

CCP1IF

—

PSMC2SIE PSMC1SIE

82

83

84

—

PIR1

TMR1GIF

OSFIF

ADIF

C2IF

RCIF

C1IF

TXIF

EEIF

SSP1IF

BCL1IF

TMR2IF

C3IF

TMR1IF

CCP2IF

PIR2

—

Unimplemented

—

PIR4

—

PSMC2TIF PSMC1TIF

—

PSMC2SIF PSMC1SIF

85

Legend:

— = unimplemented location, read as ‘0’. Shaded cells are not used by interrupts.

DS40001579E-page 86

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

9.1

Wake-up from Sleep

9.0

POWER-DOWN MODE (SLEEP)

The device can wake-up from Sleep through one of the

following events:

The Power-down mode is entered by executing a

SLEEPinstruction.

1. External Reset input on MCLR pin, if enabled

2. BOR Reset, if enabled

Upon entering Sleep mode, the following conditions

exist:

3. POR Reset

1. WDT will be cleared but keeps running, if

enabled for operation during Sleep.

4. Watchdog Timer, if enabled

5. Any external interrupt

2. PD bit of the STATUS register is cleared.

3. TO bit of the STATUS register is set.

4. CPU clock is disabled.

6. Interrupts by peripherals capable of running

during Sleep (see individual peripheral for more

information)

5. 31 kHz LFINTOSC is unaffected and peripherals

that operate from it may continue operation in

Sleep.

The first three events will cause a device Reset. The

last three events are considered a continuation of

program execution. To determine whether a device

Reset or wake-up event occurred, refer to

Section 5.12 “Determining the Cause of a Reset”.

6. Timer1 and peripherals that operate from Tim-

er1 continue operation in Sleep when the Tim-

er1 clock source selected is:

•

LFINTOSC

T1CKI

When the SLEEPinstruction is being executed, the next

instruction (PC + 1) is prefetched. For the device to

wake-up through an interrupt event, the corresponding

interrupt enable bit must be enabled. Wake-up will

occur regardless of the state of the GIE bit. If the GIE

bit is disabled, the device continues execution at the

instruction after the SLEEPinstruction. If the GIE bit is

enabled, the device executes the instruction after the

SLEEPinstruction, the device will then call the Interrupt

Service Routine. In cases where the execution of the

instruction following SLEEP is not desirable, the user

should have a NOPafter the SLEEPinstruction.

Timer1 oscillator

7. ADC is unaffected, if the dedicated FRC

oscillator is selected.

8. I/O ports maintain the status they had before

SLEEP was executed (driving high, low or

high-impedance).

9. Resets other than WDT are not affected by

Sleep mode.

Refer to individual chapters for more details on

peripheral operation during Sleep.

The WDT is cleared when the device wakes up from

Sleep, regardless of the source of wake-up.

To minimize current consumption, the following

conditions should be considered:

• I/O pins should not be floating

• External circuitry sinking current from I/O pins

• Internal circuitry sourcing current from I/O pins

• Current draw from pins with internal weak pull-ups

• Modules using 31 kHz LFINTOSC

• Modules using Timer1 oscillator

I/O pins that are high-impedance inputs should be

pulled to VDD or VSS externally to avoid switching

currents caused by floating inputs.

Examples of internal circuitry that might be sourcing

current include modules such as the DAC and FVR

modules. See Section 19.0 “Digital-to-Analog

Converter (DAC) Module” and Section 15.0 “Fixed

Voltage Reference (FVR)” for more information on

these modules.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 87

PIC16(L)F1782/3

• If the interrupt occurs during or after the

execution of a SLEEPinstruction

9.1.1

WAKE-UP USING INTERRUPTS

When global interrupts are disabled (GIE cleared) and

any interrupt source has both its interrupt enable bit

and interrupt flag bit set, one of the following will occur:

- SLEEPinstruction will be completely

executed

- Device will immediately wake-up from Sleep

- WDT and WDT prescaler will be cleared

- TO bit of the STATUS register will be set

- PD bit of the STATUS register will be cleared.

• If the interrupt occurs before the execution of a

SLEEPinstruction

- SLEEPinstruction will execute as a NOP.

- WDT and WDT prescaler will not be cleared

- TO bit of the STATUS register will not be set

Even if the flag bits were checked before executing a

SLEEP instruction, it may be possible for flag bits to

become set before the SLEEPinstruction completes. To

determine whether a SLEEPinstruction executed, test

the PD bit. If the PD bit is set, the SLEEP instruction

was executed as a NOP.

- PD bit of the STATUS register will not be

cleared.

FIGURE 9-1:

WAKE-UP FROM SLEEP THROUGH INTERRUPT

Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1

Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4

CLKIN⁽¹⁾

(3)

CLKOUT⁽²⁾

T1OSC

Interrupt Latency⁽⁴⁾

Interrupt flag

GIE bit

(INTCON reg.)

Processor in

Sleep

Instruction Flow

PC

PC + 1

PC + 2

0004h

0005h

Instruction

Fetched

Inst(0004h)

Inst(PC + 1)

Inst(PC + 2)

Inst(0005h)

Inst(PC) = Sleep

Instruction

Executed

Forced NOP

Sleep

Inst(PC + 1)

Inst(PC - 1)

Inst(0004h)

Note 1:

External clock. High, Medium, Low mode assumed.

CLKOUT is shown here for timing reference.

T1OSC; See Section 30.0 “Electrical Specifications”.

GIE = 1assumed. In this case after wake-up, the processor calls the ISR at 0004h. If GIE = 0, execution will continue in-line.

2:

3:

4:

DS40001579E-page 88

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

9.2.2

PERIPHERAL USAGE IN SLEEP

9.2

Low-Power Sleep Mode

Some peripherals that can operate in Sleep mode will

not operate properly with the Low-Power Sleep mode

selected. The LDO will remain in the normal power

mode when those peripherals are enabled. The

Low-Power Sleep mode is intended for use with these

peripherals:

“F” devices contain an internal Low Dropout (LDO)

voltage regulator, which allows the device I/O pins to

operate at voltages up to 5.5V while the internal device

logic operates at a lower voltage. The LDO and its

associated reference circuitry must remain active when

the device is in Sleep mode. “F” devices allow the user

to optimize the operating current in Sleep, depending

on the application requirements.

• Brown-Out Reset (BOR)

• Watchdog Timer (WDT)

A Low-Power Sleep mode can be selected by setting

the VREGPM bit of the VREGCON register. With this

bit set, the LDO and reference circuitry are placed in a

low-power state when the device is in Sleep.

• External interrupt pin/Interrupt-on-change pins

• Timer1 (with external clock source)

Note:

“LF” devices do not have a configurable

Low-Power Sleep mode. “LF” devices are

an unregulated device and are always in

the lowest power state when in Sleep, with

no wake-up time penalty. These devices

have a lower maximum VDD and I/O

9.2.1

SLEEP CURRENT VS. WAKE-UP

TIME

In the default operating mode, the LDO and reference

circuitry remain in the normal configuration while in

Sleep. The device is able to exit Sleep mode quickly

since all circuits remain active. In Low-Power Sleep

mode, when waking up from Sleep, an extra delay time

is required for these circuits to return to the normal

configuration and stabilize.

voltage

than

“F”

devices.

See

Section 30.0 “Electrical Specifications”

for more information.

The Low-Power Sleep mode is beneficial for applica-

tions that stay in Sleep mode for long periods of time.

The normal mode is beneficial for applications that

need to wake from Sleep quickly and frequently.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 89

PIC16(L)F1782/3

9.3

Register Definitions: Voltage Regulator Control

REGISTER 9-1:

VREGCON: VOLTAGE REGULATOR CONTROL REGISTER⁽¹⁾

U-0

—

U-0

—

U-0

—

U-0

—

U-0

—

U-0

—

R/W-0/0

R/W-1/1

VREGPM

Reserved

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-2

bit 1

Unimplemented: Read as ‘0’

VREGPM: Voltage Regulator Power Mode Selection bit

1= Low-Power Sleep mode enabled in Sleep⁽²⁾

Draws lowest current in Sleep, slower wake-up

0= Normal-Power mode enabled in Sleep⁽²⁾

Draws higher current in Sleep, faster wake-up

bit 0

Reserved: Read as ‘1’. Maintain this bit set.

Note 1: “F” devices only.

2: See Section 30.0 “Electrical Specifications”.

TABLE 9-1:

SUMMARY OF REGISTERS ASSOCIATED WITH POWER-DOWN MODE

Register on

Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

INTCON

IOCBF

IOCBN

IOCBP

PIE1

GIE

PEIE

IOCBF6

IOCBN6

IOCBP6

ADIE

TMR0IE

IOCBF5

IOCBN5

IOCBP5

RCIE

INTE

IOCBF4

IOCBN4

IOCBP4

TXIE

IOCIE

IOCBF3

IOCBN3

IOCBP3

SSP1IE

BCL1IE

TMR0IF

IOCBF2

IOCBN2

IOCBP2

CCP1IE

—

INTF

RAIF

79

134

133

80

IOCBF7

IOCBN7

IOCBP7

TMR1GIE

OSEIE

IOCBF1

IOCBN1

IOCBP1

TMR2IE

C3IE

IOCBF0

IOCBN0

IOCBP0

TMR1IE

CCP2IE

PIE2

C2IE

C1IE

EEIE

81

—

Unimplemented

—

PIE4

—

PSMC2TIE PSMC1TIE

—

CCP1IF

—

PSMC2SIE PSMC1SIE

82

PIR1

TMR1GIF

ADIF

C2IF

RCIF

C1IF

TXIF

EEIF

SSP1IF

BCL1IF

TMR2IF

C3IF

TMR1IF

CCP2IF

80

PIR2

OSFIF

84

—

Unimplemented

—

PIR4

—

PSMC2TIF PSMC1TIF

—

Z

PSMC2SIF PSMC1SIF

85

STATUS

VREGCON

WDTCON

Legend:

—

TO

—

PD

—

DC

C

18

—

VREGPM

Reserved

SWDTEN

90

WDTPS<4:0>

94

— = unimplemented location, read as ‘0’. Shaded cells are not used in Power-Down mode.

DS40001579E-page 90

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

On power-up, the external capacitor will load the LDO

voltage regulator. To prevent erroneous operation, the

device is held in Reset while a constant current source

charges the external capacitor. After the cap is fully

charged, the device is released from Reset. For more

information on the constant current rate, refer to the

LDO Regulator Characteristics Table in Section 30.0

“Electrical Specifications”.

10.0 LOW DROPOUT (LDO)

VOLTAGE REGULATOR

The “F” devices have an internal Low Dropout

Regulator (LDO) which provide operation above 3.6V.

The LDO regulates a voltage for the internal device

logic while permitting the VDD and I/O pins to operate

at a higher voltage. There is no user enable/disable

control available for the LDO, it is always active. The

“LF” devices operate at a maximum VDD of 3.6V and

does not incorporate an LDO.

A device I/O pin may be configured as the LDO voltage

output, identified as the VCAP pin. Although not

required, an external low-ESR capacitor may be

connected to the VCAP pin for additional regulator

stability.

The VCAPEN bit of Configuration Words determines if

which pin is assigned as the VCAP pin. Refer to

Table 10-1.

TABLE 10-1: VCAPEN SELECT BIT

VCAPEN

1

0

No VCAP

RA6

TABLE 10-2: SUMMARY OF CONFIGURATION WORD WITH LDO

Register

on Page

Name

Bits

Bit -/7

Bit -/6

Bit 13/5

Bit 12/4

Bit 11/3

Bit 10/2

Bit 9/1

Bit 8/0

13:8

7:0

—

LVP

VCAPEN⁽¹⁾

DEBUG

—

LPBOR

—

BORV

—

STVREN

PLLEN

CONFIG2

42

WRT<1:0>

Legend:

— = unimplemented locations read as ‘0’. Shaded cells are not used by LDO.

Note 1: “F” devices only.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 91

PIC16(L)F1782/3

11.0 WATCHDOG TIMER (WDT)

The Watchdog Timer is a system timer that generates

a Reset if the firmware does not issue a CLRWDT

instruction within the time-out period. The Watchdog

Timer is typically used to recover the system from

unexpected events.

The WDT has the following features:

• Independent clock source

• Multiple operating modes

- WDT is always on

- WDT is off when in Sleep

- WDT is controlled by software

- WDT is always off

• Configurable time-out period is from 1 ms to 256

seconds (nominal)

• Multiple Reset conditions

• Operation during Sleep

FIGURE 11-1:

WATCHDOG TIMER BLOCK DIAGRAM

WDTE<1:0> = 01

SWDTEN

23-bit Programmable

Prescaler WDT

WDTE<1:0> = 11

LFINTOSC

WDT Time-out

WDTE<1:0> = 10

Sleep

WDTPS<4:0>

DS40001579E-page 92

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

11.1 Independent Clock Source

11.3 Time-Out Period

The WDT derives its time base from the 31 kHz

LFINTOSC internal oscillator. Time intervals in this

chapter are based on a nominal interval of 1 ms. See

Section 30.0 “Electrical Specifications” for the

LFINTOSC tolerances.

The WDTPS bits of the WDTCON register set the

time-out period from 1 ms to 256 seconds (nominal).

After a Reset, the default time-out period is two

seconds.

11.4 Clearing the WDT

11.2 WDT Operating Modes

The WDT is cleared when any of the following

conditions occur:

The Watchdog Timer module has four operating modes

controlled by the WDTE<1:0> bits in Configuration

Words. See Table 11-1.

• Any Reset

• CLRWDTinstruction is executed

• Device enters Sleep

11.2.1

WDT IS ALWAYS ON

• Device wakes up from Sleep

• Oscillator fail

When the WDTE bits of Configuration Words are set to

‘11’, the WDT is always on.

• WDT is disabled

WDT protection is active during Sleep.

• Oscillator Start-up TImer (OST) is running

11.2.2

WDT IS OFF IN SLEEP

See Table 11-2 for more information.

When the WDTE bits of Configuration Words are set to

‘10’, the WDT is on, except in Sleep.

11.5 Operation During Sleep

WDT protection is not active during Sleep.

When the device enters Sleep, the WDT is cleared. If

the WDT is enabled during Sleep, the WDT resumes

counting.

11.2.3

WDT CONTROLLED BY SOFTWARE

When the WDTE bits of Configuration Words are set to

‘01’, the WDT is controlled by the SWDTEN bit of the

WDTCON register.

When the device exits Sleep, the WDT is cleared

again. The WDT remains clear until the OST, if

enabled, completes. See Section 6.0 “Oscillator

Module (with Fail-Safe Clock Monitor)” for more

information on the OST.

WDT protection is unchanged by Sleep. See

Table 11-1 for more details.

When a WDT time-out occurs while the device is in

Sleep, no Reset is generated. Instead, the device

wakes up and resumes operation. The TO and PD bits

in the STATUS register are changed to indicate the

event. See Section 3.0 “Memory Organization” and

Status Register (Register 3-1) for more information.

TABLE 11-1: WDT OPERATING MODES

Device

Mode

WDT

Mode

WDTE<1:0>

SWDTEN

11

10

X

Active

Awake Active

Sleep Disabled

1

0

X

Active

X

01

00

Disabled

X

Disabled

TABLE 11-2: WDT CLEARING CONDITIONS

Conditions

WDT

WDTE<1:0> = 00

WDTE<1:0> = 01 and SWDTEN = 0

WDTE<1:0> = 10 and enter Sleep

CLRWDTCommand

Cleared

Oscillator Fail Detected

Exit Sleep + System Clock = T1OSC, EXTRC, INTOSC, EXTCLK

Exit Sleep + System Clock = XT, HS, LP

Cleared until the end of OST

Unaffected

Change INTOSC divider (IRCF bits)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 93

PIC16(L)F1782/3

11.6 Register Definitions: Watchdog Control

REGISTER 11-1: WDTCON: WATCHDOG TIMER CONTROL REGISTER

U-0

—

U-0

—

R/W-0/0

R/W-1/1

R/W-0/0

R/W-1/1

R/W-0/0

WDTPS<4:0>

SWDTEN

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

U = Unimplemented bit, read as ‘0’

-m/n = Value at POR and BOR/Value at all other Resets

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-6

bit 5-1

Unimplemented: Read as ‘0’

WDTPS<4:0>: Watchdog Timer Period Select bits⁽¹⁾

Bit Value = Prescale Rate

11111 = Reserved. Results in minimum interval (1:32)

•

10011 = Reserved. Results in minimum interval (1:32)

10010 = 1:8388608 (2²³) (Interval 256s nominal)

10001 = 1:4194304 (2²²) (Interval 128s nominal)

10000 = 1:2097152 (2²¹) (Interval 64s nominal)

01111 = 1:1048576 (2²⁰) (Interval 32s nominal)

01110 = 1:524288 (2¹⁹) (Interval 16s nominal)

01101 = 1:262144 (2¹⁸) (Interval 8s nominal)

01100 = 1:131072 (2¹⁷) (Interval 4s nominal)

01011 = 1:65536 (Interval 2s nominal) (Reset value)

01010 = 1:32768 (Interval 1s nominal)

01001 = 1:16384 (Interval 512 ms nominal)

01000 = 1:8192 (Interval 256 ms nominal)

00111 = 1:4096 (Interval 128 ms nominal)

00110 = 1:2048 (Interval 64 ms nominal)

00101 = 1:1024 (Interval 32 ms nominal)

00100 = 1:512 (Interval 16 ms nominal)

00011 = 1:256 (Interval 8 ms nominal)

00010 = 1:128 (Interval 4 ms nominal)

00001 = 1:64 (Interval 2 ms nominal)

00000 = 1:32 (Interval 1 ms nominal)

bit 0

SWDTEN: Software Enable/Disable for Watchdog Timer bit

If WDTE<1:0> = 1x:

This bit is ignored.

If WDTE<1:0> = 01:

1= WDT is turned on

0= WDT is turned off

If WDTE<1:0> = 00:

This bit is ignored.

Note 1: Times are approximate. WDT time is based on 31 kHz LFINTOSC.

DS40001579E-page 94

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 11-3: SUMMARY OF REGISTERS ASSOCIATED WITH WATCHDOG TIMER

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

OSCCON

STATUS

SPLLEN

IRCF<3:0>

—

Z

SCS<1:0>

68

18

94

—

TO

PD

DC

C

WDTCON

WDTPS<4:0>

SWDTEN

Legend: x= unknown, u= unchanged, – = unimplemented locations read as ‘0’. Shaded cells are not used by

Watchdog Timer.

TABLE 11-4: SUMMARY OF CONFIGURATION WORD WITH WATCHDOG TIMER

Register

on Page

Name

Bits

Bit -/7

Bit -/6

Bit 13/5

Bit 12/4

Bit 11/3

Bit 10/2

Bit 9/1

Bit 8/0

13:8

7:0

—

FCMEN

PWRTE

IESO

CLKOUTEN

BOREN<1:0>

FOSC<2:0>

CPD

CONFIG1

40

CP

MCLRE

WDTE<1:0>

Legend:

— = unimplemented location, read as ‘0’. Shaded cells are not used by Watchdog Timer.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 95

PIC16(L)F1782/3

12.1 EEADRL and EEADRH Registers

12.0 DATA EEPROM AND FLASH

PROGRAM MEMORY

CONTROL

The EEADRH:EEADRL register pair can address up to

a maximum of 256 bytes of data EEPROM or up to a

maximum of 32K words of program memory.

The data EEPROM and Flash program memory are

readable and writable during normal operation (full VDD

range). These memories are not directly mapped in the

register file space. Instead, they are indirectly

addressed through the Special Function Registers

(SFRs). There are six SFRs used to access these

memories:

When selecting a program address value, the MSB of

the address is written to the EEADRH register and the

LSB is written to the EEADRL register. When selecting

a EEPROM address value, only the LSB of the address

is written to the EEADRL register.

12.1.1

EECON1 AND EECON2 REGISTERS

• EECON1

• EECON2

• EEDATL

• EEDATH

• EEADRL

• EEADRH

EECON1 is the control register for EE memory

accesses.

Control bit EEPGD determines if the access will be a

program or data memory access. When clear, any

subsequent operations will operate on the EEPROM

memory. When set, any subsequent operations will

operate on the program memory. On Reset, EEPROM is

selected by default.

When interfacing the data memory block, EEDATL

holds the 8-bit data for read/write, and EEADRL holds

the address of the EEDATL location being accessed.

These devices have 256 bytes of data EEPROM with

an address range from 0h to 0FFh.

Control bits RD and WR initiate read and write,

respectively. These bits cannot be cleared, only set, in

software. They are cleared in hardware at completion

of the read or write operation. The inability to clear the

WR bit in software prevents the accidental, premature

termination of a write operation.

When accessing the program memory block, the

EEDATH:EEDATL register pair forms a 2-byte word

that holds the 14-bit data for read/write, and the

EEADRL and EEADRH registers form a 2-byte word

that holds the 15-bit address of the program memory

location being read.

The WREN bit, when set, will allow a write operation to

occur. On power-up, the WREN bit is clear. The

WRERR bit is set when a write operation is interrupted

by a Reset during normal operation. In these situations,

following Reset, the user can check the WRERR bit

and execute the appropriate error handling routine.

The EEPROM data memory allows byte read and write.

An EEPROM byte write automatically erases the

location and writes the new data (erase before write).

Interrupt flag bit EEIF of the PIR2 register is set when

write is complete. It must be cleared in the software.

The write time is controlled by an on-chip timer. The

write/erase voltages are generated by an on-chip

charge pump rated to operate over the voltage range of

the device for byte or word operations.

Reading EECON2 will read all ‘0’s. The EECON2

register is used exclusively in the data EEPROM write

sequence. To enable writes, a specific pattern must be

written to EECON2.

Depending on the setting of the Flash Program

Memory Self Write Enable bits WRT<1:0> of the

Configuration Words, the device may or may not be

able to write certain blocks of the program memory.

However, reads from the program memory are always

allowed.

When the device is code-protected, the device

programmer can no longer access data or program

memory. When code-protected, the CPU may continue

to read and write the data EEPROM memory and Flash

program memory.

DS40001579E-page 96

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

12.2.2

WRITING TO THE DATA EEPROM

MEMORY

12.2 Using the Data EEPROM

The data EEPROM is a high-endurance, byte address-

able array that has been optimized for the storage of

frequently changing information (e.g., program

variables or other data that are updated often). When

variables in one section change frequently, while

variables in another section do not change, it is

possible to exceed the total number of write cycles to

the EEPROM without exceeding the total number of

write cycles to a single byte. Refer to Section 30.0

“Electrical Specifications”. If this is the case, then a

refresh of the array must be performed. For this reason,

variables that change infrequently (such as constants,

IDs, calibration, etc.) should be stored in Flash program

memory.

To write an EEPROM data location, the user must first

write the address to the EEADRL register and the data

to the EEDATL register. Then the user must follow a

specific sequence to initiate the write for each byte.

The write will not initiate if the above sequence is not

followed exactly (write 55h to EECON2, write AAh to

EECON2, then set the WR bit) for each byte. Interrupts

should be disabled during this code segment.

Additionally, the WREN bit in EECON1 must be set to

enable write. This mechanism prevents accidental

writes to data EEPROM due to errant (unexpected)

code execution (i.e., lost programs). The user should

keep the WREN bit clear at all times, except when

updating EEPROM. The WREN bit is not cleared

by hardware.

12.2.1

READING THE DATA EEPROM

MEMORY

After a write sequence has been initiated, clearing the

WREN bit will not affect this write cycle. The WR bit will

be inhibited from being set unless the WREN bit is set.

To read a data memory location, the user must write the

address to the EEADRL register, clear the EEPGD and

CFGS control bits of the EECON1 register, and then

set control bit RD. The data is available at the very next

cycle, in the EEDATL register; therefore, it can be read

in the next instruction. EEDATL will hold this value until

another read or until it is written to by the user (during

a write operation).

At the completion of the write cycle, the WR bit is

cleared in hardware and the EE Write Complete

Interrupt Flag bit (EEIF) is set. The user can either

enable this interrupt or poll this bit. EEIF must be

cleared by software.

12.2.3

PROTECTION AGAINST SPURIOUS

WRITE

EXAMPLE 12-1:

DATA EEPROM READ

BANKSELEEADRL

;

There are conditions when the user may not want to

write to the data EEPROM memory. To protect against

spurious EEPROM writes, various mechanisms have

been built-in. On power-up, WREN is cleared. Also, the

Power-up Timer (64 ms duration) prevents EEPROM

write.

MOVLW

MOVWF

DATA_EE_ADDR ;

EEADRL

;Data Memory

;Address to read

EECON1, CFGS ;Deselect Config space

EECON1, EEPGD;Point to DATA memory

BCF

BSF

MOVF

EECON1, RD

EEDATL, W

;EE Read

;W = EEDATL

The write initiate sequence and the WREN bit together

help prevent an accidental write during:

• Brown-out

Note:

Data EEPROM can be read regardless of

the setting of the CPD bit.

• Power Glitch

• Software Malfunction

12.2.4

DATA EEPROM OPERATION

DURING CODE-PROTECT

Data memory can be code-protected by programming

the CPD bit in the Configuration Words to ‘0’.

When the data memory is code-protected, only the

CPU is able to read and write data to the data

EEPROM. It is recommended to code-protect the

program memory when code-protecting data memory.

This prevents anyone from replacing your program with

a program that will access the contents of the data

EEPROM.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 97

PIC16(L)F1782/3

EXAMPLE 12-2:

DATA EEPROM WRITE

BANKSEL EEADRL

;

MOVLW

MOVWF

MOVLW

MOVWF

BCF

DATA_EE_ADDR

EEADRL

DATA_EE_DATA

EEDATL

;

;Data Memory Address to write

;

;Data Memory Value to write

;Deselect Configuration space

EECON1, CFGS

BCF

EECON1, EEPGD ;Point to DATA memory

BSF

EECON1, WREN

;Enable writes

BCF

INTCON, GIE

55h

EECON2

0AAh

EECON2

EECON1, WR

INTCON, GIE

EECON1, WREN

EECON1, WR

$-2

;Disable INTs.

;

;Write 55h

;

MOVLW

MOVWF

MOVLW

MOVWF

BSF

BCF

BTFSC

GOTO

;Write AAh

;Set WR bit to begin write

;Enable Interrupts

;Disable writes

;Wait for write to complete

;Done

FIGURE 12-1:

FLASH PROGRAM MEMORY READ CYCLE EXECUTION

Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4

PC

PC + 1

EEADRH,EEADRL

PC + 3

PC+3

PC + 4

PC + 5

Flash ADDR

Flash Data

INSTR (PC)

INSTR (PC + 1)

EEDATH,EEDATL

INSTR (PC + 3)

INSTR (PC + 4)

BSF PMCON1,RD

executed here

INSTR(PC - 1)

executed here

INSTR(PC + 1)

executed here

Forced NOP

executed here

INSTR(PC + 3)

executed here

INSTR(PC + 4)

executed here

RD bit

EEDATH

EEDATL

Register

DS40001579E-page 98

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

12.3.1

READING THE FLASH PROGRAM

MEMORY

12.3 Flash Program Memory Overview

It is important to understand the Flash program

memory structure for erase and programming

operations. Flash program memory is arranged in

rows. A row consists of a fixed number of 14-bit

program memory words. A row is the minimum block

size that can be erased by user software.

To read a program memory location, the user must:

1. Write the Least and Most Significant address

bits to the EEADRH:EEADRL register pair.

2. Clear the CFGS bit of the EECON1 register.

3. Set the EEPGD control bit of the EECON1

register.

Flash program memory may only be written or erased

if the destination address is in a segment of memory

that is not write-protected, as defined in bits WRT<1:0>

of Configuration Words.

4. Then, set control bit RD of the EECON1 register.

Once the read control bit is set, the program memory

Flash controller will use the second instruction cycle to

read the data. This causes the second instruction

immediately following the “BSF EECON1,RD” instruction

to be ignored. The data is available in the very next cycle,

in the EEDATH:EEDATL register pair; therefore, it can

be read as two bytes in the following instructions.

After a row has been erased, the user can reprogram

all or a portion of this row. Data to be written into the

program memory row is written to 14-bit wide data write

latches. These write latches are not directly accessible

to the user, but may be loaded via sequential writes to

the EEDATH:EEDATL register pair.

EEDATH:EEDATL register pair will hold this value until

another read or until it is written to by the user.

Note:

If the user wants to modify only a portion

of a previously programmed row, then the

contents of the entire row must be read

and saved in RAM prior to the erase.

Note 1: The two instructions following a program

memory read are required to be NOPs.

This prevents the user from executing a

two-cycle instruction on the next

instruction after the RD bit is set.

The number of data write latches may not be equivalent

to the number of row locations. During programming,

user software may need to fill the set of write latches

and initiate a programming operation multiple times in

order to fully reprogram an erased row. For example, a

device with a row size of 32 words and eight write

latches will need to load the write latches with data and

initiate a programming operation four times.

2: Flash program memory can be read

regardless of the setting of the CP bit.

The size of a program memory row and the number of

program memory write latches may vary by device.

See Table 12-1 for details.

TABLE 12-1: FLASH MEMORY ORGANIZATION BY DEVICE

Device

Erase Block (Row) Size/Boundary

Number of Write Latches/Boundary

PIC16(L)F1782/3

32 words, EEADRL<4:0> = 00000

 2011-2014 Microchip Technology Inc.

DS40001579E-page 99

PIC16(L)F1782/3

EXAMPLE 12-3:

FLASH PROGRAM MEMORY READ

* This code block will read 1 word of program

* memory at the memory address:

PROG_ADDR_HI : PROG_ADDR_LO

*

data will be returned in the variables;

PROG_DATA_HI, PROG_DATA_LO

BANKSEL EEADRL

; Select Bank for EEPROM registers

MOVLW

MOVWF

MOVLW

MOVWL

PROG_ADDR_LO

EEADRL

PROG_ADDR_HI

EEADRH

;

; Store LSB of address

;

; Store MSB of address

BCF

BSF

BCF

BSF

NOP

BSF

EECON1,CFGS

EECON1,EEPGD

INTCON,GIE

EECON1,RD

; Do not select Configuration Space

; Select Program Memory

; Disable interrupts

; Initiate read

; Executed (Figure 12-1)

; Ignored (Figure 12-1)

; Restore interrupts

INTCON,GIE

MOVF

EEDATL,W

; Get LSB of word

MOVWF

MOVF

PROG_DATA_LO

EEDATH,W

; Store in user location

; Get MSB of word

MOVWF

PROG_DATA_HI

; Store in user location

DS40001579E-page 100

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

unlock sequence is required to load a write latch with

data or initiate a Flash programming operation. This

unlock sequence should not be interrupted.

12.3.2

ERASING FLASH PROGRAM

MEMORY

While executing code, program memory can only be

erased by rows. To erase a row:

1. Set the EEPGD and WREN bits of the EECON1

register.

1. Load the EEADRH:EEADRL register pair with

the address of new row to be erased.

2. Clear the CFGS bit of the EECON1 register.

3. Set the LWLO bit of the EECON1 register. When

the LWLO bit of the EECON1 register is ‘1’, the

write sequence will only load the write latches

and will not initiate the write to Flash program

memory.

2. Clear the CFGS bit of the EECON1 register.

3. Set the EEPGD, FREE, and WREN bits of the

EECON1 register.

4. Write 55h, then AAh, to EECON2 (Flash

programming unlock sequence).

4. Load the EEADRH:EEADRL register pair with

the address of the location to be written.

5. Set control bit WR of the EECON1 register to

begin the erase operation.

5. Load the EEDATH:EEDATL register pair with

the program memory data to be written.

6. Poll the FREE bit in the EECON1 register to

determine when the row erase has completed.

6. Write 55h, then AAh, to EECON2, then set the

WR bit of the EECON1 register (Flash

programming unlock sequence). The write latch

is now loaded.

See Example 12-4.

After the “BSF EECON1,WR” instruction, the processor

requires two cycles to set up the erase operation. The

user must place two NOPinstructions after the WR bit is

set. The processor will halt internal operations for the

typical 2 ms erase time. This is not Sleep mode as the

clocks and peripherals will continue to run. After the

erase cycle, the processor will resume operation with

the third instruction after the EECON1 write instruction.

7. Increment the EEADRH:EEADRL register pair

to point to the next location.

8. Repeat steps 5 through 7 until all but the last

write latch has been loaded.

9. Clear the LWLO bit of the EECON1 register.

When the LWLO bit of the EECON1 register is

‘0’, the write sequence will initiate the write to

Flash program memory.

12.3.3

WRITING TO FLASH PROGRAM

MEMORY

10. Load the EEDATH:EEDATL register pair with

the program memory data to be written.

Program memory is programmed using the following

steps:

11. Write 55h, then AAh, to EECON2, then set the

WR bit of the EECON1 register (Flash

programming unlock sequence). The entire

latch block is now written to Flash program

memory.

1. Load the starting address of the word(s) to be

programmed.

2. Load the write latches with data.

3. Initiate a programming operation.

It is not necessary to load the entire write latch block

with user program data. However, the entire write latch

block will be written to program memory.

4. Repeat steps 1 through 3 until all data is written.

Before writing to program memory, the word(s) to be

written must be erased or previously unwritten.

Program memory can only be erased one row at a time.

No automatic erase occurs upon the initiation of the

write.

An example of the complete write sequence for eight

words is shown in Example 12-5. The initial address is

loaded into the EEADRH:EEADRL register pair; the

eight words of data are loaded using indirect addressing.

Program memory can be written one or more words at

a time. The maximum number of words written at one

time is equal to the number of write latches. See

Figure 12-2 (block writes to program memory with 32

write latches) for more details. The write latches are

aligned to the address boundary defined by EEADRL

as shown in Table 12-1. Write operations do not cross

these boundaries. At the completion of a program

memory write operation, the write latches are reset to

contain 0x3FFF.

After the “BSF EECON1,WR” instruction, the processor

requires two cycles to set up the write operation. The

user must place two NOPinstructions after the WR bit is

set. The processor will halt internal operations for the

typical 2 ms, only during the cycle in which the write

takes place (i.e., the last word of the block write). This

is not Sleep mode as the clocks and peripherals will

continue to run. The processor does not stall when

LWLO = 1, loading the write latches. After the write

cycle, the processor will resume operation with the third

instruction after the EECON1 WRITEinstruction.

The following steps should be completed to load the

write latches and program a block of program memory.

These steps are divided into two parts. First, all write

latches are loaded with data except for the last program

memory location. Then, the last write latch is loaded

and the programming sequence is initiated. A special

 2011-2014 Microchip Technology Inc.

DS40001579E-page 101

PIC16(L)F1782/3

FIGURE 12-2:

BLOCK WRITES TO FLASH PROGRAM MEMORY WITH 32 WRITE LATCHES

7

5

0

0 7

EEDATH

6

EEDATA

8

Last word of block

to be written

First word of block

to be written

14

EEADRL<4:0> = 00000

EEADRL<4:0> = 00001

EEADRL<4:0> = 00010

EEADRL<4:0> = 11111

Buffer Register

Program Memory

EXAMPLE 12-4:

ERASING ONE ROW OF PROGRAM MEMORY

; This row erase routine assumes the following:

; 1. A valid address within the erase block is loaded in ADDRH:ADDRL

; 2. ADDRH and ADDRL are located in shared data memory 0x70 - 0x7F (common RAM)

BCF

INTCON,GIE

EEADRL

ADDRL,W

EEADRL

ADDRH,W

; Disable ints so required sequences will execute properly

; Load lower 8 bits of erase address boundary

; Load upper 6 bits of erase address boundary

BANKSEL

MOVF

MOVWF

MOVF

MOVWF

BSF

BCF

BSF

EEADRH

EECON1,EEPGD

EECON1,CFGS

EECON1,FREE

EECON1,WREN

; Point to program memory

; Not configuration space

; Specify an erase operation

; Enable writes

MOVLW

MOVWF

MOVLW

MOVWF

BSF

55h

EECON2

0AAh

EECON2

EECON1,WR

; Start of required sequence to initiate erase

; Write 55h

;

; Write AAh

; Set WR bit to begin erase

; Any instructions here are ignored as processor

; halts to begin erase sequence

; Processor will stop here and wait for erase complete.

NOP

; after erase processor continues with 3rd instruction

BCF

BSF

EECON1,WREN

INTCON,GIE

; Disable writes

; Enable interrupts

DS40001579E-page 102

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

EXAMPLE 12-5:

WRITING TO FLASH PROGRAM MEMORY

; This write routine assumes the following:

; 1. The 16 bytes of data are loaded, starting at the address in DATA_ADDR

; 2. Each word of data to be written is made up of two adjacent bytes in DATA_ADDR,

;

stored in little endian format

; 3. A valid starting address (the least significant bits = 000) is loaded in ADDRH:ADDRL

; 4. ADDRH and ADDRL are located in shared data memory 0x70 - 0x7F (common RAM)

;

BCF

INTCON,GIE

EEADRH

ADDRH,W

EEADRH

ADDRL,W

EEADRL

; Disable ints so required sequences will execute properly

; Bank 3

; Load initial address

;

BANKSEL

MOVF

MOVWF

MOVF

MOVWF

MOVLW

MOVWF

MOVLW

MOVWF

BSF

LOW DATA_ADDR ; Load initial data address

FSR0L

HIGH DATA_ADDR ; Load initial data address

;

FSR0H

;

EECON1,EEPGD

EECON1,CFGS

EECON1,WREN

EECON1,LWLO

; Point to program memory

; Not configuration space

; Enable writes

BCF

BSF

; Only Load Write Latches

LOOP

MOVIW

MOVWF

MOVIW

MOVWF

FSR0++

EEDATL

FSR0++

EEDATH

; Load first data byte into lower

;

; Load second data byte into upper

;

MOVF

EEADRL,W

0x07

STATUS,Z

START_WRITE

; Check if lower bits of address are '000'

; Check if we're on the last of 8 addresses

;

; Exit if last of eight words,

;

XORLW

ANDLW

BTFSC

GOTO

MOVLW

MOVWF

MOVLW

MOVWF

BSF

55h

EECON2

0AAh

EECON2

EECON1,WR

; Start of required write sequence:

; Write 55h

;

; Write AAh

; Set WR bit to begin write

NOP

; Any instructions here are ignored as processor

; halts to begin write sequence

NOP

; Processor will stop here and wait for write to complete.

; After write processor continues with 3rd instruction.

INCF

GOTO

EEADRL,F

LOOP

; Still loading latches Increment address

; Write next latches

START_WRITE

BCF

EECON1,LWLO

; No more loading latches - Actually start Flash program

; memory write

MOVLW

55h

EECON2

0AAh

EECON2

EECON1,WR

; Start of required write sequence:

; Write 55h

;

MOVWF

MOVLW

MOVWF

BSF

; Write AAh

; Set WR bit to begin write

; Any instructions here are ignored as processor

; halts to begin write sequence

; Processor will stop here and wait for write complete.

NOP

; after write processor continues with 3rd instruction

; Disable writes

; Enable interrupts

BCF

BSF

EECON1,WREN

INTCON,GIE

 2011-2014 Microchip Technology Inc.

DS40001579E-page 103

PIC16(L)F1782/3

12.4 Modifying Flash Program Memory

12.5 User ID, Device ID and

Configuration Word Access

When modifying existing data in a program memory

row, and data within that row must be preserved, it must

first be read and saved in a RAM image. Program

memory is modified using the following steps:

Instead of accessing program memory or EEPROM

data memory, the User ID’s, Device ID/Revision ID and

Configuration Words can be accessed when CFGS = 1

in the EECON1 register. This is the region that would

be pointed to by PC<15> = 1, but not all addresses are

accessible. Different access may exist for reads and

writes. Refer to Table 12-2.

1. Load the starting address of the row to be

modified.

2. Read the existing data from the row into a RAM

image.

When read access is initiated on an address outside the

parameters listed in Table 12-2, the EEDATH:EEDATL

register pair is cleared.

3. Modify the RAM image to contain the new data

to be written into program memory.

4. Load the starting address of the row to be

rewritten.

5. Erase the program memory row.

6. Load the write latches with data from the RAM

image.

7. Initiate a programming operation.

8. Repeat steps 6 and 7 as many times as required

to reprogram the erased row.

TABLE 12-2: USER ID, DEVICE ID AND CONFIGURATION WORD ACCESS (CFGS = 1)

Address

Function

Read Access

Write Access

8000h-8003h

8006h

User IDs

Yes

No

Device ID/Revision ID

Configuration Words 1 and 2

8007h-8008h

EXAMPLE 12-3: CONFIGURATION WORD AND DEVICE ID ACCESS

* This code block will read 1 word of program memory at the memory address:

*

PROG_ADDR_LO (must be 00h-08h) data will be returned in the variables;

PROG_DATA_HI, PROG_DATA_LO

BANKSEL EEADRL

; Select correct Bank

;

; Store LSB of address

; Clear MSB of address

MOVLW

MOVWF

CLRF

PROG_ADDR_LO

EEADRL

EEADRH

BSF

BCF

BSF

NOP

BSF

EECON1,CFGS

INTCON,GIE

EECON1,RD

; Select Configuration Space

; Disable interrupts

; Initiate read

; Executed (See Figure 12-1)

; Ignored (See Figure 12-1)

; Restore interrupts

INTCON,GIE

MOVF

EEDATL,W

; Get LSB of word

MOVWF

MOVF

PROG_DATA_LO

EEDATH,W

; Store in user location

; Get MSB of word

MOVWF

PROG_DATA_HI

; Store in user location

DS40001579E-page 104

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

12.6 Write Verify

Depending on the application, good programming

practice may dictate that the value written to the data

EEPROM or program memory should be verified (see

Example 12-6) to the desired value to be written.

Example 12-6 shows how to verify a write to EEPROM.

EXAMPLE 12-6:

EEPROM WRITE VERIFY

BANKSELEEDATL

;

MOVF

EEDATL, W ;EEDATL not changed

;from previous write

BSF

EECON1, RD ;YES, Read the

;value written

XORWF

BTFSS

GOTO

:

EEDATL, W

;

STATUS, Z ;Is data the same

WRITE_ERR ;No, handle error

;Yes, continue

 2011-2014 Microchip Technology Inc.

DS40001579E-page 105

PIC16(L)F1782/3

12.7 Register Definitions: EEPROM and Flash Control

REGISTER 12-1: EEDATL: EEPROM DATA LOW BYTE REGISTER

R/W-x/u

EEDAT<7:0>

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-0

EEDAT<7:0>: Read/write value for EEPROM data byte or Least Significant bits of program memory

REGISTER 12-2: EEDATH: EEPROM DATA HIGH BYTE REGISTER

U-0

—

U-0

—

R/W-x/u

EEDAT<13:8>

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-6

bit 5-0

Unimplemented: Read as ‘0’

EEDAT<13:8>: Read/write value for Most Significant bits of program memory

REGISTER 12-3: EEADRL: EEPROM ADDRESS REGISTER

R/W-0/0

EEADR<7:0>

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-0

EEADR<7:0>: Specifies the Least Significant bits for program memory address or EEPROM address

REGISTER 12-4: EEADRH: EEPROM ADDRESS HIGH BYTE REGISTER

U-1

R/W-0/0

(1)

—

EEADR<14:8>

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7

Unimplemented: Read as ‘1’

bit 6-0

Note 1:

EEADR<14:8>: Specifies the Most Significant bits for program memory address or EEPROM address

Unimplemented, read as ‘1’.

DS40001579E-page 106

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 12-5: EECON1: EEPROM CONTROL 1 REGISTER

R/W-0/0

EEPGD

R/W-0/0

CFGS

R/W-0/0

LWLO

R/W/HC-0/0

FREE

R/W-x/q

WRERR

R/W-0/0

WREN

R/S/HC-0/0 R/S/HC-0/0

WR RD

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

S = Bit can only be set

‘1’ = Bit is set

-n/n = Value at POR and BOR/Value at all other Resets

HC = Bit is cleared by hardware

bit 7

bit 6

bit 5

EEPGD: Flash Program/Data EEPROM Memory Select bit

1= Accesses program space Flash memory

0= Accesses data EEPROM memory

CFGS: Flash Program/Data EEPROM or Configuration Select bit

1= Accesses Configuration, User ID and Device ID registers

0= Accesses Flash program or data EEPROM memory

LWLO: Load Write Latches Only bit

If CFGS = 1 (Configuration space) OR CFGS = 0 and EEPGD = 1 (program Flash):

1= The next WR command does not initiate a write; only the program memory latches are

updated.

0= The next WR command writes a value from EEDATH:EEDATL into program memory latches

and initiates a write of all the data stored in the program memory latches.

If CFGS = 0 and EEPGD = 0: (Accessing data EEPROM)

LWLO is ignored. The next WR command initiates a write to the data EEPROM.

bit 4

FREE: Program Flash Erase Enable bit

If CFGS = 1 (Configuration space) OR CFGS = 0 and EEPGD = 1 (program Flash):

1= Performs an erase operation on the next WR command (cleared by hardware after comple-

tion of erase).

0= Performs a write operation on the next WR command.

If EEPGD = 0 and CFGS = 0: (Accessing data EEPROM)

FREE is ignored. The next WR command will initiate both a erase cycle and a write cycle.

bit 3

WRERR: EEPROM Error Flag bit

1= Condition indicates an improper program or erase sequence attempt or termination (bit is set

automatically on any set attempt (write ‘1’) of the WR bit).

0= The program or erase operation completed normally.

bit 2

bit 1

WREN: Program/Erase Enable bit

1= Allows program/erase cycles

0= Inhibits programming/erasing of program Flash and data EEPROM

WR: Write Control bit

1= Initiates a program Flash or data EEPROM program/erase operation.

The operation is self-timed and the bit is cleared by hardware once operation is complete.

The WR bit can only be set (not cleared) in software.

0= Program/erase operation to the Flash or data EEPROM is complete and inactive.

bit 0

RD: Read Control bit

1= Initiates an program Flash or data EEPROM read. Read takes one cycle. RD is cleared in

hardware. The RD bit can only be set (not cleared) in software.

0= Does not initiate a program Flash or data EEPROM data read.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 107

PIC16(L)F1782/3

REGISTER 12-6: EECON2: EEPROM CONTROL 2 REGISTER

W-0/0

bit 0

EEPROM Control Register 2

bit 7

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

S = Bit can only be set

‘1’ = Bit is set

bit 7-0

Data EEPROM Unlock Pattern bits

To unlock writes, a 55h must be written first, followed by an AAh, before setting the WR bit of the

EECON1 register. The value written to this register is used to unlock the writes. There are specific

timing requirements on these writes. Refer to Section 12.2.2 “Writing to the Data EEPROM

Memory” for more information.

TABLE 12-3: SUMMARY OF REGISTERS ASSOCIATED WITH DATA EEPROM

Register on

Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

EECON1

EECON2

EEADRL

EEPGD

CFGS

LWLO

FREE

WRERR

WREN

WR

RD

107

108*

106

79

EEPROM Control Register 2 (not a physical register)

EEADRL<7:0>

(1)

EEADRH

EEDATL

—

EEADRH<6:0>

EEDATL<7:0>

EEDATH

INTCON

PIE2

—

EEDATH<5:0>

GIE

PEIE

C2IE

C2IF

TMR0IE

C1IE

INTE

EEIE

EEIF

IOCIE

BCL1IE

BCL1IF

TMR0IF

INTF

C3IE

C3IF

IOCIF

CCP2IE

CCP2IF

OSEIE

OSFIF

—

81

PIR2

C1IF

84

Legend:

— = unimplemented location, read as ‘0’. Shaded cells are not used by data EEPROM module.

*

Page provides register information.

2: Unimplemented, read as ‘1’.

DS40001579E-page 108

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 13-1:

GENERIC I/O PORT

OPERATION

13.0 I/O PORTS

Each port has three standard registers for its operation.

These registers are:

• TRISx registers (data direction)

Read LATx

• PORTx registers (reads the levels on the pins of

the device)

TRISx

D

Q

• LATx registers (output latch)

Write LATx

Write PORTx

Some ports may have one or more of the following

additional registers. These registers are:

CK

Data Register

VDD

• ANSELx (analog select)

• WPUx (weak pull-up)

Data Bus

In general, when a peripheral is enabled on a port pin,

that pin cannot be used as a general purpose output.

However, the pin can still be read.

I/O pin

Read PORTx

To digital peripherals

To analog peripherals

VSS

ANSELx

TABLE 13-1: PORT AVAILABILITY PER

DEVICE

Device

PIC16(L)F1782

PIC16(L)F1783

●

The Data Latch (LATx registers) is useful for

read-modify-write operations on the value that the I/O

pins are driving.

A write operation to the LATx register has the same

effect as a write to the corresponding PORTx register.

A read of the LATx register reads of the values held in

the I/O PORT latches, while a read of the PORTx

register reads the actual I/O pin value.

Ports that support analog inputs have an associated

ANSELx register. When an ANSEL bit is set, the digital

input buffer associated with that bit is disabled.

Disabling the input buffer prevents analog signal levels

on the pin between a logic high and low from causing

excessive current in the logic input circuitry. A

simplified model of a generic I/O port, without the

interfaces to other peripherals, is shown in Figure 13-1.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 109

PIC16(L)F1782/3

13.1 Alternate Pin Function

The Alternate Pin Function Control (APFCON) register

is used to steer specific peripheral input and output

functions between different pins. The APFCON register

is shown in Register 13-1. For this device family, the

following functions can be moved between different

pins.

• C2OUT output

• CCP1 output

• SDO output

• SCL/SCK output

• SDA/SDI output

• TX/RX output

• CCP2 output

These bits have no effect on the values of any TRIS

register. PORT and TRIS overrides will be routed to the

correct pin. The unselected pin will be unaffected.

DS40001579E-page 110

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

13.2 Register Definitions: Alternate Pin Function Control

REGISTER 13-1: APFCON: ALTERNATE PIN FUNCTION CONTROL REGISTER

R/W-0/0

SCKSEL

R/W-0/0

SDISEL

R/W-0/0

TXSEL

R/W-0/0

RXSEL

R/W-0/0

C2OUTSEL

CCP1SEL

SDOSEL

CCP2SEL

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

bit 6

bit 5

bit 4

bit 3

bit 2

bit 1

bit 0

C2OUTSEL: C2OUT Pin Selection bit

1= C2OUT is on pin RA6

0= C2OUT is on pin RA5

CCP1SEL: CCP1 Input/Output Pin Selection bit

1= CCP1 is on pin RB0

0= CCP1 is on pin RC2

SDOSEL: MSSP SDO Pin Selection bit

1= SDO is on pin RB5

0= SDO is on pin RC5

SCKSEL: MSSP Serial Clock (SCL/SCK) Pin Selection bit

1= SCL/SCK is on pin RB7

0= SCL/SCK is on pin RC3

SDISEL: MSSP Serial Data (SDA/SDI) Output Pin Selection bit

1= SDA/SDI is on pin RB6

0= SDA/SDI is on pin RC4

TXSEL: TX Pin Selection bit

1= TX is on pin RB6

0= TX is on pin RC6

RXSEL: RX Pin Selection bit

1= RX is on pin RB7

0= RX is on pin RC7

CCP2SEL: CCP2 Input/Output Pin Selection bit

1= CCP2 is on pin RB3

0= CCP2 is on pin RC1

 2011-2014 Microchip Technology Inc.

DS40001579E-page 111

PIC16(L)F1782/3

13.3.5

INPUT THRESHOLD CONTROL

13.3 PORTA Registers

The INLVLA register (Register 13-9) controls the input

voltage threshold for each of the available PORTA input

pins. A selection between the Schmitt Trigger CMOS or

the TTL Compatible thresholds is available. The input

threshold is important in determining the value of a

read of the PORTA register and also the level at which

an interrupt-on-change occurs, if that feature is

enabled. See Section TABLE 30-1: “Supply Voltage”

for more information on threshold levels.

13.3.1

DATA REGISTER

PORTA is an 8-bit wide, bidirectional port. The

corresponding data direction register is TRISA

(Register 13-3). Setting a TRISA bit (= 1) will make the

corresponding PORTA pin an input (i.e., disable the

output driver). Clearing a TRISA bit (= 0) will make the

corresponding PORTA pin an output (i.e., enables

output driver and puts the contents of the output latch

on the selected pin). Example 13-1 shows how to

initialize PORTA.

Note:

Changing the input threshold selection

should be performed while all peripheral

modules are disabled. Changing the

threshold level during the time a module is

Reading the PORTA register (Register 13-2) reads the

status of the pins, whereas writing to it will write to the

PORT latch. All write operations are read-modify-write

operations. Therefore, a write to a port implies that the

port pins are read, this value is modified and then

written to the PORT data latch (LATA).

active may inadvertently generate

a

transition associated with an input pin,

regardless of the actual voltage level on

that pin.

13.3.2

DIRECTION CONTROL

13.3.6

ANALOG CONTROL

The TRISA register (Register 13-3) controls the

PORTA pin output drivers, even when they are being

used as analog inputs. The user should ensure the bits

in the TRISA register are maintained set when using

them as analog inputs. I/O pins configured as analog

inputs always read ‘0’.

The ANSELA register (Register 13-5) is used to

configure the Input mode of an I/O pin to analog.

Setting the appropriate ANSELA bit high will cause all

digital reads on the pin to be read as ‘0’ and allow

analog functions on the pin to operate correctly.

The state of the ANSELA bits has no effect on digital

output functions. A pin with TRIS clear and ANSEL set

will still operate as a digital output, but the Input mode

will be analog. This can cause unexpected behavior

when executing read-modify-write instructions on the

affected port.

13.3.3

OPEN DRAIN CONTROL

The ODCONA register (Register 13-7) controls the

open-drain feature of the port. Open drain operation is

independently selected for each pin. When an

ODCONA bit is set, the corresponding port output

becomes an open drain driver capable of sinking

current only. When an ODCONA bit is cleared, the

corresponding port output pin is the standard push-pull

drive capable of sourcing and sinking current.

Note:

The ANSELA bits default to the Analog

mode after Reset. To use any pins as

digital general purpose or peripheral

inputs, the corresponding ANSEL bits

must be initialized to ‘0’ by user software.

13.3.4

SLEW RATE CONTROL

EXAMPLE 13-1:

INITIALIZING PORTA

The SLRCONA register (Register 13-8) controls the

slew rate option for each port pin. Slew rate control is

independently selectable for each port pin. When an

SLRCONA bit is set, the corresponding port pin drive is

slew rate limited. When an SLRCONA bit is cleared,

The corresponding port pin drive slews at the maximum

rate possible.

; This code example illustrates

; initializing the PORTA register. The

; other ports are initialized in the same

; manner.

BANKSEL PORTA

CLRF PORTA

BANKSEL LATA

CLRF LATA

BANKSEL ANSELA

CLRF ANSELA

BANKSEL TRISA

;

;Init PORTA

;Data Latch

;

;digital I/O

;

MOVLW

MOVWF

B'00111000' ;Set RA<5:3> as inputs

TRISA

;and set RA<2:0> as

;outputs

DS40001579E-page 112

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

13.3.7

PORTA FUNCTIONS AND OUTPUT

PRIORITIES

Each PORTA pin is multiplexed with other functions. The

pins, their combined functions and their output priorities

are shown in Table 13-2.

When multiple outputs are enabled, the actual pin

control goes to the peripheral with the highest priority.

Analog input functions, such as ADC, and comparator

inputs, are not shown in the priority lists. These inputs

are active when the I/O pin is set for Analog mode using

the ANSELx registers. Digital output functions may

control the pin when it is in Analog mode with the

priority shown in the priority list.

TABLE 13-2: PORTA OUTPUT PRIORITY

Pin Name

Function Priority⁽¹⁾

RA0

RA1

RA0

OPA1OUT

RA1

RA2

DACOUT1

RA2

RA3

RA4

RA3

C1OUT

RA4

RA5

RA6

C2OUT

RA5

CLKOUT

C2OUT

RA6

RA7

Note 1: Priority listed from highest to lowest.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 113

PIC16(L)F1782/3

13.4 Register Definitions: PORTA

REGISTER 13-2: PORTA: PORTA REGISTER

R/W-x/x

RA7

R/W-x/x

RA6

R/W-x/x

RA5

R/W-x/x

RA4

R/W-x/x

RA3

R/W-x/x

RA2

R/W-x/x

RA1

R/W-x/x

RA0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

(1)

bit 7-0

RA<7:0>: PORTA I/O Value bits

1= Port pin is > VIH

0= Port pin is < VIL

Note 1: Writes to PORTA are actually written to corresponding LATA register. Reads from PORTA register is return of

actual I/O pin values.

REGISTER 13-3: TRISA: PORTA TRI-STATE REGISTER

R/W-1/1

TRISA7

R/W-1/1

TRISA6

R/W-1/1

TRISA5

R/W-1/1

TRISA4

R/W-1/1

TRISA3

R/W-1/1

TRISA2

R/W-1/1

TRISA1

R/W-1/1

TRISA0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7-0

TRISA<7:0>: PORTA Tri-State Control bits

1= PORTA pin configured as an input (tri-stated)

0= PORTA pin configured as an output

REGISTER 13-4: LATA: PORTA DATA LATCH REGISTER

R/W-x/u

LATA7

R/W-x/u

LATA6

R/W-x/u

LATA5

R/W-x/u

LATA4

R/W-x/u

LATA3

R/W-x/u

LATA2

R/W-x/u

LATA1

R/W-x/u

LATA0

bit 0

bit 7

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

(1)

bit 7-4

LATA<7:0>: PORTA Output Latch Value bits

Note 1: Writes to PORTA are actually written to corresponding LATA register. Reads from PORTA register is return of

actual I/O pin values.

DS40001579E-page 114

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 13-5: ANSELA: PORTA ANALOG SELECT REGISTER

R/W-1/1

ANSA7

U-0

—

R/W-1/1

ANSA5

R/W-1/1

ANSA4

R/W-1/1

ANSA3

R/W-1/1

ANSA2

R/W-1/1

ANSA1

R/W-1/1

ANSA0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 5

ANSA7: Analog Select between Analog or Digital Function on pins RA7, respectively

0= Digital I/O. Pin is assigned to port or digital special function.

1= Analog input. Pin is assigned as analog input⁽¹⁾. Digital input buffer disabled.

bit 6

Unimplemented: Read as ‘0’

bit 5-0

ANSA<5:0>: Analog Select between Analog or Digital Function on pins RA<5:0>, respectively

0= Digital I/O. Pin is assigned to port or digital special function.

1= Analog input. Pin is assigned as analog input⁽¹⁾. Digital input buffer disabled.

Note 1: When setting a pin to an analog input, the corresponding TRIS bit must be set to Input mode in order to

allow external control of the voltage on the pin.

REGISTER 13-6: WPUA: WEAK PULL-UP PORTA REGISTER

R/W-1/1

WPUA7

R/W-1/1

WPUA6

R/W-1/1

WPUA5

R/W-1/1

WPUA4

R/W-1/1

WPUA3

R/W-1/1

WPUA2

R/W-1/1

WPUA1

R/W-1/1

WPUA0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

WPUA<7:0>: Weak Pull-up Register bits

1= Pull-up enabled

0= Pull-up disabled

Note 1: Global WPUEN bit of the OPTION_REG register must be cleared for individual pull-ups to be enabled.

2: The weak pull-up device is automatically disabled if the pin is in configured as an output.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 115

PIC16(L)F1782/3

REGISTER 13-7: ODCONA: PORTA OPEN DRAIN CONTROL REGISTER

R/W-0/0

ODA7

R/W-0/0

ODA6

R/W-0/0

ODA5

R/W-0/0

ODA4

R/W-0/0

ODA3

R/W-0/0

ODA2

R/W-0/0

ODA1

R/W-0/0

ODA0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

ODA<7:0>: PORTA Open Drain Enable bits

For RA<7:0> pins, respectively

1= Port pin operates as open-drain drive (sink current only)

0= Port pin operates as standard push-pull drive (source and sink current)

REGISTER 13-8: SLRCONA: PORTA SLEW RATE CONTROL REGISTER

R/W-1/1

SLRA7

R/W-1/1

SLRA6

R/W-1/1

SLRA5

R/W-1/1

SLRA4

R/W-1/1

SLRA3

R/W-1/1

SLRA2

R/W-1/1

SLRA1

R/W-1/1

SLRA0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

SLRA<7:0>: PORTA Slew Rate Enable bits

For RA<7:0> pins, respectively

1= Port pin slew rate is limited

0= Port pin slews at maximum rate

REGISTER 13-9: INLVLA: PORTA INPUT LEVEL CONTROL REGISTER

R/W-0/0

INLVLA7

R/W-0/0

INLVLA6

R/W-0/0

INLVLA5

R/W-0/0

INLVLA4

R/W-0/0

INLVLA3

R/W-0/0

INLVLA2

R/W-0/0

INLVLA1

R/W-0/0

INLVLA0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

INLVLA<7:0>: PORTA Input Level Select bits

For RA<7:0> pins, respectively

1= ST input used for PORT reads and interrupt-on-change

0= TTL input used for PORT reads and interrupt-on-change

DS40001579E-page 116

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 13-3: SUMMARY OF REGISTERS ASSOCIATED WITH PORTA

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

ANSELA

ANSA7

INLVLA7

LATA7

—

ANSA5

INLVLA5

LATA5

ANSA4

INLVLA4

LATA4

ANSA3

INLVLA3

LATA3

ODA3

ANSA2

INLVLA2

LATA2

ANSA1

INLVLA1

LATA1

ANSA0

INLVLA0

LATA0

115

116

114

116

174

114

116

114

115

INLVLA

INLVLA6

LATA6

ODA6

LATA

ODCONA

OPTION_REG

PORTA

ODA7

ODA5

ODA4

ODA2

ODA1

ODA0

WPUEN

RA7

INTEDG

RA6

TMR0CS

RA5

TMR0SE

RA4

PSA

PS<2:0>

RA1

RA3

RA2

RA0

SLRCONA

TRISA

SLRA7

TRISA7

WPUA7

SLRA6

TRISA6

WPUA6

SLRA5

TRISA5

WPUA5

SLRA4

TRISA4

WPUA4

SLRA3

TRISA3

WPUA3

SLRA2

TRISA2

WPUA2

SLRA1

TRISA1

WPUA1

SLRA0

TRISA0

WPUA0

WPUA

Legend:

x= unknown, u= unchanged, – = unimplemented locations read as ‘0’. Shaded cells are not used by PORTA.

TABLE 13-4: SUMMARY OF CONFIGURATION WORD WITH PORTA

Register

on Page

Name

Bits

Bit -/7

Bit -/6

Bit 13/5

Bit 12/4

Bit 11/3

Bit 10/2

Bit 9/1

Bit 8/0

13:8

7:0

—

FCMEN

PWRTE

IESO

CLKOUTEN

BOREN<1:0>

FOSC<2:0>

CPD

CONFIG1

40

CP

MCLRE

WDTE<1:0>

Legend:

— = unimplemented location, read as ‘0’. Shaded cells are not used by PORTA.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 117

PIC16(L)F1782/3

13.5.4

INPUT THRESHOLD CONTROL

13.5 PORTB Registers

The INLVLB register (Register 13-17) controls the input

voltage threshold for each of the available PORTB

input pins. A selection between the Schmitt Trigger

CMOS or the TTL Compatible thresholds is available.

The input threshold is important in determining the

value of a read of the PORTB register and also the level

at which an interrupt-on-change occurs, if that feature

is enabled. See Section TABLE 30-1: “Supply Volt-

age” for more information on threshold levels.

PORTB is an 8-bit wide, bidirectional port. The

corresponding data direction register is TRISB

(Register 13-11). Setting a TRISB bit (= 1) will make the

corresponding PORTB pin an input (i.e., put the

corresponding output driver in a High-Impedance mode).

Clearing a TRISB bit (= 0) will make the corresponding

PORTB pin an output (i.e., enable the output driver and

put the contents of the output latch on the selected pin).

Example 13-1 shows how to initialize an I/O port.

Note:

Changing the input threshold selection

should be performed while all peripheral

modules are disabled. Changing the

threshold level during the time a module is

active may inadvertently generate a tran-

sition associated with an input pin, regard-

less of the actual voltage level on that pin.

Reading the PORTB register (Register 13-10) reads the

status of the pins, whereas writing to it will write to the

PORT latch. All write operations are read-modify-write

operations. Therefore, a write to a port implies that the

port pins are read, this value is modified and then written

to the PORT data latch (LATB).

13.5.1

DIRECTION CONTROL

13.5.5

ANALOG CONTROL

The TRISB register (Register 13-11) controls the PORTB

pin output drivers, even when they are being used as

analog inputs. The user should ensure the bits in the

TRISB register are maintained set when using them as

analog inputs. I/O pins configured as analog inputs

always read ‘0’.

The ANSELB register (Register 13-13) is used to

configure the Input mode of an I/O pin to analog.

Setting the appropriate ANSELB bit high will cause all

digital reads on the pin to be read as ‘0’ and allow

analog functions on the pin to operate correctly.

The state of the ANSELB bits has no effect on digital out-

put functions. A pin with TRIS clear and ANSELB set will

still operate as a digital output, but the Input mode will be

analog. This can cause unexpected behavior when

executing read-modify-write instructions on the affected

port.

13.5.2

OPEN DRAIN CONTROL

The ODCONB register (Register 13-15) controls the

open-drain feature of the port. Open drain operation is

independently selected for each pin. When an

ODCONB bit is set, the corresponding port output

becomes an open drain driver capable of sinking

current only. When an ODCONB bit is cleared, the

corresponding port output pin is the standard push-pull

drive capable of sourcing and sinking current.

Note:

The ANSELB bits default to the Analog

mode after Reset. To use any pins as

digital general purpose or peripheral

inputs, the corresponding ANSEL bits

must be initialized to ‘0’ by user software.

13.5.3

SLEW RATE CONTROL

The SLRCONB register (Register 13-16) controls the

slew rate option for each port pin. Slew rate control is

independently selectable for each port pin. When an

SLRCONB bit is set, the corresponding port pin drive is

slew rate limited. When an SLRCONB bit is cleared,

The corresponding port pin drive slews at the maximum

rate possible.

DS40001579E-page 118

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

13.5.6

PORTB FUNCTIONS AND OUTPUT

PRIORITIES

Each PORTB pin is multiplexed with other functions. The

pins, their combined functions and their output priorities

are shown in Table 13-5.

When multiple outputs are enabled, the actual pin

control goes to the peripheral with the highest priority.

Analog input and some digital input functions are not

included in the list below. These input functions can

remain active when the pin is configured as an output.

Certain digital input functions override other port

functions and are included in the priority list.

TABLE 13-5: PORTB OUTPUT PRIORITY

Pin Name

Function Priority⁽¹⁾

RB0

CCP1

RB0

RB1

RB2

RB3

OPA2OUT

RB1

CLKR

RB2

CCP2

RB3

RB4

RB5

RB4

SDO

C3OUT

RB5

RB6

RB7

ICSPCLK

SDA

TX/CK

RB6

ICSPDAT

DACOUT2

SCL/SCK

DT

RB7

Note 1: Priority listed from highest to lowest.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 119

PIC16(L)F1782/3

13.6 Register Definitions: PORTB

REGISTER 13-10: PORTB: PORTB REGISTER

R/W-x/u

RB7

R/W-x/u

RB6

R/W-x/u

RB5

R/W-x/u

RB4

R/W-x/u

RB3

R/W-x/u

RB2

R/W-x/u

RB1

R/W-x/u

RB0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

RB<7:0>: PORTB General Purpose I/O Pin bits⁽¹⁾

1= Port pin is > VIH

0= Port pin is < VIL

Note 1: Writes to PORTB are actually written to corresponding LATB register. Reads from PORTB register is return of

actual I/O pin values.

REGISTER 13-11: TRISB: PORTB TRI-STATE REGISTER

R/W-1/1

TRISB7

R/W-1/1

TRISB6

R/W-1/1

TRISB5

R/W-1/1

TRISB4

R/W-1/1

TRISB3

R/W-1/1

TRISB2

R/W-1/1

TRISB1

R/W-1/1

TRISB0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

TRISB<7:0>: PORTB Tri-State Control bits

1= PORTB pin configured as an input (tri-stated)

0= PORTB pin configured as an output

REGISTER 13-12: LATB: PORTB DATA LATCH REGISTER

R/W-x/u

LATB7

R/W-x/u

LATB6

R/W-x/u

LATB5

R/W-x/u

LATB4

R/W-x/u

LATB3

R/W-x/u

LATB2

R/W-x/u

LATB1

R/W-x/u

LATB0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

LATB<7:0>: PORTB Output Latch Value bits⁽¹⁾

Note 1: Writes to PORTB are actually written to corresponding LATB register. Reads from PORTB register is

return of actual I/O pin values.

DS40001579E-page 120

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 13-13: ANSELB: PORTB ANALOG SELECT REGISTER

U-0

—

U-0

—

R/W-1/1

ANSB5

R/W-1/1

ANSB4

R/W-1/1

ANSB3

R/W-1/1

ANSB2

R/W-1/1

ANSB1

R/W-1/1

ANSB0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-6

bit 5-0

Unimplemented: Read as ‘0’

ANSB<5:0>: Analog Select between Analog or Digital Function on pins RB<5:0>, respectively

0= Digital I/O. Pin is assigned to port or digital special function.

1= Analog input. Pin is assigned as analog input⁽¹⁾. Digital input buffer disabled.

Note 1: When setting a pin to an analog input, the corresponding TRIS bit must be set to Input mode in order to

allow external control of the voltage on the pin.

REGISTER 13-14: WPUB: WEAK PULL-UP PORTB REGISTER

R/W-1/1

WPUB7

R/W-1/1

WPUB6

R/W-1/1

WPUB5

R/W-1/1

WPUB4

R/W-1/1

WPUB3

R/W-1/1

WPUB2

R/W-1/1

WPUB1

R/W-1/1

WPUB0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

WPUB<7:0>: Weak Pull-up Register bits

1= Pull-up enabled

0= Pull-up disabled

Note 1: Global WPUEN bit of the OPTION_REG register must be cleared for individual pull-ups to be enabled.

2: The weak pull-up device is automatically disabled if the pin is in configured as an output.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 121

PIC16(L)F1782/3

REGISTER 13-15: ODCONB: PORTB OPEN DRAIN CONTROL REGISTER

R/W-0/0

ODB7

R/W-0/0

ODB6

R/W-0/0

ODB5

R/W-0/0

ODB4

R/W-0/0

ODB3

R/W-0/0

ODB2

R/W-0/0

ODB1

R/W-0/0

ODB0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

ODB<7:0>: PORTB Open Drain Enable bits

For RB<7:0> pins, respectively

1= Port pin operates as open-drain drive (sink current only)

0= Port pin operates as standard push-pull drive (source and sink current)

REGISTER 13-16: SLRCONB: PORTB SLEW RATE CONTROL REGISTER

R/W-1/1

SLRB7

R/W-1/1

SLRB6

R/W-1/1

SLRB5

R/W-1/1

SLRB4

R/W-1/1

SLRB3

R/W-1/1

SLRB2

R/W-1/1

SLRB1

R/W-1/1

SLRB0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

SLRB<7:0>: PORTB Slew Rate Enable bits

For RB<7:0> pins, respectively

1= Port pin slew rate is limited

0= Port pin slews at maximum rate

REGISTER 13-17: INLVLB: PORTB INPUT LEVEL CONTROL REGISTER

R/W-0/0

INLVLB7

R/W-0/0

INLVLB6

R/W-0/0

INLVLB5

R/W-0/0

INLVLB4

R/W-0/0

INLVLB3

R/W-0/0

INLVLB2

R/W-0/0

INLVLB1

R/W-0/0

INLVLB0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

INLVLB<7:0>: PORTB Input Level Select bits

For RB<7:0> pins, respectively

1= ST input used for PORT reads and interrupt-on-change

0= TTL input used for PORT reads and interrupt-on-change

DS40001579E-page 122

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 13-6: SUMMARY OF REGISTERS ASSOCIATED WITH PORTB

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

ANSELB

INLVLB

LATB

—

ANSB5

ANSB4

ANSB3

ANSB2

ANSB1

ANSB0

121

122

120

122

120

122

120

121

INLVLB7 INLVLB6 INLVLB5 INLVLB4 INLVLB3 INLVLB2 INLVLB1 INLVLB0

LATB7

ODB7

LATB6

ODB6

LATB5

ODB5

LATB4

ODB4

LATB3

ODB3

RB3

LATB2

ODB2

RB2

LATB1

ODB1

RB1

LATB0

ODB0

RB0

ODCONB

PORTB

SLRCONB

TRISB

RB7

RB6

RB5

RB4

SLRB7

TRISB7

WPUB7

SLRB6

TRISB6

WPUB6

SLRB5

TRISB5

WPUB5

SLRB4

TRISB4

WPUB4

SLRB3

TRISB3

SLRB2

SLRB1

SLRB0

TRISB2 TRISB1 TRISB0

WPUB

WPUB3 WPUB2 WPUB1 WPUB0

Legend:

x = unknown, u = unchanged, - = unimplemented locations read as ‘0’. Shaded cells are not used by

PORTB.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 123

PIC16(L)F1782/3

Voltage” for more information on threshold levels.

13.7 PORTC Registers

Note:

Changing the input threshold selection

should be performed while all peripheral

modules are disabled. Changing the thresh-

old level during the time a module is active

may inadvertently generate a transition

associated with an input pin, regardless of

the actual voltage level on that pin.

13.7.1

DATA REGISTER

PORTC is an 8-bit wide bidirectional port. The

corresponding data direction register is TRISC

(Register 13-19). Setting a TRISC bit (= 1) will make the

corresponding PORTC pin an input (i.e., put the

corresponding output driver in a High-Impedance mode).

Clearing a TRISC bit (= 0) will make the corresponding

PORTC pin an output (i.e., enable the output driver and

put the contents of the output latch on the selected pin).

Example 13-1 shows how to initialize an I/O port.

13.7.6

PORTC FUNCTIONS AND OUTPUT

PRIORITIES

Reading the PORTC register (Register 13-18) reads the

status of the pins, whereas writing to it will write to the

PORT latch. All write operations are read-modify-write

operations. Therefore, a write to a port implies that the

port pins are read, this value is modified and then written

to the PORT data latch (LATC).

Each PORTC pin is multiplexed with other functions. The

pins, their combined functions and their output priorities

are shown in Table 13-7.

When multiple outputs are enabled, the actual pin

control goes to the peripheral with the highest priority.

Analog input and some digital input functions are not

included in the list below. These input functions can

remain active when the pin is configured as an output.

Certain digital input functions override other port

functions and are included in the priority list.

13.7.2

DIRECTION CONTROL

The TRISC register (Register 13-19) controls the

PORTC pin output drivers, even when they are being

used as analog inputs. The user should ensure the bits in

the TRISC register are maintained set when using them

as analog inputs. I/O pins configured as analog inputs

always read ‘0’.

TABLE 13-7: PORTC OUTPUT PRIORITY

Pin Name

Function Priority⁽¹⁾

RC0

T1OSO

PSMC1A

RC0

13.7.3

OPEN DRAIN CONTROL

The ODCONC register (Register 13-22) controls the

open-drain feature of the port. Open drain operation is

independently selected for each pin. When an

ODCONC bit is set, the corresponding port output

becomes an open drain driver capable of sinking

current only. When an ODCONC bit is cleared, the

corresponding port output pin is the standard push-pull

drive capable of sourcing and sinking current.

RC1

RC2

RC3

PSMC1B

CCP2

RC1

PSMC1C

CCP1

RC2

PSMC1D

SCL

13.7.4

SLEW RATE CONTROL

SCK

RC3

The SLRCONC register (Register 13-23) controls the

slew rate option for each port pin. Slew rate control is

independently selectable for each port pin. When an

SLRCONC bit is set, the corresponding port pin drive is

slew rate limited. When an SLRCONC bit is cleared,

The corresponding port pin drive slews at the maximum

rate possible.

RC4

RC5

RC6

RC7

PSMC1E

SDA

RC4

PSMC1F

SDO

RC5

13.7.5

INPUT THRESHOLD CONTROL

PSMC2A

TX/CK

RC6

The INLVLC register (Register 13-24) controls the input

voltage threshold for each of the available PORTC

input pins. A selection between the Schmitt Trigger

CMOS or the TTL Compatible thresholds is available.

The input threshold is important in determining the

value of a read of the PORTC register and also the

level at which an interrupt-on-change occurs, if that

feature is enabled. See Section TABLE 30-1: “Supply

PSMC2B

DT

RC7

Note 1: Priority listed from highest to lowest.

DS40001579E-page 124

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

13.8 Register Definitions: PORTC

REGISTER 13-18: PORTC: PORTC REGISTER

R/W-x/u

RC7

R/W-x/u

RC6

R/W-x/u

RC5

R/W-x/u

RC4

R/W-x/u

RC3

R/W-x/u

RC2

R/W-x/u

RC1

R/W-x/u

RC0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

RC<7:0>: PORTC General Purpose I/O Pin bits⁽¹⁾

1= Port pin is > VIH

0= Port pin is < VIL

Note 1: Writes to PORTC are actually written to corresponding LATC register. Reads from PORTC register is

return of actual I/O pin values.

REGISTER 13-19: TRISC: PORTC TRI-STATE REGISTER

R/W-1/1

TRISC7

R/W-1/1

TRISC6

R/W-1/1

TRISC5

R/W-1/1

TRISC4

R/W-1/1

TRISC3

R/W-1/1

TRISC2

R/W-1/1

TRISC1

R/W-1/1

TRISC0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

TRISC<7:0>: PORTC Tri-State Control bits

1= PORTC pin configured as an input (tri-stated)

0= PORTC pin configured as an output

REGISTER 13-20: LATC: PORTC DATA LATCH REGISTER

R/W-x/u

LATC7

R/W-x/u

LATC6

R/W-x/u

LATC5

R/W-x/u

LATC4

R/W-x/u

LATC3

R/W-x/u

LATC2

R/W-x/u

LATC1

R/W-x/u

LATC0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

LATC<7:0>: PORTC Output Latch Value bits⁽¹⁾

Note 1: Writes to PORTC are actually written to corresponding LATC register. Reads from PORTC register is

return of actual I/O pin values.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 125

PIC16(L)F1782/3

REGISTER 13-21: WPUC: WEAK PULL-UP PORTC REGISTER

R/W-1/1

WPUC7

R/W-1/1

WPUC6

R/W-1/1

WPUC5

R/W-1/1

WPUC4

R/W-1/1

WPUC3

R/W-1/1

WPUC2

R/W-1/1

WPUC1

R/W-1/1

WPUC0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

WPUC<7:0>: Weak Pull-up Register bits

1= Pull-up enabled

0= Pull-up disabled

Note 1: Global WPUEN bit of the OPTION_REG register must be cleared for individual pull-ups to be enabled.

2: The weak pull-up device is automatically disabled if the pin is in configured as an output.

REGISTER 13-22: ODCONC: PORTC OPEN DRAIN CONTROL REGISTER

R/W-0/0

ODC7

R/W-0/0

ODC6

R/W-0/0

ODC5

R/W-0/0

ODC4

R/W-0/0

ODC3

R/W-0/0

ODC2

R/W-0/0

ODC1

R/W-0/0

ODC0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

ODC<7:0>: PORTC Open Drain Enable bits

For RC<7:0> pins, respectively

1= Port pin operates as open-drain drive (sink current only)

0= Port pin operates as standard push-pull drive (source and sink current)

REGISTER 13-23: SLRCONC: PORTC SLEW RATE CONTROL REGISTER

R/W-1/1

SLRC7

R/W-1/1

SLRC6

R/W-1/1

SLRC5

R/W-1/1

SLRC4

R/W-1/1

SLRC3

R/W-1/1

SLRC2

R/W-1/1

SLRC1

R/W-1/1

SLRC0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-0

SLRC<7:0>: PORTC Slew Rate Enable bits

For RC<7:0> pins, respectively

1= Port pin slew rate is limited

0= Port pin slews at maximum rate

DS40001579E-page 126

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 13-24: INLVLC: PORTC INPUT LEVEL CONTROL REGISTER

R/W-1/1

INLVLC7

R/W-1/1

INLVLC6

R/W-1/1

INLVLC5

R/W-1/1

INLVLC4

R/W-1/1

INLVLC3

R/W-1/1

INLVLC2

R/W-1/1

INLVLC1

R/W-1/1

INLVLC0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

INLVLC<7:0>: PORTC Input Level Select bits

For RC<7:0> pins, respectively

1= ST input used for PORT reads and interrupt-on-change

0= TTL input used for PORT reads and interrupt-on-change

TABLE 13-8: SUMMARY OF REGISTERS ASSOCIATED WITH PORTC

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

LATC

LATC7

RC7

LATC6

RC6

LATC5

RC5

LATC4

RC4

LATC3

RC3

LATC2

RC2

LATC1

RC1

LATC0

RC0

125

126

127

125

126

125

126

PORTC

TRISC

TRISC7

TRISC6

TRISC5

WPUC5

TRISC4

TRISC3 TRISC2 TRISC1 TRISC0

WPUC

WPUC7 WPUC6

WPUC4 WPUC3 WPUC2 WPUC1 WPUC0

INLVLC

LATC

INLVLC7 INLVLC6 INLVLC5 INLVLC4 INLVLC3 INLVLC2 INLVLC1 INLVLC0

LATC7

ODC7

RC7

LATC6

ODC6

RC6

LATC5

ODC5

RC5

LATC4

ODC4

RC4

LATC3

ODC3

RC3

LATC2

ODC2

RC2

LATC1

ODC1

RC1

LATC0

ODC0

RC0

ODCONC

PORTC

SLRCONC

Legend:

SLRC7

SLRC6

SLRC5

SLRC4

SLRC3

SLRC2

SLRC1

SLRC0

x = unknown, u = unchanged, - = unimplemented locations read as ‘0’. Shaded cells are not used by

PORTC.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 127

PIC16(L)F1782/3

13.9 PORTE Registers

RE3 is input only, and also functions as MCLR. The

MCLR feature can be disabled via a configuration fuse.

RE3 also supplies the programming voltage. The TRIS bit

for RE3 (TRISE3) always reads ‘1’.

13.9.1

INPUT THRESHOLD CONTROL

The INLVLE register (Register 13-28) controls the input

voltage threshold for each of the available PORTE

input pins. A selection between the Schmitt Trigger

CMOS or the TTL Compatible thresholds is available.

The input threshold is important in determining the

value of a read of the PORTE register and also the level

at which an interrupt-on-change occurs, if that feature

is enabled. See Section TABLE 30-1: “Supply Volt-

age” for more information on threshold levels.

Note:

Changing the input threshold selection

should be performed while all peripheral

modules are disabled. Changing the

threshold level during the time a module is

active may inadvertently generate

a

transition associated with an input pin,

regardless of the actual voltage level on

that pin.

13.9.2

PORTE FUNCTIONS AND OUTPUT

PRIORITIES

No output priorities. RE3 is an input-only pin.

DS40001579E-page 128

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

13.10 Register Definitions: PORTE

REGISTER 13-25: PORTE: PORTE REGISTER

U-0

—

U-0

—

U-0

—

U-0

—

R-x/u

RE3

U-0

—

U-0

—

U-0

—

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-4

bit 3

Unimplemented: Read as ‘0’

RE3: PORTE Input Pin bit

1= Port pin is > VIH

0= Port pin is < VIL

bit 2-0

Unimplemented: Read as ‘0’

REGISTER 13-26: TRISE: PORTE TRI-STATE REGISTER

U-0

—

U-0

—

U-0

—

U-0

—

U-1⁽¹⁾

—

U-0

—

U-0

—

U-0

—

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-4

bit 3

Unimplemented: Read as ‘0’

Unimplemented: Read as ‘1’

Unimplemented: Read as ‘0’

bit 2-0

Note 1: Unimplemented, read as ‘1’.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 129

PIC16(L)F1782/3

REGISTER 13-27: WPUE: WEAK PULL-UP PORTE REGISTER

U-0

—

U-0

—

U-0

—

U-0

—

R/W-1/1

WPUE3

U-0

—

U-0

—

U-0

—

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-4

bit 3

Unimplemented: Read as ‘0’

WPUE3: Weak Pull-up Register bit

1= Pull-up enabled

0= Pull-up disabled

bit 2-0

Unimplemented: Read as ‘0’

Note 1: Global WPUEN bit of the OPTION_REG register must be cleared for individual pull-ups to be enabled.

2: The weak pull-up device is automatically disabled if the pin is in configured as an output.

REGISTER 13-28: INLVLE: PORTE INPUT LEVEL CONTROL REGISTER

U-0

—

U-0

—

U-0

—

U-0

—

R/W-1/1

INLVLE3

U-0

—

U-0

—

U-0

—

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-4

bit 3

Unimplemented: Read as ‘0’

INLVLE3: PORTE Input Level Select bit⁽¹⁾

1= ST input used for PORT reads and interrupt-on-change

0= TTL input used for PORT reads and interrupt-on-change

bit 2-0

Unimplemented: Read as ‘0’

TABLE 13-9: SUMMARY OF REGISTERS ASSOCIATED WITH PORTE

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

ADCON0

INLVLE

PORTE

TRISE

ADRMD

CHS<4:0>

GO/DONE

ADON

—

147

130

129

130

—

INLVLE3

RE3

—

(1)

—

WPUE

WPUE3

—

Legend:

x= unknown, u= unchanged, – = unimplemented locations read as ‘0’. Shaded cells are not used by PORTE.

Note 1: Unimplemented, read as ‘1’.

2: PIC16(L)F1783 only

DS40001579E-page 130

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

14.3 Interrupt Flags

14.0 INTERRUPT-ON-CHANGE

The bits located in the IOCxF registers are status flags

that correspond to the Interrupt-on-change pins of each

port. If an expected edge is detected on an appropriately

enabled pin, then the status flag for that pin will be set,

and an interrupt will be generated if the IOCIE bit is set.

The IOCIF bit of the INTCON register reflects the status

of all IOCxF bits.

All pins on all ports can be configured to operate as

Interrupt-On-Change (IOC) pins. An interrupt can be

generated by detecting a signal that has either a rising

edge or a falling edge. Any individual pin, or combination

of pins, can be configured to generate an interrupt. The

interrupt-on-change module has the following features:

• Interrupt-on-Change enable (Master Switch)

• Individual pin configuration

14.4 Clearing Interrupt Flags

• Rising and falling edge detection

• Individual pin interrupt flags

The individual status flags, (IOCxF register bits), can be

cleared by resetting them to zero. If another edge is

detected during this clearing operation, the associated

status flag will be set at the end of the sequence,

regardless of the value actually being written.

Figure 14-1 is a block diagram of the IOC module.

14.1 Enabling the Module

To allow individual pins to generate an interrupt, the

IOCIE bit of the INTCON register must be set. If the

IOCIE bit is disabled, the edge detection on the pin will

still occur, but an interrupt will not be generated.

In order to ensure that no detected edge is lost while

clearing flags, only AND operations masking out known

changed bits should be performed. The following

sequence is an example of what should be performed.

EXAMPLE 14-1:

CLEARING INTERRUPT

FLAGS

(PORTA EXAMPLE)

14.2 Individual Pin Configuration

For each pin, a rising edge detector and a falling edge

detector are present. To enable a pin to detect a rising

edge, the associated bit of the IOCxP register is set. To

enable a pin to detect a falling edge, the associated bit

of the IOCxN register is set.

MOVLW 0xff

XORWF IOCAF, W

ANDWF IOCAF, F

A pin can be configured to detect rising and falling

edges simultaneously by setting the associated bits in

both of the IOCxP and IOCxN registers.

14.5 Operation in Sleep

The interrupt-on-change interrupt sequence will wake

the device from Sleep mode, if the IOCIE bit is set.

If an edge is detected while in Sleep mode, the affected

IOCxF register will be updated prior to the first

instruction executed out of Sleep.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 131

PIC16(L)F1782/3

FIGURE 14-1:

INTERRUPT-ON-CHANGE BLOCK DIAGRAM

Q4Q1

IOCBNx

D

Q

CK

edge

detect

R

RBx

data bus =

0 or 1

S

to data bus

IOCBFx

IOCBPx

D

Q

D

Q

write IOCBFx

CK

IOCIE

R

Q2

from all other

IOCBFx individual

pin detectors

IOC interrupt

to CPU core

Q1

Q2

Q3

Q2

Q3

Q4

Q4Q1

Q4

Q4Q1

DS40001579E-page 132

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

14.6 Register Definitions: Interrupt-on-Change Control

REGISTER 14-1: IOCxP: INTERRUPT-ON-CHANGE POSITIVE EDGE REGISTER

R/W-0/0

IOCxP7

R/W-0/0

IOCxP6

R/W-0/0

IOCxP5

R/W-0/0

IOCxP4

R/W-0/0

IOCxP3

R/W-0/0

IOCxP2

R/W-0/0

IOCxP1

R/W-0/0

IOCxP0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

IOCxP<7:0>: Interrupt-on-Change Positive Edge Enable bits⁽¹⁾

1= Interrupt-on-Change enabled on the pin for a positive going edge. Associated Status bit and

interrupt flag will be set upon detecting an edge.

0= Interrupt-on-Change disabled for the associated pin.

Note 1: For IOCEP register, bit 3 (IOCEP3) is the only implemented bit in the register.

REGISTER 14-2: IOCxN: INTERRUPT-ON-CHANGE NEGATIVE EDGE REGISTER

R/W-0/0

IOCxN7

R/W-0/0

IOCxN6

R/W-0/0

IOCxN5

R/W-0/0

IOCxN4

R/W-0/0

IOCxN3

R/W-0/0

IOCxN2

R/W-0/0

IOCxN1

R/W-0/0

IOCxN0

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

IOCxN<7:0>: Interrupt-on-Change Negative Edge Enable bits⁽¹⁾

1= Interrupt-on-Change enabled on the pin for a negative going edge. Associated Status bit and

interrupt flag will be set upon detecting an edge.

0= Interrupt-on-Change disabled for the associated pin.

Note 1: For IOCEN register, bit 3 (IOCEN3) is the only implemented bit in the register.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 133

PIC16(L)F1782/3

REGISTER 14-3: IOCxF: INTERRUPT-ON-CHANGE FLAG REGISTER

R/W/HS-0/0 R/W/HS-0/0 R/W/HS-0/0 R/W/HS-0/0 R/W/HS-0/0 R/W/HS-0/0 R/W/HS-0/0 R/W/HS-0/0

IOCxF7

bit 7

IOCxF6

IOCxF5

IOCxF4

IOCxF3

IOCxF2

IOCxF1

IOCxF0

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

-n/n = Value at POR and BOR/Value at all other Resets

HS - Bit is set in hardware

bit 7-0

IOCxF<7:0>: Interrupt-on-Change Flag bits⁽¹⁾

1= An enabled change was detected on the associated pin.

Set when IOCxPx = 1and a rising edge was detected RBx, or when IOCxNx = 1and a falling edge

was detected on RBx.

0= No change was detected, or the user cleared the detected change.

Note 1: For IOCEF register, bit 3 (IOCEF3) is the only implemented bit in the register.

TABLE 14-1:

Name

SUMMARY OF REGISTERS ASSOCIATED WITH INTERRUPT-ON-CHANGE

Register

on Page

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

ANSELB

INTCON

IOCAF

IOCAN

IOCAP

IOCBF

IOCBN

IOCBP

IOCCF

IOCCN

IOCCP

IOCEF

IOCEN

IOCEP

—

ANSB5

ANSB4

INTE

ANSB3

IOCIE

ANSB2

ANSB1

INTF

ANSB0

IOCIF

121

79

GIE

PEIE

TMR0IE

TMR0IF

IOCAF7 IOCAF6 IOCAF5 IOCAF4 IOCAF3 IOCAF2 IOCAF1 IOCAF0

IOCAN7 IOCAN6 IOCAN5 IOCAN4 IOCAN3 IOCAN2 IOCAN1 IOCAN0

IOCAP7 IOCAP6 IOCAP5 IOCAP4 IOCAP3 IOCAP2 IOCAP1 IOCAP0

IOCBF7 IOCBF6 IOCBF5 IOCBF4 IOCBF3 IOCBF2 IOCBF1 IOCBF0

IOCBN7 IOCBN6 IOCBN5 IOCBN4 IOCBN3 IOCBN2 IOCBN1 IOCBN0

IOCBP7 IOCBP6 IOCBP5 IOCBP4 IOCBP3 IOCBP2 IOCBP1 IOCBP0

IOCCF7 IOCCF6 IOCCF5 IOCCF4 IOCCF3 IOCCF2 IOCCF1 IOCCF0

IOCCN7 IOCCN6 IOCCN5 IOCCN4 IOCCN3 IOCCN2 IOCCN1 IOCCN0

IOCCP7 IOCCP6 IOCCP5 IOCCP4 IOCCP3 IOCCP2 IOCCP1 IOCCP0

134

133

134

133

134

133

134

133

120

—

IOCEF3

IOCEN3

IOCEP3

—

TRISB7 TRISB6 TRISB5 TRISB4 TRISB3 TRISB2 TRISB1 TRISB0

TRISB

Legend: — = unimplemented location, read as ‘0’. Shaded cells are not used by interrupt-on-change.

DS40001579E-page 134

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

15.1 Independent Gain Amplifiers

15.0 FIXED VOLTAGE REFERENCE

(FVR)

The output of the FVR supplied to the ADC,

Comparators, and DAC is routed through two

independent programmable gain amplifiers. Each

amplifier can be programmed for a gain of 1x, 2x or 4x,

to produce the three possible voltage levels.

The Fixed Voltage Reference, or FVR, is a stable

voltage reference, independent of VDD, with 1.024V,

2.048V or 4.096V selectable output levels. The output

of the FVR can be configured to supply a reference

voltage to the following:

The ADFVR<1:0> bits of the FVRCON register are used

to enable and configure the gain amplifier settings for

the reference supplied to the ADC module. Reference

Section 17.0 “Analog-to-Digital Converter (ADC)

Module” for additional information.

• ADC input channel

• ADC positive reference

• Comparator positive input

• Digital-to-Analog Converter (DAC)

The CDAFVR<1:0> bits of the FVRCON register are

used to enable and configure the gain amplifier settings

for the reference supplied to the DAC and comparator

module. Reference Section 19.0 “Digital-to-Analog

Converter (DAC) Module” and Section 20.0

“Comparator Module” for additional information.

The FVR can be enabled by setting the FVREN bit of

the FVRCON register.

15.2 FVR Stabilization Period

When the Fixed Voltage Reference module is enabled, it

requires time for the reference and amplifier circuits to

stabilize. Once the circuits stabilize and are ready for use,

the FVRRDY bit of the FVRCON register will be set. See

Section 30.0 “Electrical Specifications” for the

minimum delay requirement.

15.3 FVR Buffer Stabilization Period

When either FVR Buffer1 or FVR Buffer 2 is enabled,

the buffer amplifier circuits require 30 s to stabilize.

This stabilization time is required even when the FVR

is already operating and stable.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 135

PIC16(L)F1782/3

FIGURE 15-1:

VOLTAGE REFERENCE BLOCK DIAGRAM

ADFVR<1:0>

2

X1

X2

X4

FVR BUFFER1

(To ADC Module)

CDAFVR<1:0>

2

X1

X2

X4

FVR BUFFER2

(To Comparators, DAC)

HFINTOSC Enable

HFINTOSC

To BOR, LDO

+

_

FVREN

FVRRDY

Any peripheral requiring the

Fixed Reference

(See Table 15-1)

TABLE 15-1: PERIPHERALS REQUIRING THE FIXED VOLTAGE REFERENCE (FVR)

Peripheral

Conditions

Description

HFINTOSC

FOSC<2:0> = 100and

IRCF<3:0>  000x

INTOSC is active and device is not in Sleep

BOREN<1:0> = 11

BOR always enabled

BOR

LDO

BOREN<1:0> = 10and BORFS = 1 BOR disabled in Sleep mode, BOR Fast Start enabled.

BOREN<1:0> = 01and BORFS = 1 BOR under software control, BOR Fast Start enabled

All PIC16F1782/3 devices, when

The device runs off of the ULP regulator when in Sleep mode.

VREGPM = 1and not in Sleep

PSMC 64 MHz PxSRC<1:0>

64 MHz clock forces HFINTOSC on during Sleep.

DS40001579E-page 136

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

15.4 Register Definitions: FVR Control

REGISTER 15-1: FVRCON: FIXED VOLTAGE REFERENCE CONTROL REGISTER

R/W-0/0

FVREN

R-q/q

FVRRDY⁽¹⁾

R/W-0/0

TSEN

R/W-0/0

TSRNG

R/W-0/0

CDAFVR<1:0>

ADFVR<1:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

-n/n = Value at POR and BOR/Value at all other Resets

q = Value depends on condition

bit 7

bit 6

bit 5

bit 4

bit 3-2

FVREN: Fixed Voltage Reference Enable bit

1= Fixed Voltage Reference is enabled

0= Fixed Voltage Reference is disabled

FVRRDY: Fixed Voltage Reference Ready Flag bit⁽¹⁾

1= Fixed Voltage Reference output is ready for use

0= Fixed Voltage Reference output is not ready or not enabled

TSEN: Temperature Indicator Enable bit⁽³⁾

1= Temperature Indicator is enabled

0= Temperature Indicator is disabled

TSRNG: Temperature Indicator Range Selection bit⁽³⁾

1= VOUT = VDD - 4VT (High Range)

0= VOUT = VDD - 2VT (Low Range)

CDAFVR<1:0>: Comparator and DAC Fixed Voltage Reference Selection bit

11= Comparator and DAC Fixed Voltage Reference Peripheral output is 4x (4.096V)⁽²⁾

10= Comparator and DAC Fixed Voltage Reference Peripheral output is 2x (2.048V)⁽²⁾

01= Comparator and DAC Fixed Voltage Reference Peripheral output is 1x (1.024V)

00= Comparator and DAC Fixed Voltage Reference Peripheral output is off.

bit 1-0

ADFVR<1:0>: ADC Fixed Voltage Reference Selection bit

11= ADC Fixed Voltage Reference Peripheral output is 4x (4.096V)⁽²⁾

10= ADC Fixed Voltage Reference Peripheral output is 2x (2.048V)⁽²⁾

01= ADC Fixed Voltage Reference Peripheral output is 1x (1.024V)

00= ADC Fixed Voltage Reference Peripheral output is off.

Note 1: FVRRDY is always ‘1’ on “F” devices only.

2: Fixed Voltage Reference output cannot exceed VDD.

3: See Section 16.0 “Temperature Indicator Module” for additional information.

TABLE 15-2: SUMMARY OF REGISTERS ASSOCIATED WITH FIXED VOLTAGE REFERENCE

Register

on page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

FVRCON

FVREN

FVRRDY

TSEN

TSRNG

CDAFVR<1:0>

ADFVR<1:0>

137

Legend:

Shaded cells are not used with the Fixed Voltage Reference.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 137

PIC16(L)F1782/3

FIGURE 16-1:

TEMPERATURE CIRCUIT

DIAGRAM

16.0 TEMPERATURE INDICATOR

MODULE

This family of devices is equipped with a temperature

circuit designed to measure the operating temperature

of the silicon die. The circuit’s range of operating

temperature falls between -40°C and +85°C. The

output is a voltage that is proportional to the device

temperature. The output of the temperature indicator is

internally connected to the device ADC.

VDD

TSEN

TSRNG

The circuit may be used as a temperature threshold

detector or a more accurate temperature indicator,

depending on the level of calibration performed. A one-

point calibration allows the circuit to indicate a

temperature closely surrounding that point. A two-point

calibration allows the circuit to sense the entire range

of temperature more accurately. Reference Application

Note AN1333, “Use and Calibration of the Internal

Temperature Indicator” (DS01333) for more details

regarding the calibration process.

VOUT

To ADC

16.1 Circuit Operation

16.2 Minimum Operating VDD

Figure 16-1 shows a simplified block diagram of the

temperature circuit. The proportional voltage output is

achieved by measuring the forward voltage drop across

multiple silicon junctions.

When the temperature circuit is operated in low range,

the device may be operated at any operating voltage

that is within specifications.

When the temperature circuit is operated in high range,

the device operating voltage, VDD, must be high

enough to ensure that the temperature circuit is

correctly biased.

Equation 16-1 describes the output characteristics of

the temperature indicator.

EQUATION 16-1: VOUT RANGES

Table 16-1 shows the recommended minimum VDD vs.

range setting.

High Range: VOUT = VDD - 4VT

Low Range: VOUT = VDD - 2VT

TABLE 16-1: RECOMMENDED VDD VS.

RANGE

Min. VDD, TSRNG = 1

Min. VDD, TSRNG = 0

The temperature sense circuit is integrated with the

Fixed Voltage Reference (FVR) module. See

Section 15.0 “Fixed Voltage Reference (FVR)” for

more information.

3.6V

1.8V

16.3 Temperature Output

The output of the circuit is measured using the internal

Analog-to-Digital Converter. A channel is reserved for

the temperature circuit output. Refer to Section 17.0

“Analog-to-Digital Converter (ADC) Module” for

detailed information.

The circuit is enabled by setting the TSEN bit of the

FVRCON register. When disabled, the circuit draws no

current.

The circuit operates in either high or low range. The high

range, selected by setting the TSRNG bit of the

FVRCON register, provides a wider output voltage. This

provides more resolution over the temperature range,

but may be less consistent from part to part. This range

requires a higher bias voltage to operate and thus, a

higher VDD is needed.

16.4 ADC Acquisition Time

To ensure accurate temperature measurements, the

user must wait at least 200 s after the ADC input

multiplexer is connected to the temperature indicator

output before the conversion is performed. In addition,

the user must wait 200 s between sequential

conversions of the temperature indicator output.

The low range is selected by clearing the TSRNG bit of

the FVRCON register. The low range generates a lower

voltage drop and thus, a lower bias voltage is needed to

operate the circuit. The low range is provided for low-

voltage operation.

DS40001579E-page 138

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 16-2: SUMMARY OF REGISTERS ASSOCIATED WITH THE TEMPERATURE INDICATOR

Register

on page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

FVRCON

FVREN

FVRRDY

TSEN

TSRNG

—

ADFVR<1:0>

136

Legend:

Shaded cells are unused by the temperature indicator module.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 139

PIC16(L)F1782/3

the conversion result into the ADC result registers

(ADRESH:ADRESL register pair). Figure 17-1 shows

the block diagram of the ADC.

17.0 ANALOG-TO-DIGITAL

CONVERTER (ADC) MODULE

The Analog-to-Digital Converter (ADC) allows

conversion of a single-ended and differential analog

input signals to a 12-bit binary representation of that

signal. This device uses analog inputs, which are

multiplexed into a single sample and hold circuit. The

output of the sample and hold is connected to the input

of the converter. The converter generates a 12-bit

binary result via successive approximation and stores

The ADC voltage reference is software selectable to be

either internally generated or externally supplied.

The ADC can generate an interrupt upon completion of

a conversion. This interrupt can be used to wake-up the

device from Sleep.

FIGURE 17-1:

ADC BLOCK DIAGRAM

ADPREF = 11

VDD

ADPREF = 00

ADPREF = 01

VREF+

AN0

AN1

00000

00001

00010

00011

00100

00101

VREF-/AN2

VREF+/AN3

AN4

ADNREF = 1

ADPNEF = 0

Reserved

AN8

00110

00111

01000

01001

01010

01011

01100

01101

10

Ref+ Ref-

1

+

-

ADC

12

AN9

0

GO/DONE

12

AN10

ADRMD

AN11

0= Sign Magnitude

1= 2’s Complement

AN12

ADFM

ADON⁽¹⁾

AN13

16

VSS

ADRESH ADRESL

11101

11110

11111

Temperature Indicator

DAC_output

FVR Buffer1

CHS<4:0>⁽²⁾

CHSN<3:0>

Note 1: When ADON = 0, all multiplexer inputs are disconnected.

2: See ADCON0 register (Register 17-1) and ADCON2 register (Register 17-3) for detailed

analog channel selection per device.

DS40001579E-page 140

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

17.1.3

ADC VOLTAGE REFERENCE

17.1 ADC Configuration

The ADPREF bits of the ADCON1 register provide

control of the positive voltage reference. The positive

voltage reference can be:

When configuring and using the ADC the following

functions must be considered:

• Port configuration

• Channel selection

- Single-ended

• VREF+

• VDD

• FVR Buffer1

- Differential

The ADNREF bits of the ADCON1 register provide

control of the negative voltage reference. The negative

voltage reference can be:

• ADC voltage reference selection

• ADC conversion clock source

• Interrupt control

• VREF- pin

• VSS

• Result formatting

17.1.1

PORT CONFIGURATION

See Section 15.0 “Fixed Voltage Reference (FVR)”

for more details on the Fixed Voltage Reference.

The ADC can be used to convert both analog and

digital signals. When converting analog signals, the I/O

pin should be configured for analog by setting the

associated TRIS and ANSEL bits. Refer to

Section 13.0 “I/O Ports” for more information.

17.1.4

CONVERSION CLOCK

The source of the conversion clock is software

selectable via the ADCS bits of the ADCON1 register.

There are seven possible clock options:

Note:

Analog voltages on any pin that is defined

as a digital input may cause the input

buffer to conduct excess current.

• FOSC/2

• FOSC/4

• FOSC/8

17.1.2

CHANNEL SELECTION

• FOSC/16

There are up to 14 channel selections available:

• FOSC/32

• AN<13:8, 4:0> pins

• FOSC/64

• Temperature Indicator

• DAC_output

• FRC (dedicated internal FRC oscillator)

The time to complete one bit conversion is defined as

TAD. One full 12-bit conversion requires 15 TAD periods

as shown in Figure 17-2.

• FVR (Fixed Voltage Reference) Output

Refer to Section 15.0 “Fixed Voltage Reference

(FVR)” and Section 16.0 “Temperature Indicator

Module” for more information on these channel

selections.

For correct conversion, the appropriate TAD specification

must be met. Refer to the ADC conversion requirements

in Section 30.0 “Electrical Specifications” for more

information. Table 17-1 gives examples of appropriate

ADC clock selections.

When converting differential signals, the negative input

for the channel is selected with the CHSN<3:0> bits of

the ADCON2 register. Any positive input can be paired

with any negative input to determine the differential

channel.

Note:

Unless using the FRC, any changes in the

system clock frequency will change the

ADC clock frequency, which may

adversely affect the ADC result.

The CHS<4:0> bits of the ADCON0 register determine

which positive channel is selected.

When CHSN<3:0> = 1111then the ADC is effectively

a single ended ADC converter.

When changing channels, a delay is required before

starting the next conversion.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 141

PIC16(L)F1782/3

TABLE 17-1: ADC CLOCK PERIOD (TAD) VS. DEVICE OPERATING FREQUENCIES

ADC Clock Period (TAD)

Device Frequency (FOSC)

ADC

ADCS<2:0>

Clock Source

32 MHz

20 MHz

16 MHz

8 MHz

4 MHz

1 MHz

FOSC/2

FOSC/4

FOSC/8

FOSC/16

FOSC/32

FOSC/64

FRC

000

100

001

101

010

110

x11

62.5ns⁽²⁾

125 ns⁽²⁾

0.5 s⁽²⁾

800 ns

100 ns⁽²⁾

200 ns⁽²⁾

400 ns⁽²⁾

800 ns

125 ns⁽²⁾

250 ns⁽²⁾

0.5 s⁽²⁾

1.0 s

250 ns⁽²⁾

500 ns⁽²⁾

1.0 s

500 ns⁽²⁾

1.0 s

2.0 s

4.0 s

8.0 s⁽³⁾

16.0 s⁽³⁾

32.0 s⁽³⁾

64.0 s⁽³⁾

2.0 s

4.0 s

1.0 s

1.6 s

2.0 s

4.0 s

8.0 s⁽³⁾

16.0 s⁽³⁾

2.0 s

3.2 s

4.0 s

1.0-6.0 s^(1,4)1.0-6.0 s^(1,4)1.0-6.0 s^(1,4)1.0-6.0 s^(1,4)1.0-6.0 s^(1,4)1.0-6.0 s^(1,4)

Legend:

Shaded cells are outside of recommended range.

Note 1: The FRC source has a typical TAD time of 1.6 s for VDD.

2: These values violate the minimum required TAD time.

3: For faster conversion times, the selection of another clock source is recommended.

4: The ADC clock period (TAD) and total ADC conversion time can be minimized when the ADC clock is derived from the

system clock FOSC. However, the FRC oscillator source must be used when conversions are to be performed with the

device in Sleep mode.

FIGURE 17-2:

ANALOG-TO-DIGITAL CONVERSION TAD CYCLES

TCY - TAD

TAD6 TAD7 TAD8 TAD9 TAD10 TAD11 TAD12 TAD13 TAD14 TAD15 TAD16 TAD17

b1 b0

TAD1 TAD2 TAD3 TAD4 TAD5

sign

b6

b3

b2

b11

b10

b9

b8

b7

b5

b4

Conversion

starts

Holding cap.

discharge

Holding cap disconnected

from input

Set GO

bit

Input

Sample

On the following cycle:

GO bit is cleared, ADIF bit is set,

holding capacitor is connected to analog input.

DS40001579E-page 142

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

17.1.5

INTERRUPTS

17.1.6

RESULT FORMATTING

The ADC module allows for the ability to generate an

interrupt upon completion of an Analog-to-Digital

conversion. The ADC Interrupt Flag is the ADIF bit in

the PIR1 register. The ADC Interrupt Enable is the

ADIE bit in the PIE1 register. The ADIF bit must be

cleared in software.

The 10-bit and 12-bit ADC conversion results can be

supplied in two formats: 2’s complement or

sign-magnitude. The ADFM bit of the ADCON1 register

controls the output format. Sign magnitude is left

justified with the sign bit in the LSb position. Negative

numbers are indicated when the sign bit is '1'.

Two's complement is right justified with the sign

extended into the most significant bits.

Note 1: The ADIF bit is set at the completion of

every conversion, regardless of whether

or not the ADC interrupt is enabled.

Figure 17-3 shows the two output formats. Table 17-2

shows conversion examples.

2: The ADC operates during Sleep only

when the FRC oscillator is selected.

This interrupt can be generated while the device is

operating or while in Sleep. If the device is in Sleep, the

interrupt will wake-up the device. Upon waking from

Sleep, the next instruction following the SLEEP

instruction is always executed. If the user is attempting

to wake-up from Sleep and resume in-line code

execution, the GIE and PEIE bits of the INTCON

register must be disabled. If the GIE and PEIE bits of

the INTCON register are enabled, execution will switch

to the Interrupt Service Routine.

FIGURE 17-3:

ADC CONVERSION RESULT FORMAT

12-bit sign and magnitude

Bit 11 Bit 10 Bit 9 Bit 8 Bit 7 Bit 6 Bit 5 Bit 4

bit 7 bit 0

Bit 3 Bit 2 Bit 1 Bit 0 ‘0’

‘0’

‘0’ Sign

ADFM = 0

bit 7

bit 0

ADRMD = 0

12-bit ADC Result

Loaded with ‘0’

12-bit 2’s compliment

Bit 12 Bit 12 Bit 12 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8

bit 7 bit 0

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

ADFM = 1

bit 7

bit 0

ADRMD = 0

Loaded with Sign bits’

12-bit ADC Result

10-bit sign and magnitude

Bit 9 Bit 8 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2

bit 7 bit 0

Bit 1 Bit 0 ‘0’

‘0’

‘0’ Sign

ADFM = 0

bit 7

bit 0

ADRMD = 1

10-bit ADC Result

Loaded with ‘0’

10-bit 2’s compliment

Bit 10 Bit 10 Bit 10 Bit 10 Bit 10 Bit 10 Bit 9 Bit 8

bit 7 bit 0

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

ADFM = 1

bit 7

bit 0

ADRMD = 1

Loaded with Sign bits’

10-bit ADC Result

 2011-2014 Microchip Technology Inc.

DS40001579E-page 143

PIC16(L)F1782/3

TABLE 17-2: ADC OUTPUT RESULTS FORMAT

Sign and Magnitude Result

2’s Compliment Result

ADFM = 0, ADRMD = 0

ADFM = 1, ADRMD = 0

Absolute ADC Value

(decimal)

ADRESH

ADRESL

ADRESH

ADRESL

(ADRES<15:8>)

(ADRES<7:0>)

(ADRES<15:8>)

(ADRES<7:0>)

+ 4095

+ 2355

+ 0001

0000

1111 1111

1001 0011

0000 0000

1111 1111

0000 0000

1111 0000

0011 0000

0001 0000

0000 0000

0001 0001

1111 0001

0000 0001

0000 1111

0000 1001

0000 0000

1111 1111

1111 0000

1111 1111

0011 0011

0000 0001

0000 0000

1111 1111

0000 0001

0000 0000

- 0001

- 4095

- 4096

Note 1: For the RSD ADC, the raw 13-bits from the ADC is presented in 2’s compliment format, so no data

translation is required for 2’s compliment results.

2: For the SAR ADC, the raw 13-bits from the ADC is presented in sign and magnitude format, so no data

translation is required for sign and magnitude results

DS40001579E-page 144

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

17.2.4

ADC OPERATION DURING SLEEP

17.2 ADC Operation

The ADC module can operate during Sleep. This

requires the ADC clock source to be set to the FRC

option. When the FRC oscillator source is selected, the

ADC waits one additional instruction before starting the

conversion. This allows the SLEEP instruction to be

executed, which can reduce system noise during the

conversion. If the ADC interrupt is enabled, the device

will wake-up from Sleep when the conversion

completes. If the ADC interrupt is disabled, the ADC

module is turned off after the conversion completes,

although the ADON bit remains set.

17.2.1

STARTING A CONVERSION

To enable the ADC module, the ADON bit of the

ADCON0 register must be set to a ‘1’. Setting the

GO/DONE bit of the ADCON0 register to a ‘1’ will clear

the ADRESH and ADRESL registers and start the

Analog-to-Digital conversion.

Note:

The GO/DONE bit should not be set in the

same instruction that turns on the ADC.

Refer to Section 17.2.6 “A/D Conversion

Procedure”.

When the ADC clock source is something other than

FRC, a SLEEP instruction causes the present conver-

sion to be aborted and the ADC module is turned off,

although the ADON bit remains set.

17.2.2

COMPLETION OF A CONVERSION

When the conversion is complete, the ADC module will:

• Clear the GO/DONE bit

17.2.5

AUTO-CONVERSION TRIGGER

• Set the ADIF Interrupt Flag bit

The Auto-conversion Trigger allows periodic ADC mea-

surements without software intervention. When a rising

edge of the selected source occurs, the GO/DONE bit

is set by hardware.

17.2.3

TERMINATING A CONVERSION

When a conversion is terminated before completion by

clearing the GO/DONE bit then the partial results are

discarded and the results in the ADRESH and ADRESL

registers from the previous conversion remain

unchanged.

The Auto-conversion Trigger source is selected with

the TRIGSEL<3:0> bits of the ADCON2 register.

Using the Auto-conversion Trigger does not assure

proper ADC timing. It is the user’s responsibility to

ensure that the ADC timing requirements are met.

Note:

A device Reset forces all registers to their

Reset state. Thus, the ADC module is

turned off and any pending conversion is

terminated.

Auto-conversion sources are:

• CCP1

• CCP2

• PSMC1⁽¹⁾

• PSMC2⁽¹⁾

Note:

The PSMC clock frequency, after the

prescaler, must be less than FOSC/4 to

ensure that the ADC detects the

auto-conversion trigger. This limitation can

be overcome by synchronizing a slave

PSMC, running at the required slower

clock frequency, to the first PSMC and

triggering the conversion from the slave

PSMC.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 145

PIC16(L)F1782/3

17.2.6

A/D CONVERSION PROCEDURE

EXAMPLE 17-1:

A/D CONVERSION

This is an example procedure for using the ADC to

perform an Analog-to-Digital conversion:

;This code block configures the ADC

;for polling, Vdd and Vss references, Frc

;clock and AN0 input.

;

1. Configure Port:

• Disable pin output driver (Refer to the TRIS

register)

;Conversion start & polling for completion

; are included.

;

• Configure pin as analog (Refer to the ANSEL

register)

BANKSEL

MOVLW

ADCON1

;

B’11110000’ ;2’s complement, Frc

;clock

2. Configure the ADC module:

• Select ADC conversion clock

• Configure voltage reference

• Select ADC input channel

• Turn on ADC module

MOVWF

MOVLW

MOVWF

ADCON1

;Vdd and Vss Vref

B’00001111’ ;set negative input

ADCON2

;to negative

;reference

BANKSEL

BSF

BANKSEL

BSF

BANKSEL

MOVLW

MOVWF

CALL

TRISA

TRISA,0

ANSEL

ANSEL,0

ADCON0

;

;Set RA0 to input

;

;Set RA0 to analog

;

3. Configure ADC interrupt (optional):

• Clear ADC interrupt flag

• Enable ADC interrupt

• Enable peripheral interrupt

• Enable global interrupt⁽¹⁾

B’00000001’ ;Select channel AN0

ADCON0

SampleTime

;Turn ADC On

;Acquisiton delay

4. Wait the required acquisition time⁽²⁾

.

BSF

ADCON0,ADGO ;Start conversion

5. Start conversion by setting the GO/DONE bit.

BTFSC

GOTO

BANKSEL

MOVF

ADCON0,ADGO ;Is conversion done?

$-1

;No, test again

;

6. Wait for ADC conversion to complete by one of

the following:

ADRESH

ADRESH,W

RESULTHI

;Read upper 2 bits

;store in GPR space

• Polling the GO/DONE bit

MOVWF

• Waiting for the ADC interrupt (interrupts

enabled)

7. Read ADC Result.

8. Clear the ADC interrupt flag (required if interrupt

is enabled).

Note 1: The global interrupt can be disabled if the

user is attempting to wake-up from Sleep

and resume in-line code execution.

2: Refer

to

Section 17.4

“ADC

Acquisition Requirements”.

DS40001579E-page 146

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

17.3 Register Definitions: ADC Control

REGISTER 17-1: ADCON0: ADC CONTROL REGISTER 0

R/W-0/0

ADRMD

R/W-0/0

ADON

CHS<4:0>

GO/DONE

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7

ADRMD: ADC Result Mode bit

1= ADRESL and ADRESH provide data formatted for a 10-bit result

0= ADRESL and ADRESH provide data formatted for a 12-bit result

See Figure 17-3 for details

bit 6-2

CHS<4:0>: Positive Differential Input Channel Select bits

11111= FVR (Fixed Voltage Reference) Buffer 1 Output⁽³⁾

11110= DAC_output⁽²⁾

11101= Temperature Indicator⁽⁴⁾

11100= Reserved. No channel connected.

•

01110= Reserved. No channel connected.

01101= AN13

01100= AN12

01011= AN11

01010= AN10

01001= AN9

01000= AN8

00111= Reserved. No channel connected.

00110= Reserved. No channel connected.

00101= Reserved. No channel connected.

00100= AN4

00011= AN3

00010= AN2

00001= AN1

00000= AN0

bit 1

bit 0

GO/DONE: ADC Conversion Status bit

1= ADC conversion cycle in progress. Setting this bit starts an ADC conversion cycle.

This bit is automatically cleared by hardware when the ADC conversion has completed.

0= ADC conversion completed/not in progress

ADON: ADC Enable bit

1= ADC is enabled

0= ADC is disabled and consumes no operating current

Note 1: See Section 19.0 “Digital-to-Analog Converter (DAC) Module” for more information.

2: See Section 15.0 “Fixed Voltage Reference (FVR)” for more information.

3: See Section 16.0 “Temperature Indicator Module” for more information.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 147

PIC16(L)F1782/3

REGISTER 17-2: ADCON1: ADC CONTROL REGISTER 1

R/W-0/0

ADFM

R/W-0/0

U-0

—

R/W-0/0

ADCS<2:0>

ADNREF

ADPREF<1:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

ADFM: ADC Result Format Select bit (see Figure 17-3)

1= 2’s complement format.

0= Sign-magnitude result format.

bit 6-4

ADCS<2:0>: ADC Conversion Clock Select bits

111=FRC (clock supplied from a dedicated FRC oscillator)

110=FOSC/64

101=FOSC/16

100=FOSC/4

011=FRC (clock supplied from a dedicated FRC oscillator)

010=FOSC/32

001=FOSC/8

000=FOSC/2

bit 3

bit 2

Unimplemented: Read as ‘0’

ADNREF: ADC Negative Voltage Reference Configuration bit

1= VREF- is connected to external VREF- pin⁽¹⁾

0= VREF- is connected to VSS

bit 1-0

ADPREF<1:0>: ADC Positive Voltage Reference Configuration bits

11= VREF+ is connected internally to FVR Buffer 1

10= Reserved

01= VREF+ is connected to VREF+ pin

00= VREF+ is connected to VDD

Note 1: When selecting the FVR or VREF+ pin as the source of the positive reference, be aware that a minimum

voltage specification exists. See Section 30.0 “Electrical Specifications” for details.

DS40001579E-page 148

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 17-3: ADCON2: ADC CONTROL REGISTER 2

R/W-0/0 R/W-0/0 R/W-0/0 R/W-0/0 R/W-0/0

TRIGSEL<3:0>

R/W-0/0

bit 0

CHSN<3:0>

bit 7

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-4

TRIGSEL<3:0>: ADC Auto-conversion Trigger Source Selection bits

1111= Reserved. Auto-conversion Trigger disabled.

1110= Reserved. Auto-conversion Trigger disabled.

1101= Reserved. Auto-conversion Trigger disabled.

1100= Reserved. Auto-conversion Trigger disabled.

1011= Reserved. Auto-conversion Trigger disabled.

1010= Reserved. Auto-conversion Trigger disabled.

1001= PSMC2 Falling Edge Event

1000= PSMC2 Rising Edge Event

0111= PSMC2 Period Match Event

0110= PSMC1 Falling Edge Event

0101= PSMC1 Rising Edge Event

0100= PSMC1 Period Match Event

0011= Reserved. Auto-conversion Trigger disabled.

0010= CCP2, Auto-conversion Trigger

0001= CCP1, Auto-conversion Trigger

0000= Disabled

bit 3-0

CHSN<3:0>: Negative Differential Input Channel Select bits

When ADON = 0, all multiplexer inputs are disconnected.

1111= ADC Negative reference - selected by ADNREF

1110= Reserved. No channel connected.

1101= AN13

1100= AN12

1011= AN11

1010= AN10

1001= AN9

1000= AN8

0111= Reserved. No channel connected.

0110= Reserved. No channel connected.

0101= Reserved. No channel connected.

0100= AN4

0011= AN3

0010= AN2

0001= AN1

0000= AN0

 2011-2014 Microchip Technology Inc.

DS40001579E-page 149

PIC16(L)F1782/3

REGISTER 17-4: ADRESH: ADC RESULT REGISTER HIGH (ADRESH) ADFM = 0

R/W-x/u

bit 0

AD<11:4>

bit 7

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

AD<11:4>: ADC Result Register bits

Upper 8 bits of 12-bit conversion result

REGISTER 17-5: ADRESL: ADC RESULT REGISTER LOW (ADRESL) ADFM = 0

R/W-x/u

—

R/W-x/u

—

R/W-x/u

—

R/W-x/u

ADSIGN

AD<3:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-4

AD<3:0>: ADC Result Register bits

Lower 4 bits of 12-bit conversion result

bit 3-1

bit 0

Extended LSb bits: These are cleared to zero by DC conversion.

ADSIGN: ADC Result Sign bit

DS40001579E-page 150

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 17-6: ADRESH: ADC RESULT REGISTER HIGH (ADRESH) ADFM = 1

R/W-x/u R/W-x/u R/W-x/u R/W-x/u R/W-x/u R/W-x/u R/W-x/u

ADSIGN AD<11:8>

R/W-x/u

bit 0

bit 7

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-4

bit 3-0

ADSIGN: Extended AD Result Sign bit

AD<11:8>: ADC Result Register bits

Most Significant 4 bits of 12-bit conversion result

REGISTER 17-7: ADRESL: ADC RESULT REGISTER LOW (ADRESL) ADFM = 1

R/W-x/u

bit 0

AD<7:0>

bit 7

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

AD<7:0>: ADC Result Register bits

Least Significant 8 bits of 12-bit conversion result

 2011-2014 Microchip Technology Inc.

DS40001579E-page 151

PIC16(L)F1782/3

source impedance is decreased, the acquisition time

may be decreased. After the analog input channel is

selected (or changed), an ADC acquisition must be

done before the conversion can be started. To calculate

the minimum acquisition time, Equation 17-1 may be

used. This equation assumes that 1/2 LSb error is used

(4,096 steps for the ADC). The 1/2 LSb error is the

maximum error allowed for the ADC to meet its

specified resolution.

17.4 ADC Acquisition Requirements

For the ADC to meet its specified accuracy, the charge

holding capacitor (CHOLD) must be allowed to fully

charge to the input channel voltage level. The Analog

Input model is shown in Figure 17-4. The source

impedance (RS) and the internal sampling switch (RSS)

impedance directly affect the time required to charge

the capacitor CHOLD. The sampling switch (RSS)

impedance varies over the device voltage (VDD), refer

to Figure 17-4. The maximum recommended

impedance for analog sources is 10 k. As the

EQUATION 17-1: ACQUISITION TIME EXAMPLE

Temperature = 50°C and external impedance of 10k 5.0V VDD

Assumptions:

TACQ = Amplifier Settling Time + Hold Capacitor Charging Time + Temperature Coefficient

= TAMP + TC + TCOFF

= 2µs + TC + Temperature - 25°C0.05µs/°C

The value for TC can be approximated with the following equations:

1





;[1] VCHOLD charged to within 1/2 lsb

^VAPPLIED^{1 – -------------------------- = VCHOLD}



2^{n + 1} – 1

–TC

---------





RC

VAPPLIED 1 – e

= V^CHOLD







;[2] VCHOLD charge response to VAPPLIED

;combining [1] and [2]



–Tc

--------









RC

1







^{= VAPPLIED}^{1 – --------------------------}

2^{n + 1} – 1

VAPPLIED 1 – e





Note: Where n = number of bits of the ADC.

Solving for TC:

TC = –CHOLDRIC + RSS + RS ln(1/8191)

= –10pF1k + 7k + 10k ln(0.000122)

= 1.62µs

Therefore:

TACQ = 2µs + 1.62µs + 50°C- 25°C0.05µs/°C

= 4.87µs

Note 1: The reference voltage (VREF) has no effect on the equation, since it cancels itself out.

2: Maximum source impedance feeding the input pin should be considered so that the pin leakage does not

cause a voltage divider, thereby limiting the absolute accuracy.

DS40001579E-page 152

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 17-4:

ANALOG INPUT MODEL

VDD

Analog

Input

Sampling

Switch

VT  0.6V

SS

RIC  1k

Rss

Rs

(1)

CPIN

5 pF

VA

I LEAKAGE

CHOLD = 10 pF

VSS/VREF-

VT  0.6V

6V

5V

VDD 4V

3V

RSS

Legend:

CHOLD

CPIN

= Sample/Hold Capacitance

= Input Capacitance

2V

I LEAKAGE = Leakage current at the pin due to

various junctions

5 6 7 8 9 1011

Sampling Switch

RIC

RSS

SS

VT

= Interconnect Resistance

= Resistance of Sampling Switch

= Sampling Switch

(k)

= Threshold Voltage

Note 1: Refer to Section 30.0 “Electrical Specifications”.

FIGURE 17-5:

ADC TRANSFER FUNCTION

Full-Scale Range

FFFh

FFEh

FFDh

FFCh

FFBh

03h

02h

01h

00h

Analog Input Voltage (Positive input channel

relative to negative

0.5 LSB

1.5 LSB

input channel)

Zero-Scale

Transition

VREF-

Full-Scale

Transition

VREF+

 2011-2014 Microchip Technology Inc.

DS40001579E-page 153

PIC16(L)F1782/3

TABLE 17-3: SUMMARY OF REGISTERS ASSOCIATED WITH ADC

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

147

148

149

ADCON0

ADCON1

ADCON2

ADRESH

ADRMD

ADFM

CHS<4:0>

GO/DONE

ADON

ADCS<2:0>

—

ADNREF

ADPREF<1:0>

TRIGSEL<3:0>

CHSN<3:0>

A/D Result Register High

A/D Result Register Low

150, 151

115

ADRESL

ANSELA

ANSELB

INTCON

ANSA7

—

ANSA5

ANSB5

TMR0IE

ANSA4

ANSB4

INTE

ANSA3

ANSB3

IOCIE

ANSA2

ANSB2

TMR0IF

ANSA1

ANSB1

INTF

ANSA0

ANSB0

IOCIF

121

GIE

PEIE

79

TMR1GIE

TMR1GIF

TRISA7

TRISB7

FVREN

PIE1

ADIE

ADIF

RCIE

RCIF

TXIE

TXIF

SSP1IE

SSP1IF

TRISA3

TRISB3

CCP1IE

CCP1IF

TRISA2

TRISB2

TMR2IE

TMR2IF

TRISA1

TRISB1

TMR1IE

TMR1IF

TRISA0

TRISB0

80

PIR1

83

TRISA

TRISB

FVRCON

Legend:

TRISA6

TRISB6

FVRRDY

TRISA5

TRISB5

TSEN

TRISA4

TRISB4

TSRNG

114

120

CDAFVR<1:0>

ADFVR<1:0>

137

x= unknown, u= unchanged, —= unimplemented read as ‘0’, q= value depends on condition. Shaded cells are not

used for the ADC module.

DS40001579E-page 154

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

18.0 OPERATIONAL AMPLIFIER

(OPA) MODULES

The Operational Amplifier (OPA) is

a standard

three-terminal device requiring external feedback to

operate. The OPA module has the following features:

• External connections to I/O ports

• Low leakage inputs

• Factory Calibrated Input Offset Voltage

FIGURE 18-1:

OPAx MODULE BLOCK DIAGRAM

OPAXEN

OPAXSP⁽¹⁾

0x

OPAxIN+

10

11

DAC_output

FVR Buffer 2

OPAXOUT

OPA

OPAxIN-

OPAxNCH<1:0>

Note 1: The OPAxSP bit must be set to ‘1’. Low Power mode is not supported.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 155

PIC16(L)F1782/3

18.1 Effects of Reset

18.3 OPAxCON Control Register

A device Reset forces all registers to their Reset state.

This disables the OPA module.

The OPAxCON register, shown in Register 18-1,

controls the OPA module.

The OPA module is enabled by setting the OPAxEN bit

of the OPAxCON register. When enabled, the OPA

forces the output driver of OPAxOUT pin into tri-state to

prevent contention between the driver and the OPA

output.

18.2 OPA Module Performance

Common AC and DC performance specifications for

the OPA module:

• Common Mode Voltage Range

• Leakage Current

Note:

When the OPA module is enabled, the

OPAxOUT pin is driven by the op amp out-

put, not by the PORT digital driver. Refer

to the Electrical specifications for the op

amp output drive capability.

• Input Offset Voltage

• Open Loop Gain

• Gain Bandwidth Product

Common mode voltage range is the specified voltage

range for the OPA+ and OPA- inputs, for which the OPA

module will perform to within its specifications. The

OPA module is designed to operate with input voltages

between VSS and VDD. Behavior for Common mode

voltages greater than VDD, or below VSS, are not guar-

anteed.

Leakage current is a measure of the small source or

sink currents on the OPA+ and OPA- inputs. To mini-

mize the effect of leakage currents, the effective imped-

ances connected to the OPA+ and OPA- inputs should

be kept as small as possible and equal.

Input offset voltage is a measure of the voltage differ-

ence between the OPA+ and OPA- inputs in a closed

loop circuit with the OPA in its linear region. The offset

voltage will appear as a DC offset in the output equal to

the input offset voltage, multiplied by the gain of the cir-

cuit. The input offset voltage is also affected by the

Common mode voltage. The OPA is factory calibrated

to minimize the input offset voltage of the module.

Open loop gain is the ratio of the output voltage to the

differential input voltage, (OPA+) - (OPA-). The gain is

greatest at DC and falls off with frequency.

Gain Bandwidth Product or GBWP is the frequency

at which the open loop gain falls off to 0 dB.

DS40001579E-page 156

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

18.4 Register Definitions: Op Amp Control

REGISTER 18-1: OPAxCON: OPERATIONAL AMPLIFIERS (OPAx) CONTROL REGISTERS

R/W-0/0

OPAxEN

R/W-0/0

OPAxSP

U-0

—

U-0

—

U-0

—

U-0

—

R/W-0/0

OPAxCH<1:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

u = Bit is unchanged

‘1’ = Bit is set

-n/n = Value at POR and BOR/Value at all other Resets

q = Value depends on condition

bit 7

bit 6

OPAxEN: Op Amp Enable bit

1 = Op amp is enabled

0 = Op amp is disabled and consumes no active power

OPAxSP: Op Amp Speed/Power Select bit

1 = Comparator operates in high GBWP mode

0 = Reserved. Do not use.

bit 5-2

bit 1-0

Unimplemented: Read as ‘0’

OPAxCH<1:0>: Non-inverting Channel Selection bits

11 = Non-inverting input connects to FVR Buffer 2 output

10 = Non-inverting input connects to DAC_output

0x = Non-inverting input connects to OPAxIN+ pin

TABLE 18-1: SUMMARY OF REGISTERS ASSOCIATED WITH OP AMPS

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

ANSELA

ANSELB

DACCON0

DACCON1

OPA1CON

OPA2CON

TRISA

ANSA7

—

ANSA5

ANSB5

ANSA4

ANSB4

ANSA3

ANSB3

ANSA2

ANSB2

ANSA1

ANSB1

—

ANSA0

ANSB0

115

121

161

157

114

120

125

DACEN

DACOE1

DACOE2

DACPSS<1:0>

DACNSS

DACR<7:0>

OPA1EN

OPA2EN

TRISA7

TRISB7

TRISC7

OPA1SP

OPA2SP

TRISA6

TRISB6

TRISC6

—

OPA1PCH<1:0>

OPA2PCH<1:0>

—

TRISA5

TRISB5

TRISC5

TRISA4

TRISB4

TRISC4

TRISA3

TRISB3

TRISC3

TRISA2

TRISB2

TRISC2

TRISA1

TRISA0

TRISB0

TRISC0

TRISB

TRISB1

TRISC1

TRISC

Legend:

— = unimplemented location, read as ‘0’. Shaded cells are not used by op amps.

Note 1: PIC16(L)F1783 only

 2011-2014 Microchip Technology Inc.

DS40001579E-page 157

PIC16(L)F1782/3

The Digital-to-Analog Converter (DAC) is enabled by

setting the DACEN bit of the DACCON0 register.

19.0 DIGITAL-TO-ANALOG

CONVERTER (DAC) MODULE

The Digital-to-Analog Converter supplies a variable

voltage reference, ratiometric with the input source,

with 256 selectable output levels.

19.1 Output Voltage Selection

The DAC has 256 voltage level ranges. The 256 levels

are set with the DACR<7:0> bits of the DACCON1

register.

The input of the DAC can be connected to:

• External VREF pins

The DAC output voltage is determined by Equation 19-1:

• VDD supply voltage

• FVR (Fixed Voltage Reference)

The output of the DAC can be configured to supply a

reference voltage to the following:

• Comparator positive input

• Op amp positive input

• ADC input channel

• DACOUT1 pin

• DACOUT2 pin

EQUATION 19-1: DAC OUTPUT VOLTAGE

IF DACxEN = 1

DACxR7:0





VOUT = VSOURCE+ – VSOURCE-  -------------------------------- + VSOURCE-

2⁸





VSOURCE+ = VDD, VREF, or FVR BUFFER 2

VSOURCE- = VSS

19.2 Ratiometric Output Level

The DAC output value is derived using a resistor ladder

with each end of the ladder tied to a positive and

negative voltage reference input source. If the voltage

of either input source fluctuates, a similar fluctuation will

result in the DAC output value.

The value of the individual resistors within the ladder

can be found in Section 30.0 “Electrical

Specifications”.

19.3 DAC Voltage Reference Output

The DAC voltage can be output to the DACOUT1 and

DACOUT2 pins by setting the respective DACOE1 and

DACOE2 pins of the DACCON0 register. Selecting the

DAC reference voltage for output on either DACOUTX

pin automatically overrides the digital output buffer and

digital input threshold detector functions of that pin.

Reading the DACOUTX pin when it has been

configured for DAC reference voltage output will

always return a ‘0’.

Due to the limited current drive capability, a buffer must

be used on the DAC voltage reference output for

external connections to either DACOUTx pin.

Figure 19-2 shows an example buffering technique.

DS40001579E-page 158

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 19-1:

DIGITAL-TO-ANALOG CONVERTER BLOCK DIAGRAM

Digital-to-Analog Converter (DAC)

FVR BUFFER2

VSOURCE+

VDD

DACxR<7:0>

8

VREF+

R

DACxPSS<1:0>

DACxEN

2

R

256

Steps

DAC_Output

(To Comparator and

ADC Modules)

R

DACXOUT1

DACXOE1

DACxNSS

DACXOUT2

DACXOE2

VREF-

VSS

VSOURCE-

FIGURE 19-2:

VOLTAGE REFERENCE OUTPUT BUFFER EXAMPLE

PIC^®MCU

DAC

Module

R

+

–

Buffered DAC Output

DACXOUTX

Voltage

Reference

Output

Impedance

 2011-2014 Microchip Technology Inc.

DS40001579E-page 159

PIC16(L)F1782/3

19.4 Operation During Sleep

When the device wakes up from Sleep through an

interrupt or a Watchdog Timer time-out, the contents of

the DACCON0 register are not affected. To minimize

current consumption in Sleep mode, the voltage

reference should be disabled.

19.5 Effects of a Reset

A device Reset affects the following:

• DAC is disabled.

• DAC output voltage is removed from the

DACOUT pin.

• The DACR<7:0> range select bits are cleared.

DS40001579E-page 160

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

19.6 Register Definitions: DAC Control

REGISTER 19-1: DACCON0: VOLTAGE REFERENCE CONTROL REGISTER 0

R/W-0/0

DACEN

U-0

—

R/W-0/0

U-0

—

R/W-0/0

DACOE1

DACOE2

DACPSS<1:0>

DACNSS

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

DACEN: DAC Enable bit

1= DAC is enabled

0= DAC is disabled

bit 6

bit 5

Unimplemented: Read as ‘0’

DACOE1: DAC Voltage Output 1 Enable bit

1= DAC voltage level is also an output on the DACOUT1 pin

0= DAC voltage level is disconnected from the DACOUT1 pin

bit 4

DACOE2: DAC Voltage Output 2 Enable bit

1= DAC voltage level is also an output on the DACOUT2 pin

0= DAC voltage level is disconnected from the DACOUT2 pin

bit 3-2

DACPSS<1:0>: DAC Positive Source Select bits

11= Reserved, do not use

10= FVR Buffer2 output

01= VREF+ pin

00= VDD

bit 1

bit 0

Unimplemented: Read as ‘0’

DACNSS: DAC Negative Source Select bits

1= VREF- pin

0= VSS

REGISTER 19-2: DACCON1: VOLTAGE REFERENCE CONTROL REGISTER 1

R/W-0/0

DACR<7:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

u = Bit is unchanged

‘1’ = Bit is set

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-0

DACR<7:0>: DAC Voltage Output Select bits

 2011-2014 Microchip Technology Inc.

DS40001579E-page 161

PIC16(L)F1782/3

TABLE 19-1: SUMMARY OF REGISTERS ASSOCIATED WITH THE DAC MODULE

Register

on page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

FVRCON

DACCON0

DACCON1

Legend:

FVREN

FVRRDY

TSEN

TSRNG

CDAFVR<1:0>

DACPSS<1:0>

DACR<7:0>

— = Unimplemented location, read as ‘0’. Shaded cells are not used with the DAC module.

ADFVR<1:0>

137

161

DACEN

—

DACOE1 DACOE2

—

DACNSS

DS40001579E-page 162

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 20-1:

SINGLE COMPARATOR

20.0 COMPARATOR MODULE

Comparators are used to interface analog circuits to a

digital circuit by comparing two analog voltages and

providing a digital indication of their relative magnitudes.

Comparators are very useful mixed signal building

blocks because they provide analog functionality

independent of program execution. The analog

comparator module includes the following features:

VIN+

VIN-

+

Output

–

VIN-

VIN+

• Independent comparator control

• Programmable input selection

• Comparator output is available internally/externally

• Programmable output polarity

• Interrupt-on-change

Output

• Wake-up from Sleep

• Programmable Speed/Power optimization

• PWM shutdown

Note:

The black areas of the output of the

comparator represents the uncertainty

due to input offsets and response time.

• Programmable and fixed voltage reference

20.1

Comparator Overview

A single comparator is shown in Figure 20-1 along with

the relationship between the analog input levels and

the digital output. When the analog voltage at VIN+ is

less than the analog voltage at VIN-, the output of the

comparator is a digital low level. When the analog

voltage at VIN+ is greater than the analog voltage at

VIN-, the output of the comparator is a digital high level.

The comparators available for this device are located in

Table 20-1.

TABLE 20-1: COMPARATORAVAILABILITY

PER DEVICE

Device

C1

C2

C3

PIC16(L)F1782

PIC16(L)F1783

●

 2011-2014 Microchip Technology Inc.

DS40001579E-page 163

PIC16(L)F1782/3

FIGURE 20-2:

COMPARATOR MODULE SIMPLIFIED BLOCK DIAGRAM

CxNCH<2:0>

CxON⁽¹⁾

3

CxINTP

Interrupt

det

CXIN0-

CXIN1-

CXIN2-

CXIN3-

0

Set CxIF

1

CxINTN

Interrupt

det

2

MUX

(2)

3

CXPOL

CxVN

CxVP

Reserved

4

5

-

0

1

to CMXCON0 (CXOUT)

and CM2CON1 (MCXOUT)

D

Q

Cx

ZLF

+

6

Q1

EN

7

CxHYS

AGND

CxZLF

CxSP

async_CxOUT

CXSYNC

CXOE

TRIS bit

CXOUT

0

1

D

Q

0

CXIN0+

From Timer1

tmr1_clk

sync_CxOUT

To Timer1

and PSMC Logic

1

CXIN1+

MUX

(2)

2

3

Reserved

4

5

6

7

Reserved

DAC_Output

FVR Buffer2

AGND

CxON

CXPCH<2:0>

3

Note 1: When CxON = 0, the comparator will produce a ‘0’ at the output.

2: When CxON = 0, all multiplexer inputs are disconnected.

DS40001579E-page 164

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

20.2.3

COMPARATOR OUTPUT POLARITY

20.2 Comparator Control

Inverting the output of the comparator is functionally

equivalent to swapping the comparator inputs. The

polarity of the comparator output can be inverted by

setting the CxPOL bit of the CMxCON0 register.

Clearing the CxPOL bit results in a non-inverted output.

Each comparator has two control registers: CMxCON0

and CMxCON1.

The CMxCON0 register (see Register 20-1) contains

Control and Status bits for the following:

• Enable

Table 20-2 shows the output state versus input

conditions, including polarity control.

• Output selection

• Output polarity

TABLE 20-2: COMPARATOR OUTPUT

STATE VS. INPUT

• Speed/Power selection

• Hysteresis enable

• Output synchronization

CONDITIONS

Input Condition

CxPOL

CxOUT

The CMxCON1 register (see Register 20-2) contains

Control bits for the following:

CxVN > CxVP

CxVN < CxVP

CxVN > CxVP

CxVN < CxVP

0

1

0

1

0

• Interrupt enable

• Interrupt edge polarity

• Positive input channel selection

• Negative input channel selection

20.2.4

COMPARATOR SPEED/POWER

SELECTION

20.2.1

COMPARATOR ENABLE

The trade-off between speed or power can be

optimized during program execution with the CxSP

control bit. The default state for this bit is ‘1’ which

selects the normal speed mode. Device power

consumption can be optimized at the cost of slower

comparator propagation delay by clearing the CxSP bit

to ‘0’.

Setting the CxON bit of the CMxCON0 register enables

the comparator for operation. Clearing the CxON bit

disables the comparator resulting in minimum current

consumption.

20.2.2

COMPARATOR OUTPUT

SELECTION

The output of the comparator can be monitored by

reading either the CxOUT bit of the CMxCON0 register

or the MCxOUT bit of the CMOUT register. In order to

make the output available for an external connection,

the following conditions must be true:

• CxOE bit of the CMxCON0 register must be set

• Corresponding TRIS bit must be cleared

• CxON bit of the CMxCON0 register must be set

Note 1: The CxOE bit of the CMxCON0 register

overrides the PORT data latch. Setting

the CxON bit of the CMxCON0 register

has no impact on the port override.

2: The internal output of the comparator is

latched with each instruction cycle.

Unless otherwise specified, external

outputs are not latched.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 165

PIC16(L)F1782/3

20.3 Comparator Hysteresis

20.5 Comparator Interrupt

A selectable amount of separation voltage can be

added to the input pins of each comparator to provide a

hysteresis function to the overall operation. Hysteresis

is enabled by setting the CxHYS bit of the CMxCON0

register.

An interrupt can be generated upon a change in the

output value of the comparator for each comparator, a

rising edge detector and a falling edge detector are

present.

When either edge detector is triggered and its associ-

ated enable bit is set (CxINTP and/or CxINTN bits of

the CMxCON1 register), the Corresponding Interrupt

Flag bit (CxIF bit of the PIR2 register) will be set.

See Section 30.0 “Electrical Specifications” for

more information.

20.4 Timer1 Gate Operation

To enable the interrupt, you must set the following bits:

• CxON, CxPOL and CxSP bits of the CMxCON0

register

The output resulting from a comparator operation can

be used as a source for gate control of Timer1. See

Section 22.6 “Timer1 Gate” for more information.

This feature is useful for timing the duration or interval

of an analog event.

• CxIE bit of the PIE2 register

• CxINTP bit of the CMxCON1 register (for a rising

edge detection)

It is recommended that the comparator output be

synchronized to Timer1. This ensures that Timer1 does

not increment while a change in the comparator is

occurring.

• CxINTN bit of the CMxCON1 register (for a falling

edge detection)

• PEIE and GIE bits of the INTCON register

The associated interrupt flag bit, CxIF bit of the PIR2

register, must be cleared in software. If another edge is

detected while this flag is being cleared, the flag will still

be set at the end of the sequence.

20.4.1

COMPARATOR OUTPUT

SYNCHRONIZATION

The output from a comparator can be synchronized

with Timer1 by setting the CxSYNC bit of the CMx-

CON0 register.

Note:

Although a comparator is disabled, an

interrupt can be generated by changing

the output polarity with the CxPOL bit of

the CMxCON0 register, or by switching

the comparator on or off with the CxON bit

of the CMxCON0 register.

Once enabled, the comparator output is latched on the

falling edge of the Timer1 source clock. If a prescaler is

used with Timer1, the comparator output is latched after

the prescaling function. To prevent a race condition, the

comparator output is latched on the falling edge of the

Timer1 clock source and Timer1 increments on the

rising edge of its clock source. See the Comparator

Block Diagram (Figure 20-2) and the Timer1 Block

Diagram (Figure 22-1) for more information.

20.6 Comparator Positive Input

Selection

Configuring the CxPCH<2:0> bits of the CMxCON1

register directs an internal voltage reference or an

analog pin to the non-inverting input of the comparator:

• CxIN+ analog pin

• DAC output

• FVR (Fixed Voltage Reference)

• VSS (Ground)

See Section 15.0 “Fixed Voltage Reference (FVR)”

for more information on the Fixed Voltage Reference

module.

See Section 19.0 “Digital-to-Analog Converter

(DAC) Module” for more information on the DAC input

signal.

Any time the comparator is disabled (CxON = 0), all

comparator inputs are disabled.

DS40001579E-page 166

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Therefore, both of these times must be considered when

determining the total response time to a comparator

input change. See the Comparator and Voltage

Reference Specifications in Section 30.0 “Electrical

Specifications” for more details.

20.7 Comparator Negative Input

Selection

The CxNCH<2:0> bits of the CMxCON0 register direct

an analog input pin or analog ground to the inverting

input of the comparator:

20.9 Zero Latency Filter

• CxIN- pin

• Analog Ground

In high-speed operation, and under proper circuit

conditions, it is possible for the comparator output to

oscillate. This oscillation can have adverse effects on

the hardware and software relying on this signal.

Therefore, a digital filter has been added to the

comparator output to suppress the comparator output

oscillation. Once the comparator output changes, the

output is prevented from reversing the change for a

nominal time of 20 ns. This allows the comparator

output to stabilize without affecting other dependent

devices. Refer to Figure 20-3.

Some inverting input selections share a pin with the

operational amplifier output function. Enabling both

functions at the same time will direct the operational

amplifier output to the comparator inverting input.

Note:

To use CxINy+ and CxINy- pins as analog

input, the appropriate bits must be set in

the ANSEL register and the correspond-

ing TRIS bits must also be set to disable

the output drivers.

20.8 Comparator Response Time

The comparator output is indeterminate for a period of

time after the change of an input source or the selection

of a new reference voltage. This period is referred to as

the response time. The response time of the comparator

differs from the settling time of the voltage reference.

FIGURE 20-3:

COMPARATOR ZERO LATENCY FILTER OPERATION

CxOUT From Comparator

CxOUT From ZLF

TZLF

Output waiting for TZLF to expire before an output change is allowed

TZLF has expired so output change of ZLF is immediate based on

comparator output change

 2011-2014 Microchip Technology Inc.

DS40001579E-page 167

PIC16(L)F1782/3

20.10.1 ALTERNATE PIN LOCATIONS

20.10 Analog Input Connection

Considerations

This module incorporates I/O pins that can be moved to

other locations with the use of the alternate pin function

register APFCON. To determine which pins can be

moved and what their default locations are upon a

Reset, see Section 13.1 “Alternate Pin Function” for

more information.

A simplified circuit for an analog input is shown in

Figure 20-4. Since the analog input pins share their

connection with a digital input, they have reverse

biased ESD protection diodes to VDD and VSS. The

analog input, therefore, must be between VSS and VDD.

If the input voltage deviates from this range by more

than 0.6V in either direction, one of the diodes is

forward biased and a latch-up may occur.

A maximum source impedance of 10 k is recommended

for the analog sources. Also, any external component

connected to an analog input pin, such as a capacitor or

a Zener diode, should have very little leakage current to

minimize inaccuracies introduced.

Note 1: When reading a PORT register, all pins

configured as analog inputs will read as a

‘0’. Pins configured as digital inputs will

convert as an analog input, according to

the input specification.

2: Analog levels on any pin defined as a

digital input, may cause the input buffer to

consume more current than is specified.

FIGURE 20-4:

ANALOG INPUT MODEL

VDD

Analog

Input

VT  0.6V

RIC

Rs < 10K

To Comparator

(1)

ILEAKAGE

CPIN

5 pF

VA

VT  0.6V

Vss

Legend: CPIN

= Input Capacitance

ILEAKAGE = Leakage Current at the pin due to various junctions

RIC

RS

VA

= Interconnect Resistance

= Source Impedance

= Analog Voltage

VT

= Threshold Voltage

Note 1: See Section 30.0 “Electrical Specifications”

DS40001579E-page 168

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

20.11 Register Definitions: Comparator Control

REGISTER 20-1: CMxCON0: COMPARATOR Cx CONTROL REGISTER 0

R/W-0/0

CxON

R-0/0

R/W-0/0

CxOE

R/W-0/0

CxPOL

R/W-0/0

CxZLF

R/W-1/1

CxSP

R/W-0/0

CxHYS

R/W-0/0

CxSYNC

CxOUT

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

bit 6

CxON: Comparator Enable bit

1= Comparator is enabled

0= Comparator is disabled and consumes no active power

CxOUT: Comparator Output bit

If CxPOL = 1 (inverted polarity):

1= CxVP < CxVN

0= CxVP > CxVN

If CxPOL = 0 (non-inverted polarity):

1= CxVP > CxVN

0= CxVP < CxVN

bit 5

CxOE: Comparator Output Enable bit

1= CxOUT is present on the CxOUT pin. Requires that the associated TRIS bit be cleared to actually

drive the pin. Not affected by CxON.

0= CxOUT is internal only

bit 4

bit 3

bit 2

bit 1

bit 0

CxPOL: Comparator Output Polarity Select bit

1= Comparator output is inverted

0= Comparator output is not inverted

CxZLF: Comparator Zero Latency Filter Enable bit

1= Comparator output is filtered

0= Comparator output is unfiltered

CxSP: Comparator Speed/Power Select bit

1= Comparator operates in normal power, higher speed mode

0= Comparator operates in low-power, low-speed mode

CxHYS: Comparator Hysteresis Enable bit

1= Comparator hysteresis enabled

0= Comparator hysteresis disabled

CxSYNC: Comparator Output Synchronous Mode bit

1= Comparator output to Timer1 and I/O pin is synchronous to changes on Timer1 clock source.

Output updated on the falling edge of Timer1 clock source.

0= Comparator output to Timer1 and I/O pin is asynchronous.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 169

PIC16(L)F1782/3

REGISTER 20-2: CMxCON1: COMPARATOR Cx CONTROL REGISTER 1

R/W-0/0

CxINTP

R/W-0/0

CxINTN

R/W-0/0

bit 0

CxPCH<2:0>

CxNCH<2:0>

bit 7

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7

CxINTP: Comparator Interrupt on Positive Going Edge Enable bits

1= The CxIF interrupt flag will be set upon a positive going edge of the CxOUT bit

0= No interrupt flag will be set on a positive going edge of the CxOUT bit

bit 6

CxINTN: Comparator Interrupt on Negative Going Edge Enable bits

1= The CxIF interrupt flag will be set upon a negative going edge of the CxOUT bit

0= No interrupt flag will be set on a negative going edge of the CxOUT bit

bit 5-3

CxPCH<2:0>: Comparator Positive Input Channel Select bits

111= CxVP connects to AGND

110= CxVP connects to FVR Buffer 2

101= CxVP connects to DAC_output

100= Reserved, input floating

011= Reserved, input floating

010= Reserved, input floating

001= CxVP connects to CxIN1+ pin

000= CxVP connects to CxIN0+ pin

bit 2-0

CxNCH<2:0>: Comparator Negative Input Channel Select bits

111= CxVN connects to AGND

110= CxVN unconnected, input floating

101= Reserved, input floating

100= Reserved, input floating

011= CxVN connects to CxIN3- pin

010= CxVN connects to CxIN2- pin

001= CxVN connects to CxIN1- pin

000= CxVN connects to CxIN0- pin

DS40001579E-page 170

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 20-3: CMOUT: COMPARATOR OUTPUT REGISTER

U-0

—

U-0

—

U-0

—

U-0

—

U-0

—

R-0/0

MC3OUT

MC2OUT

MC1OUT

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7-3

bit 2

Unimplemented: Read as ‘0’

MC3OUT: Mirror Copy of C3OUT bit

MC2OUT: Mirror Copy of C2OUT bit

MC1OUT: Mirror Copy of C1OUT bit

bit 1

bit 0

TABLE 20-3: SUMMARY OF REGISTERS ASSOCIATED WITH COMPARATOR MODULE

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

ANSELA

ANSELB

CM1CON0

CM2CON0

CM1CON1

CM2CON1

CM3CON0

CM3CON1

CMOUT

FVRCON

DACCON0

DACCON1

INTCON

PIE2

ANSA7

—

ANSA5

ANSB5

C1OE

ANSA4

ANSB4

ANSA3

ANSB3

C1ZLF

C2ZLF

ANSA2

ANSB2

C1SP

ANSA1

ANSB1

ANSA0

ANSB0

115

121

169

170

169

170

171

137

161

79

C1ON

C2ON

C1NTP

C2NTP

C3ON

C3INTP

—

C1OUT

C2OUT

C1INTN

C2INTN

C3OUT

C3INTN

—

C1POL

C1HYS

C1SYNC

C2SYNC

C2OE

C2POL

C2SP

C2HYS

C1PCH<2:0>

C2PCH<2:0>

C3POL

C1NCH<2:0>

C2NCH<2:0>

C3HYS

C3OE

C3ZLF

—

C3SP

C3SYNC

C3PCH<2:0>

—

C3NCH<2:0>

—

MC3OUT MC2OUT MC1OUT

ADFVR<1:0>

FVREN

DACEN

FVRRDY

—

TSEN

TSRNG

CDAFVR<1:0>

DACPSS<1:0>

DACOE1

DACOE2

—

DACNSS

DACR<7:0>

GIE

PEIE

C2IE

TMR0IE

C1IE

INTE

EEIE

IOCIE

BCL1IE

BCL1IF

TRISA3

TRISB3

TRISC3

TMR0IF

—

INTF

C3IE

IOCIF

OSEIE

OSFIF

CCP2IE

CCP2IF

TRISA0

TRISB0

TRISC0

81

PIR2

C2IF

C1IF

EEIF

—

C3IF

84

TRISA

TRISA7

TRISB7

TRISC7

TRISA6

TRISB6

TRISC6

TRISA5

TRISB5

TRISC5

TRISA4

TRISB4

TRISC4

TRISA2

TRISB2

TRISC2

TRISA1

TRISB1

TRISC1

115

121

125

TRISB

TRISC

Note 1: — = unimplemented location, read as ‘0’. Shaded cells are unused by the comparator module.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 171

PIC16(L)F1782/3

21.1.2

8-BIT COUNTER MODE

21.0 TIMER0 MODULE

In 8-Bit Counter mode, the Timer0 module will increment

on every rising or falling edge of the T0CKI pin.

The Timer0 module is an 8-bit timer/counter with the

following features:

8-Bit Counter mode using the T0CKI pin is selected by

setting the TMR0CS bit in the OPTION_REG register to

‘1’.

• 8-bit timer/counter register (TMR0)

• 8-bit prescaler (independent of Watchdog Timer)

• Programmable internal or external clock source

• Programmable external clock edge selection

• Interrupt on overflow

The rising or falling transition of the incrementing edge

for either input source is determined by the TMR0SE bit

in the OPTION_REG register.

• TMR0 can be used to gate Timer1

Figure 21-1 is a block diagram of the Timer0 module.

21.1 Timer0 Operation

The Timer0 module can be used as either an 8-bit timer

or an 8-bit counter.

21.1.1

8-BIT TIMER MODE

The Timer0 module will increment every instruction

cycle, if used without a prescaler. 8-bit Timer mode is

selected by clearing the TMR0CS bit of the

OPTION_REG register.

When TMR0 is written, the increment is inhibited for

two instruction cycles immediately following the write.

Note:

The value written to the TMR0 register

can be adjusted, in order to account for

the two instruction cycle delay when

TMR0 is written.

FIGURE 21-1:

BLOCK DIAGRAM OF THE TIMER0

FOSC/4

Data Bus

0

1

8

T0CKI

1

Sync

TMR0

2 TCY

0

Set Flag bit TMR0IF

TMR0SE

TMR0CS

8-bit

Prescaler

on Overflow

PSA

Overflow to Timer1

8

PS<2:0>

DS40001579E-page 172

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

21.1.3

SOFTWARE PROGRAMMABLE

PRESCALER

A software programmable prescaler is available for

exclusive use with Timer0. The prescaler is enabled by

clearing the PSA bit of the OPTION_REG register.

Note:

The Watchdog Timer (WDT) uses its own

independent prescaler.

There are eight prescaler options for the Timer0

module ranging from 1:2 to 1:256. The prescale values

are selectable via the PS<2:0> bits of the

OPTION_REG register. In order to have a 1:1 prescaler

value for the Timer0 module, the prescaler must be

disabled by setting the PSA bit of the OPTION_REG

register.

The prescaler is not readable or writable. All instructions

writing to the TMR0 register will clear the prescaler.

21.1.4

TIMER0 INTERRUPT

Timer0 will generate an interrupt when the TMR0

register overflows from FFh to 00h. The TMR0IF

interrupt flag bit of the INTCON register is set every

time the TMR0 register overflows, regardless of

whether or not the Timer0 interrupt is enabled. The

TMR0IF bit can only be cleared in software. The Timer0

interrupt enable is the TMR0IE bit of the INTCON

register.

Note:

The Timer0 interrupt cannot wake the

processor from Sleep since the timer is

frozen during Sleep.

21.1.5

8-BIT COUNTER MODE

SYNCHRONIZATION

When in 8-Bit Counter mode, the incrementing edge on

the T0CKI pin must be synchronized to the instruction

clock. Synchronization can be accomplished by

sampling the prescaler output on the Q2 and Q4 cycles

of the instruction clock. The high and low periods of the

external clocking source must meet the timing

requirements as shown in Section 30.0 “Electrical

Specifications”.

21.1.6

OPERATION DURING SLEEP

Timer0 cannot operate while the processor is in Sleep

mode. The contents of the TMR0 register will remain

unchanged while the processor is in Sleep mode.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 173

PIC16(L)F1782/3

21.2 Register Definitions: Option Register

REGISTER 21-1: OPTION_REG: OPTION REGISTER

R/W-1/1

WPUEN

R/W-1/1

INTEDG

R/W-1/1

PSA

R/W-1/1

PS<2:0>

R/W-1/1

bit 0

TMR0CS

TMR0SE

bit 7

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

bit 6

bit 5

bit 4

bit 3

bit 2-0

WPUEN: Weak Pull-Up Enable bit

1= All weak pull-ups are disabled (except MCLR, if it is enabled)

0= Weak pull-ups are enabled by individual WPUx latch values

INTEDG: Interrupt Edge Select bit

1= Interrupt on rising edge of INT pin

0= Interrupt on falling edge of INT pin

TMR0CS: Timer0 Clock Source Select bit

1= Transition on T0CKI pin

0= Internal instruction cycle clock (FOSC/4)

TMR0SE: Timer0 Source Edge Select bit

1= Increment on high-to-low transition on T0CKI pin

0= Increment on low-to-high transition on T0CKI pin

PSA: Prescaler Assignment bit

1= Prescaler is not assigned to the Timer0 module

0= Prescaler is assigned to the Timer0 module

PS<2:0>: Prescaler Rate Select bits

Bit Value

Timer0 Rate

000

001

010

011

100

101

110

111

1 : 2

1 : 4

1 : 8

1 : 16

1 : 32

1 : 64

1 : 128

1 : 256

TABLE 21-1: SUMMARY OF REGISTERS ASSOCIATED WITH TIMER0

Register

on Page

Name

INTCON

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

GIE

PEIE

TMR0IE

INTE

IOCIE

PSA

TMR0IF

INTF

IOCIF

79

174

172*

114

OPTION_REG WPUEN INTEDG TMR0CS TMR0SE

PS<2:0>

TMR0

TRISA

Timer0 Module Register

TRISA7 TRISA6 TRISA5 TRISA4

TRISA3

TRISA2

TRISA1 TRISA0

Legend: — = Unimplemented location, read as ‘0’. Shaded cells are not used by the Timer0 module.

Page provides register information.

*

DS40001579E-page 174

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

• Gate Toggle mode

22.0 TIMER1 MODULE WITH GATE

CONTROL

• Gate Single-pulse mode

• Gate Value Status

The Timer1 module is a 16-bit timer/counter with the

following features:

• Gate Event Interrupt

Figure 22-1 is a block diagram of the Timer1 module.

• 16-bit timer/counter register pair (TMR1H:TMR1L)

• Programmable internal or external clock source

• 2-bit prescaler

• Dedicated 32 kHz oscillator circuit

• Optionally synchronized comparator out

• Multiple Timer1 gate (count enable) sources

• Interrupt on overflow

• Wake-up on overflow (external clock,

Asynchronous mode only)

• Time base for the Capture/Compare function

• Auto-conversion Trigger (with CCP)

• Selectable Gate Source Polarity

FIGURE 22-1:

TIMER1 BLOCK DIAGRAM

T1GSS<1:0>

T1G

T1GSPM

00

From Timer0

Overflow

0

01

10

11

t1g_in

Data Bus

T1GVAL

0

1

D

Q

Single-Pulse

Acq. Control

RD

sync_C1OUT

sync_C2OUT

1

T1GCON

Q1 EN

D

Q

Interrupt

Set

T1GGO/DONE

CK

TMR1ON

T1GTM

TMR1GIF

det

R

T1GPOL

TMR1GE

Set flag bit

TMR1IF on

Overflow

TMR1ON

To Comparator Module

TMR1⁽²⁾

EN

D

Synchronized

clock input

0

To ADC Auto-Conversion

T1CLK

TMR1H

TMR1L

Q

1

TMR1CS<1:0>

Reserved

T1SYNC

T1OSO

T1OSI

OUT

11

10

Synchronize⁽³⁾

det

T1OSC

EN

Prescaler

1, 2, 4, 8

1

0

2

T1CKPS<1:0>

FOSC

Internal

Clock

01

00

FOSC/2

Internal

Clock

T1OSCEN

T1CKI

Sleep input

FOSC/4

Internal

Clock

(1)

To Clock Switching Modules

Note 1: ST Buffer is high speed type when using T1CKI.

2: Timer1 register increments on rising edge.

3: Synchronize does not operate while in Sleep.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 175

PIC16(L)F1782/3

22.1 Timer1 Operation

22.2 Clock Source Selection

The Timer1 module is a 16-bit incrementing counter

which is accessed through the TMR1H:TMR1L register

pair. Writes to TMR1H or TMR1L directly update the

counter.

The TMR1CS<1:0> and T1OSCEN bits of the T1CON

register are used to select the clock source for Timer1.

Table 22-2 displays the clock source selections.

22.2.1

INTERNAL CLOCK SOURCE

When used with an internal clock source, the module is

a timer and increments on every instruction cycle.

When used with an external clock source, the module

can be used as either a timer or counter and

increments on every selected edge of the external

source.

When the internal clock source is selected, the

TMR1H:TMR1L register pair will increment on multiples

of FOSC as determined by the Timer1 prescaler.

When the FOSC internal clock source is selected, the

Timer1 register value will increment by four counts every

instruction clock cycle. Due to this condition, a 2 LSB

error in resolution will occur when reading the Timer1

value. To utilize the full resolution of Timer1, an

asynchronous input signal must be used to gate the

Timer1 clock input.

Timer1 is enabled by configuring the TMR1ON and

TMR1GE bits in the T1CON and T1GCON registers,

respectively. Table 22-1 displays the Timer1 enable

selections.

The following asynchronous sources may be used:

TABLE 22-1: TIMER1 ENABLE

SELECTIONS

• Asynchronous event on the T1G pin to Timer1

gate

Timer1

Operation

TMR1ON

TMR1GE

• C1 or C2 comparator input to Timer1 gate

0

1

0

1

0

1

Off

22.2.2

EXTERNAL CLOCK SOURCE

When the external clock source is selected, the Timer1

module may work as a timer or a counter.

Always On

Count Enabled

When enabled to count, Timer1 is incremented on the

rising edge of the external clock input T1CKI, which can

be synchronized to the microcontroller system clock or

can run asynchronously.

When used as a timer with a clock oscillator, an

external 32.768 kHz crystal can be used in conjunction

with the dedicated internal oscillator circuit.

Note:

In Counter mode, a falling edge must be

registered by the counter prior to the first

incrementing rising edge after any one or

more of the following conditions:

• Timer1 enabled after POR

• Write to TMR1H or TMR1L

• Timer1 is disabled

• Timer1 is disabled (TMR1ON = 0)

when T1CKI is high then Timer1 is

enabled (TMR1ON=1) when T1CKI is

low.

TABLE 22-2: CLOCK SOURCE SELECTIONS

TMR1CS<1:0>

T1OSCEN

Clock Source

11

10

01

00

x

1

0

x

Reserved

Timer1 Oscillator

External Clocking on T1CKI Pin

System Clock (FOSC)

Instruction Clock (FOSC/4)

DS40001579E-page 176

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

22.5.1

READING AND WRITING TIMER1 IN

ASYNCHRONOUS COUNTER

MODE

22.3 Timer1 Prescaler

Timer1 has four prescaler options allowing 1, 2, 4 or 8

divisions of the clock input. The T1CKPS bits of the

T1CON register control the prescale counter. The

prescale counter is not directly readable or writable;

however, the prescaler counter is cleared upon a write to

TMR1H or TMR1L.

Reading TMR1H or TMR1L while the timer is running

from an external asynchronous clock will ensure a valid

read (taken care of in hardware). However, the user

should keep in mind that reading the 16-bit timer in two

8-bit values itself, poses certain problems, since the

timer may overflow between the reads.

22.4 Timer1 Oscillator

For writes, it is recommended that the user simply stop

the timer and write the desired values. A write

contention may occur by writing to the timer registers,

while the register is incrementing. This may produce an

unpredictable value in the TMR1H:TMR1L register pair.

A dedicated low-power 32.768 kHz oscillator circuit is

built-in between pins T1OSI (input) and T1OSO

(amplifier output). This internal circuit is to be used in

conjunction with an external 32.768 kHz crystal.

The oscillator circuit is enabled by setting the T1OS-

CEN bit of the T1CON register. The oscillator will con-

tinue to run during Sleep.

22.6 Timer1 Gate

Timer1 can be configured to count freely or the count

can be enabled and disabled using Timer1 gate

circuitry. This is also referred to as Timer1 Gate Enable.

Note:

The oscillator requires a start-up and

stabilization time before use. Thus,

T1OSCEN should be set and a suitable

delay observed prior to using Timer1. A

suitable delay similar to the OST delay

can be implemented in software by

clearing the TMR1IF bit then presetting

the TMR1H:TMR1L register pair to

FC00h. The TMR1IF flag will be set when

1024 clock cycles have elapsed, thereby

indicating that the oscillator is running and

reasonably stable.

Timer1 gate can also be driven by multiple selectable

sources.

22.6.1

TIMER1 GATE ENABLE

The Timer1 Gate Enable mode is enabled by setting

the TMR1GE bit of the T1GCON register. The polarity

of the Timer1 Gate Enable mode is configured using

the T1GPOL bit of the T1GCON register.

When Timer1 Gate Enable mode is enabled, Timer1

will increment on the rising edge of the Timer1 clock

source. When Timer1 Gate Enable mode is disabled,

no incrementing will occur and Timer1 will hold the

current count. See Figure 22-3 for timing details.

22.5 Timer1 Operation in

Asynchronous Counter Mode

If the control bit T1SYNC of the T1CON register is set,

the external clock input is not synchronized. The timer

increments asynchronously to the internal phase

clocks. If the external clock source is selected then the

timer will continue to run during Sleep and can

generate an interrupt on overflow, which will wake-up

the processor. However, special precautions in

software are needed to read/write the timer (see

Section 22.5.1 “Reading and Writing Timer1 in

Asynchronous Counter Mode”).

TABLE 22-3: TIMER1 GATE ENABLE

SELECTIONS

T1CLK T1GPOL

T1G

Timer1 Operation



0

1

0

1

0

1

Counts

Holds Count

Counts

Note:

When switching from synchronous to

asynchronous operation, it is possible to

skip an increment. When switching from

asynchronous to synchronous operation,

it is possible to produce an additional

increment.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 177

PIC16(L)F1782/3

Timer1 Gate Toggle mode is enabled by setting the

T1GTM bit of the T1GCON register. When the T1GTM

bit is cleared, the flip-flop is cleared and held clear. This

is necessary in order to control which edge is

measured.

22.6.2

TIMER1 GATE SOURCE

SELECTION

Timer1 gate source selections are shown in Table 22-4.

Source selection is controlled by the T1GSS bits of the

T1GCON register. The polarity for each available source

is also selectable. Polarity selection is controlled by the

T1GPOL bit of the T1GCON register.

Note:

Enabling Toggle mode at the same time

as changing the gate polarity may result in

indeterminate operation.

TABLE 22-4: TIMER1 GATE SOURCES

22.6.4

TIMER1 GATE SINGLE-PULSE

MODE

T1GSS

Timer1 Gate Source

Timer1 Gate Pin

00

01

When Timer1 Gate Single-Pulse mode is enabled, it is

possible to capture a single-pulse gate event. Timer1

Gate Single-Pulse mode is enabled by first setting the

T1GSPM bit in the T1GCON register. Next, the

T1GGO/DONE bit in the T1GCON register must be set.

The Timer1 will be fully enabled on the next

incrementing edge. On the next trailing edge of the

pulse, the T1GGO/DONE bit will automatically be

cleared. No other gate events will be allowed to

increment Timer1 until the T1GGO/DONE bit is once

again set in software. See Figure 22-5 for timing details.

Overflow of Timer0

(TMR0 increments from FFh to 00h)

10

11

Comparator 1 Output sync_C1OUT

(optionally Timer1 synchronized output)

Comparator 2 Output sync_C2OUT

(optionally Timer1 synchronized output)

22.6.2.1

T1G Pin Gate Operation

The T1G pin is one source for Timer1 gate control. It

can be used to supply an external source to the Timer1

gate circuitry.

If the Single-Pulse Gate mode is disabled by clearing the

T1GSPM bit in the T1GCON register, the T1GGO/DONE

bit should also be cleared.

22.6.2.2

Timer0 Overflow Gate Operation

Enabling the Toggle mode and the Single-Pulse mode

simultaneously will permit both sections to work

together. This allows the cycle times on the Timer1 gate

source to be measured. See Figure 22-6 for timing

details.

When Timer0 increments from FFh to 00h,

low-to-high pulse will automatically be generated and

internally supplied to the Timer1 gate circuitry.

a

22.6.2.3

Comparator C1 Gate Operation

The output resulting from a Comparator 1 operation can

be selected as a source for Timer1 gate control. The

22.6.5

TIMER1 GATE VALUE

When Timer1 Gate Value Status is utilized, it is possible

to read the most current level of the gate control value.

The value is accessible by reading the T1GVAL bit in

the T1GCON register. The T1GVAL bit is valid even

when the Timer1 gate is not enabled (TMR1GE bit is

cleared).

Comparator

1

output (sync_C1OUT) can be

synchronized to the Timer1 clock or left asynchronous.

For more information see Section 20.4.1 “Comparator

Output Synchronization”.

22.6.2.4

Comparator C2 Gate Operation

The output resulting from a Comparator 2 operation

can be selected as a source for Timer1 gate control.

The Comparator 2 output (sync_C2OUT) can be

synchronized to the Timer1 clock or left asynchronous.

For more information see Section 20.4.1 “Comparator

Output Synchronization”.

22.6.6

TIMER1 GATE EVENT INTERRUPT

When Timer1 Gate Event Interrupt is enabled, it is

possible to generate an interrupt upon the completion

of a gate event. When the falling edge of T1GVAL

occurs, the TMR1GIF flag bit in the PIR1 register will be

set. If the TMR1GIE bit in the PIE1 register is set, then

an interrupt will be recognized.

22.6.3

TIMER1 GATE TOGGLE MODE

The TMR1GIF flag bit operates even when the Timer1

gate is not enabled (TMR1GE bit is cleared).

When Timer1 Gate Toggle mode is enabled, it is

possible to measure the full-cycle length of a Timer1

gate signal, as opposed to the duration of a single level

pulse.

The Timer1 gate source is routed through a flip-flop that

changes state on every incrementing edge of the

signal. See Figure 22-4 for timing details.

DS40001579E-page 178

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

22.7 Timer1 Interrupt

22.9 CCP Capture/Compare Time Base

The Timer1 register pair (TMR1H:TMR1L) increments

to FFFFh and rolls over to 0000h. When Timer1 rolls

over, the Timer1 interrupt flag bit of the PIR1 register is

set. To enable the interrupt on rollover, you must set

these bits:

The CCP modules use the TMR1H:TMR1L register

pair as the time base when operating in Capture or

Compare mode.

In Capture mode, the value in the TMR1H:TMR1L

register pair is copied into the CCPR1H:CCPR1L

register pair on a configured event.

• TMR1ON bit of the T1CON register

• TMR1IE bit of the PIE1 register

• PEIE bit of the INTCON register

• GIE bit of the INTCON register

In Compare mode, an event is triggered when the value

CCPR1H:CCPR1L register pair matches the value in

the TMR1H:TMR1L register pair. This event can be a

Auto-conversion Trigger.

The interrupt is cleared by clearing the TMR1IF bit in

the Interrupt Service Routine.

For

more

information,

see

Section 25.0

“Capture/Compare/PWM Modules”.

Note:

The TMR1H:TMR1L register pair and the

TMR1IF bit should be cleared before

enabling interrupts.

22.10 CCP Auto-Conversion Trigger

When any of the CCP’s are configured to trigger a

auto-conversion, the trigger will clear the

TMR1H:TMR1L register pair. This auto-conversion

does not cause a Timer1 interrupt. The CCP module

may still be configured to generate a CCP interrupt.

22.8 Timer1 Operation During Sleep

Timer1 can only operate during Sleep when setup in

Asynchronous Counter mode. In this mode, an external

crystal or clock source can be used to increment the

counter. To set up the timer to wake the device:

In this mode of operation, the CCPR1H:CCPR1L

register pair becomes the period register for Timer1.

• TMR1ON bit of the T1CON register must be set

• TMR1IE bit of the PIE1 register must be set

• PEIE bit of the INTCON register must be set

• T1SYNC bit of the T1CON register must be set

Timer1 should be synchronized and FOSC/4 should be

selected as the clock source in order to utilize the

Auto-conversion Trigger. Asynchronous operation of

Timer1 can cause a Auto-conversion Trigger to be

missed.

• TMR1CS bits of the T1CON register must be

configured

In the event that a write to TMR1H or TMR1L coincides

with a Auto-conversion Trigger from the CCP, the write

will take precedence.

• T1OSCEN bit of the T1CON register must be

configured

For

more

information,

see

Section 25.2.4

The device will wake-up on an overflow and execute

the next instructions. If the GIE bit of the INTCON

register is set, the device will call the Interrupt Service

Routine.

“Auto-Conversion Trigger”.

Timer1 oscillator will continue to operate in Sleep

regardless of the T1SYNC bit setting.

FIGURE 22-2:

TIMER1 INCREMENTING EDGE

T1CKI = 1

when TMR1

Enabled

T1CKI = 0

when TMR1

Enabled

Note 1: Arrows indicate counter increments.

2: In Counter mode, a falling edge must be registered by the counter prior to the first incrementing rising edge of the clock.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 179

PIC16(L)F1782/3

FIGURE 22-3:

TIMER1 GATE ENABLE MODE

TMR1GE

T1GPOL

t1g_in

T1CKI

T1GVAL

Timer1

N

N + 1

N + 2

N + 3

N + 4

FIGURE 22-4:

TIMER1 GATE TOGGLE MODE

TMR1GE

T1GPOL

T1GTM

t1g_in

T1CKI

T1GVAL

Timer1

N

N + 1 N + 2 N + 3 N + 4

N + 5 N + 6 N + 7 N + 8

DS40001579E-page 180

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 22-5:

TIMER1 GATE SINGLE-PULSE MODE

TMR1GE

T1GPOL

T1GSPM

Cleared by hardware on

falling edge of T1GVAL

T1GGO/

DONE

Set by software

Counting enabled on

rising edge of T1G

t1g_in

T1CKI

T1GVAL

Timer1

N

N + 1

N + 2

Cleared by

software

Set by hardware on

falling edge of T1GVAL

Cleared by software

TMR1GIF

 2011-2014 Microchip Technology Inc.

DS40001579E-page 181

PIC16(L)F1782/3

FIGURE 22-6:

TMR1GE

T1GPOL

TIMER1 GATE SINGLE-PULSE AND TOGGLE COMBINED MODE

T1GSPM

T1GTM

Cleared by hardware on

falling edge of T1GVAL

T1GGO/

DONE

Set by software

Counting enabled on

rising edge of T1G

t1g_in

T1CKI

T1GVAL

Timer1

N + 4

N + 2 N + 3

N

N + 1

Set by hardware on

falling edge of T1GVAL

Cleared by

software

Cleared by software

TMR1GIF

DS40001579E-page 182

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

22.11 Register Definitions: Timer1 Control

T

REGISTER 22-1: T1CON: TIMER1 CONTROL REGISTER

R/W-0/u

T1SYNC

U-0

—

R/W-0/u

TMR1CS<1:0>

T1CKPS<1:0>

T1OSCEN

TMR1ON

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-6

TMR1CS<1:0>: Timer1 Clock Source Select bits

11= Reserved, do not use.

10= Timer1 clock source is pin or oscillator:

If T1OSCEN = 0:

External clock from T1CKI pin (on the rising edge)

If T1OSCEN = 1:

Crystal oscillator on T1OSI/T1OSO pins

01= Timer1 clock source is system clock (FOSC)

00= Timer1 clock source is instruction clock (FOSC/4)

bit 5-4

T1CKPS<1:0>: Timer1 Input Clock Prescale Select bits

11= 1:8 Prescale value

10= 1:4 Prescale value

01= 1:2 Prescale value

00= 1:1 Prescale value

bit 3

bit 2

T1OSCEN: LP Oscillator Enable Control bit

1= Dedicated Timer1 oscillator circuit enabled

0= Dedicated Timer1 oscillator circuit disabled

T1SYNC: Timer1 Synchronization Control bit

1= Do not synchronize asynchronous clock input

0= Synchronize asynchronous clock input with system clock (FOSC)

bit 1

bit 0

Unimplemented: Read as ‘0’

TMR1ON: Timer1 On bit

1= Enables Timer1

0= Stops Timer1 and clears Timer1 gate flip-flop

 2011-2014 Microchip Technology Inc.

DS40001579E-page 183

PIC16(L)F1782/3

REGISTER 22-2: T1GCON: TIMER1 GATE CONTROL REGISTER

R/W-0/u

T1GPOL

R/W-0/u

T1GTM

R/W-0/u

R/W/HC-0/u

R-x/x

R/W-0/u

TMR1GE

T1GSPM

T1GGO/

DONE

T1GVAL

T1GSS<1:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

-n/n = Value at POR and BOR/Value at all other Resets

HC = Bit is cleared by hardware

bit 7

TMR1GE: Timer1 Gate Enable bit

If TMR1ON = 0:

This bit is ignored

If TMR1ON = 1:

1= Timer1 counting is controlled by the Timer1 gate function

0= Timer1 counts regardless of Timer1 gate function

bit 6

bit 5

T1GPOL: Timer1 Gate Polarity bit

1= Timer1 gate is active-high (Timer1 counts when gate is high)

0= Timer1 gate is active-low (Timer1 counts when gate is low)

T1GTM: Timer1 Gate Toggle Mode bit

1= Timer1 Gate Toggle mode is enabled

0= Timer1 Gate Toggle mode is disabled and toggle flip-flop is cleared

Timer1 gate flip-flop toggles on every rising edge.

bit 4

T1GSPM: Timer1 Gate Single-Pulse Mode bit

1= Timer1 Gate Single-Pulse mode is enabled and is controlling Timer1 gate

0= Timer1 Gate Single-Pulse mode is disabled

bit 3

T1GGO/DONE: Timer1 Gate Single-Pulse Acquisition Status bit

1= Timer1 gate single-pulse acquisition is ready, waiting for an edge

0= Timer1 gate single-pulse acquisition has completed or has not been started

bit 2

T1GVAL: Timer1 Gate Current State bit

Indicates the current state of the Timer1 gate that could be provided to TMR1H:TMR1L.

Unaffected by Timer1 Gate Enable (TMR1GE).

bit 1-0

T1GSS<1:0>: Timer1 Gate Source Select bits

11= Comparator 2 optionally synchronized output (sync_C2OUT)

10= Comparator 1 optionally synchronized output (sync_C1OUT)

01= Timer0 overflow output

00= Timer1 gate pin

DS40001579E-page 184

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 22-5: SUMMARY OF REGISTERS ASSOCIATED WITH TIMER1

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

ANSELB

CCP1CON

CCP2CON

INTCON

PIE1

—

ANSB5

ANSB4

ANSB3

ANSB2

ANSB1

ANSB0

121

255

79

DC1B<1:0>

DC2B<1:0>

CCP1M<3:0>

CCP2M<3:0>

—

GIE

PEIE

ADIE

ADIF

TMR0IE

INTE

TXIE

TXIF

IOCIE

SSP1IE

SSP1IF

TMR0IF

INTF

IOCIF

TMR1IE

TMR1IF

TMR1GIE

TMR1GIF

RCIE

RCIF

CCP1IE

CCP1IF

TMR2IE

TMR2IF

80

PIR1

83

TMR1H

TMR1L

TRISB

Holding Register for the Most Significant Byte of the 16-bit TMR1 Register

Holding Register for the Least Significant Byte of the 16-bit TMR1 Register

175*

120

125

183

184

TRISB7

TRISC7

TRISB6

TRISC6

TRISB5

TRISC5

TRISB4

TRISC4

TRISB3

TRISC3

TRISB2

TRISC2

T1SYNC

T1GVAL

TRISB1

TRISC1

—

TRISB0

TRISC0

TMR1ON

TRISC

T1CON

T1GCON

TMR1CS<1:0>

T1CKPS<1:0>

T1OSCEN

TMR1GE

T1GPOL

T1GTM

T1GSPM

T1GGO/

DONE

T1GSS<1:0>

Legend:

— = unimplemented location, read as ‘0’. Shaded cells are not used by the Timer1 module.

*

Page provides register information.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 185

PIC16(L)F1782/3

23.0 TIMER2 MODULE

The Timer2 module incorporates the following features:

• 8-bit Timer and Period registers (TMR2 and PR2,

respectively)

• Readable and writable (both registers)

• Software programmable prescaler (1:1, 1:4, 1:16,

and 1:64)

• Software programmable postscaler (1:1 to 1:16)

• Interrupt on TMR2 match with PR2

• Optional use as the shift clock for the MSSP

module

See Figure 23-1 for a block diagram of Timer2.

FIGURE 23-1:

TIMER2 BLOCK DIAGRAM

Prescaler

TMR2

Reset

EQ

TMR2 Output

FOSC/4

1:1, 1:4, 1:16, 1:64

Postscaler

1:1 to 1:16

2

Comparator

Sets Flag bit TMR2IF

T2CKPS<1:0>

PR2

4

T2OUTPS<3:0>

DS40001579E-page 186

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

23.1 Timer2 Operation

23.3 Timer2 Output

The clock input to the Timer2 modules is the system

instruction clock (FOSC/4).

The unscaled output of TMR2 is available primarily to

the CCP modules, where it is used as a time base for

operations in PWM mode.

A 4-bit counter/prescaler on the clock input allows direct

input, divide-by-4 and divide-by-16 prescale options.

These options are selected by the prescaler control bits,

T2CKPS<1:0> of the T2CON register. The value of

TMR2 is compared to that of the Period register, PR2, on

each clock cycle. When the two values match, the

comparator generates a match signal as the timer

output. This signal also resets the value of TMR2 to 00h

on the next cycle and drives the output

Timer2 can be optionally used as the shift clock source

for the MSSP module operating in SPI mode.

Additional information is provided in Section 26.0

“Master Synchronous Serial Port (MSSP) Module”

23.4 Timer2 Operation During Sleep

The Timer2 timers cannot be operated while the

processor is in Sleep mode. The contents of the TMR2

and PR2 registers will remain unchanged while the

processor is in Sleep mode.

counter/postscaler

(see

Section 23.2

“Timer2

Interrupt”).

The TMR2 and PR2 registers are both directly readable

and writable. The TMR2 register is cleared on any

device Reset, whereas the PR2 register initializes to

FFh. Both the prescaler and postscaler counters are

cleared on the following events:

• a write to the TMR2 register

• a write to the T2CON register

• Power-on Reset (POR)

• Brown-out Reset (BOR)

• MCLR Reset

• Watchdog Timer (WDT) Reset

• Stack Overflow Reset

• Stack Underflow Reset

• RESETInstruction

Note:

TMR2 is not cleared when T2CON is

written.

23.2 Timer2 Interrupt

Timer2 can also generate an optional device interrupt.

The Timer2 output signal (TMR2-to-PR2 match)

provides the input for the 4-bit counter/postscaler. This

counter generates the TMR2 match interrupt flag which

is latched in TMR2IF of the PIR1 register. The interrupt

is enabled by setting the TMR2 Match Interrupt Enable

bit, TMR2IE, of the PIE1 register.

A range of 16 postscale options (from 1:1 through 1:16

inclusive) can be selected with the postscaler control

bits, T2OUTPS<3:0>, of the T2CON register.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 187

PIC16(L)F1782/3

23.5 Register Definitions: Timer2 Control

REGISTER 23-1: T2CON: TIMER2 CONTROL REGISTER

U-0

—

R/W-0/0

T2OUTPS<3:0>

TMR2ON

T2CKPS<1:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

Unimplemented: Read as ‘0’

bit 6-3

T2OUTPS<3:0>: Timer2 Output Postscaler Select bits

1111= 1:16 Postscaler

1110= 1:15 Postscaler

1101= 1:14 Postscaler

1100= 1:13 Postscaler

1011= 1:12 Postscaler

1010= 1:11 Postscaler

1001= 1:10 Postscaler

1000= 1:9 Postscaler

0111= 1:8 Postscaler

0110= 1:7 Postscaler

0101= 1:6 Postscaler

0100= 1:5 Postscaler

0011= 1:4 Postscaler

0010= 1:3 Postscaler

0001= 1:2 Postscaler

0000= 1:1 Postscaler

bit 2

TMR2ON: Timer2 On bit

1= Timer2 is on

0= Timer2 is off

bit 1-0

T2CKPS<1:0>: Timer2 Clock Prescale Select bits

11= Prescaler is 64

10= Prescaler is 16

01= Prescaler is 4

00= Prescaler is 1

DS40001579E-page 188

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 23-1: SUMMARY OF REGISTERS ASSOCIATED WITH TIMER2

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

CCP2CON

INTCON

PIE1

—

DC2B<1:0>

CCP2M<3:0>

255

79

GIE

PEIE

TMR0IE

INTE

IOCIE

TMR0IF

INTF

IOCIF

TMR1GIE

TMR1GIF

ADIE

ADIF

RCIE

RCIF

TXIE

TXIF

SSP1IE

SSP1IF

CCP1IE TMR2IE

TMR1IE

TMR1IF

80

PIR1

CCP1IF

TMR2IF

83

PR2

Timer2 Module Period Register

T2OUTPS<3:0>

Holding Register for the 8-bit TMR2 Register

186*

188

186*

T2CON

TMR2

—

TMR2ON

T2CKPS<1:0>

Legend: — = unimplemented location, read as ‘0’. Shaded cells are not used for Timer2 module.

Page provides register information.

*

 2011-2014 Microchip Technology Inc.

DS40001579E-page 189

PIC16(L)F1782/3

Modes of operation include:

24.0 PROGRAMMABLE SWITCH

MODE CONTROL (PSMC)

• Single-phase

• Complementary Single-phase

• Push-Pull

The Programmable Switch Mode Controller (PSMC) is

a high-performance Pulse Width Modulator (PWM) that

can be configured to operate in one of several modes

to support single or multiple phase applications.

• Push-Pull 4-Bridge

• Complementary Push-Pull 4-Bridge

• Pulse Skipping

A simplified block diagram indicating the relationship

between inputs, outputs, and controls is shown in

Figure 24-1.

• Variable Frequency Fixed Duty Cycle

• Complementary Variable Frequency Fixed Duty

Cycle

This section begins with the fundamental aspects of the

PSMC operation. A more detailed description of opera-

tion for each mode is located later in Section 24.3

“Modes of Operation”

• ECCP Compatible modes

- Full-Bridge

- Full-Bridge Reverse

• 3-Phase 6-Step PWM

DS40001579E-page 190

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

The basic waveform generated from these events is

shown in Figure 24-2.

24.1 Fundamental Operation

PSMC operation is based on the sequence of three

events:

• Period Event – Determines the frequency of the

active signal.

• Rising Edge Event – Determines start of the

active pulse. This is also referred to as the phase.

• Falling Edge Event – Determines the end of the

active pulse. This is also referred to as the duty

cycle.

FIGURE 24-2:

BASIC PWM WAVEFORM GENERATION

1

2

3

PWM Cycle Number

Inputs

Period Event

Rising Edge Event

Falling Edge Event

Outputs

PWM output

Each of the three types of events is triggered by a user

selectable combination of synchronous timed and

asynchronous external inputs.

PSMC operation can be quickly terminated without

software intervention by the auto-shutdown control.

Auto-shutdown can be triggered by any combination of

the following:

Asynchronous event inputs may come directly from an

input pin or through the comparators.

• PSMCxIN pin

• sync_C1OUT

• sync_C2OUT

• sync_C3OUT

Synchronous timed events are determined from the

PSMCxTMR counter, which is derived from internal

clock sources. See Section 24.2.5 “PSMC Time Base

Clock Sources” for more detail.

The active pulse stream can be further modulated by

one of several internal or external sources:

• Register control bit

• Comparator output

• CCP output

• Input pin

User selectable deadtime can be inserted in the drive

outputs to prevent shoot through of configurations with

two devices connected in series between the supply

rails.

Applications requiring very small frequency granularity

control when the PWM frequency is large can do so

with the fractional frequency control available in the

variable frequency fixed Duty Cycle modes.

DS40001579E-page 192

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

prevent the PSMC output from chattering in the

presence of spurious event inputs. A rising edge event

is also suppressed when it occurs after a falling edge

event in the same period.

24.1.1

PERIOD EVENT

The period event determines the frequency of the

active pulse. Period event sources include any

combination of the following:

The rising edge event also triggers the start of two other

timers when needed: falling edge blanking and

dead-band period. For more detail refer to

Section 24.2.8 “Input Blanking” and Section 24.4

“Dead-Band Control”.

• PSMCxTMR counter match

• PSMC input pin

• sync_C1OUT

• sync_C2OUT

• sync_C3OUT

•

When the rising edge event is delayed from the period

start, the amount of delay subtracts from the total amount

of time available for the drive duty cycle. For example, if

the rising edge event is delayed by 10% of the period

time, the maximum duty cycle for that period is 90%. A

100% duty cycle is still possible in this example, but duty

cycles from 90% to 100% are not possible.

Period event sources are selected with the PSMC

Period Source (PSMCxPRS) register (Register 24-13).

Section 24.2.1.2 “16-bit Period Register” contains

details on configuring the PSMCxTMR counter match

for synchronous period events.

24.1.3

FALLING EDGE EVENT

All period events cause the PSMCxTMR counter to

reset on the counting clock edge immediately following

the period event. The PSMCxTMR counter resumes

counting from zero on the counting clock edge after the

period event Reset.

The falling edge event determines the end of the active

drive period. The falling edge event is also referred to

as the duty cycle because varying the falling edge

event, while keeping the rising edge event and period

events fixed, varies the active drive duty cycle.

During a period, the rising event and falling event are

each permitted to occur only once. Subsequent rising

or falling events that may occur within the period are

suppressed, thereby preventing output chatter from

spurious inputs.

Depending on the PSMC mode, one or more of the

PSMC outputs will change in immediate response to

the falling edge event. Falling edge event sources

include any combination of the following:

• Synchronous:

- PSMCxTMR time base counter match

• Asynchronous:

- PSMC input pin

- sync_C1OUT

24.1.2

RISING EDGE EVENT

The rising edge event determines the start of the active

drive period. The rising edge event is also referred to

as the phase because two synchronized PSMC periph-

erals may have different rising edge events relative to

the period start, thereby creating a phase relationship

between the two PSMC peripheral outputs.

- sync_C2OUT

- sync_C3OUT

Depending on the PSMC mode, one or more of the

PSMC outputs will change in immediate response to

the rising edge event. Rising edge event sources

include any combination of the following:

-

Falling edge event sources are selected with PSMC Duty

Cycle Source (PSMCxDCS) register (Register 24-12).

For configuring the PSMCxTMR time base counter

match for synchronous falling edge events, see

Section 24.2.1.4 “16-bit Duty Cycle Register”.

• Synchronous:

- PSMCxTMR time base counter match

• Asynchronous:

- PSMC input pin

- sync_C1OUT

The first falling edge event in a cycle period is the only

one permitted to cause action. All subsequent falling

edge events in the same period are suppressed to

prevent the PSMC output from chattering in the

presence of spurious event inputs.

- sync_C2OUT

- sync_C3OUT

-

A falling edge event suppresses any subsequent rising

edges that may occur in the same period. In other words,

if an asynchronous falling event input should come late

and occur early in the period, following that for which it

was intended, the rising edge in that period will be sup-

pressed. This will have a similar effect as pulse skipping.

Rising edge event sources are selected with the PSMC

Phase Source (PSMCxPHS) register (Register 24-11).

For configuring the PSMCxTMR time base counter

match for synchronous rising edge events, see

Section 24.2.1.3 “16-bit Phase Register”.

The falling edge event also triggers the start of two

other timers: rising edge blanking and dead-band

period. For more detail refer to Section 24.2.8 “Input

Blanking” and Section 24.4 “Dead-Band Control”.

The first rising edge event in a cycle period is the only

one permitted to cause action. All subsequent rising

edge events in the same period are suppressed to

 2011-2014 Microchip Technology Inc.

DS40001579E-page 193

PIC16(L)F1782/3

24.2.1.2

16-bit Period Register

24.2 Event Sources

The PSMCxPR Period register is used to determine a

synchronous period event referenced to the 16-bit

PSMCxTMR digital counter. A match between the

PSMCxTMR and PSMCxPR register values will

generate a period event.

There are two main sources for the period, rising edge

and falling edge events:

• Synchronous input

- Time base

• Asynchronous Inputs

- Digital Inputs

The match will generate a period match interrupt,

thereby setting the PxTPRIF bit of the PSMC Time Base

Interrupt Control (PSMCxINT) register (Register 24-32).

- Analog inputs

The 16-bit period value is accessible to software as

two 8-bit registers:

24.2.1

TIME BASE

The Time Base section consists of several smaller

pieces.

• PSMC Period Count Low Byte (PSMCxPRL)

register (Register 24-23)

• 16-bit time base counter

• PSMC Period Count High Byte (PSMCxPRH)

register (Register 24-24)

• 16-bit Period register

• 16-bit Phase register (rising edge event)

• 16-bit Duty Cycle register (falling edge event)

• Clock control

The 16-bit period value is double-buffered before it is

presented to the 16-bit time base for comparison. The

buffered registers are updated on the first period event

Reset after the PSMCxLD bit of the PSMCxCON

register is set.

• Interrupt Generator

An example of a fully synchronous PWM waveform

generated with the time base is shown in Figure 24-2.

The synchronous PWM period time can be determined

from Equation 24-1.

The PSMCxLD bit of the PSMCxCON register is

provided to synchronize changes to the event Count

registers. Changes are withheld from taking action until

the first period event Reset after the PSMCxLD bit is

set. For example, to change the PWM frequency, while

maintaining the same effective duty cycle, the Period

and Duty Cycle registers need to be changed. The

changes to all four registers take effect simultaneously

on the period event Reset after the PSMCxLD bit is set.

EQUATION 24-1: PWM PERIOD

PSMCxPR[15:0] + 1

Period = -------------------------------------------------

F_{psmc_clk}

24.2.1.3

16-bit Phase Register

The PSMCxPH Phase register is used to determine a

synchronous rising edge event referenced to the 16-bit

PSMCxTMR digital counter. A match between the

PSMCxTMR and the PSMCxPH register values will

generate a rising edge event.

24.2.1.1

16-bit Counter (Time Base)

The PSMCxTMR is the counter used as a timing

reference for each synchronous PWM period. The

counter starts at 0000h and increments to FFFFh on

the rising edge of the psmc_clk signal.

The match will generate a phase match interrupt,

thereby setting the PxTPHIF bit of the PSMC Time

When the counter rolls over from FFFFh to 0000h

without a period event occurring, the overflow interrupt

will be generated, thereby setting the PxTOVIF bit of

the PSMC Time Base Interrupt Control (PSMCxINT)

register (Register 24-32).

Base

Interrupt

Control

(PSMCxINT)

register

(Register 24-32).

The 16-bit phase value is accessible to software as

two 8-bit registers:

The PSMCxTMR counter is reset on both synchronous

and asynchronous period events.

• PSMC Phase Count Low Byte (PSMCxPHL)

register (Register 24-32)

The PSMCxTMR is accessible to software as two 8-bit

registers:

• PSMC Phase Count High Byte (PSMCxPHH)

register (Register 24-32)

• PSMC Time Base Counter Low (PSMCxTMRL)

register (Register 24-17)

The 16-bit phase value is double-buffered before it is

presented to the 16-bit PSMCxTMR for comparison.

The buffered registers are updated on the first period

event Reset after the PSMCxLD bit of the PSMCxCON

register is set.

• PSMC PSMC Time Base Counter High

(PSMCxTMRH) register (Register 24-18)

PSMCxTMR is reset to the default POR value when the

PSMCxEN bit is cleared.

DS40001579E-page 194

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Each interrupt has an interrupt flag bit and an interrupt

enable bit. The interrupt flag bit is set anytime a given

event occurs, regardless of the status of the enable bit.

24.2.1.4

The PSMCxDC Duty Cycle register is used to

determine synchronous falling edge event

16-bit Duty Cycle Register

a

Time base interrupt enables and flags are located in

the PSMC Time Base Interrupt Control (PSMCxINT)

register (Register 24-32).

referenced to the 16-bit PSMCxTMR digital counter. A

match between the PSMCxTMR and PSMCxDC

register values will generate a falling edge event.

The match will generate a duty cycle match interrupt,

thereby setting the PxTDCIF bit of the PSMC Time Base

Interrupt Control (PSMCxINT) register (Register 24-32).

PSMC time base interrupts also require that the

PSMCxTIE bit in the PIE4 register and the PEIE and

GIE bits in the INTCON register be set in order to

generate an interrupt. The PSMCxTIF interrupt flag in

the PIR4 register will only be set by a time base

interrupt when one or more of the enable bits in the

PSMCxINT register is set.

The 16-bit duty cycle value is accessible to software

as two 8-bit registers:

• PSMC Duty Cycle Count Low Byte (PSMCxDCL)

register (Register 24-21)

The interrupt flag bits need to be cleared in software.

However, all PMSCx time base interrupt flags, except

PSMCxTIF, are cleared when the PSMCxEN bit is

cleared.

• PSMC Duty Cycle Count High Byte (PSMCxDCH)

register (Register 24-22)

The 16-bit duty cycle value is double-buffered before it

is presented to the 16-bit time base for comparison.

The buffered registers are updated on the first period

event Reset after the PSMCxLD bit of the PSMCxCON

register is set.

Interrupt bits that are set by software will generate an

interrupt provided that the corresponding interrupt is

enabled.

When the period, phase, and duty cycle are all deter-

mined from the time base, the effective PWM duty

cycle can be expressed as shown in Equation 24-2.

Note:

Interrupt flags in both the PIE4 and

PSMCxINT registers must be cleared to

clear the interrupt. The PSMCxINT flags

must be cleared first.

EQUATION 24-2: PWM DUTY CYCLE

24.2.5

PSMC TIME BASE CLOCK

SOURCES

PSMCxDC[15:0] – PSMCxPH[15:0]

DUTYCYCLE = ----------------------------------------------------------------------------------------

PSMCxPR[15:0] + 1

There are three clock sources available to the module:

• Internal 64 MHz clock

• Fosc system clock

• External clock input pin

24.2.2

0% DUTY CYCLE OPERATION

USING TIME BASE

The clock source is selected with the PxCSRC<1:0>

bits of the PSMCx Clock Control (PSMCxCLK) register

(Register 24-5).

To configure the PWM for 0% duty cycle set

PSMCxDC<15:0> = PSMCxPH<15:0>. This will trigger

a falling edge event simultaneous with the rising edge

event and prevent the PWM from being asserted.

When the Internal 64 MHz clock is selected as the

source, the HFINTOSC continues to operate and clock

the PSMC circuitry in Sleep. However, the system

clock to other peripherals and the CPU is suppressed.

24.2.3

100% DUTY CYCLE OPERATION

USING TIME BASE

To configure the PWM for 100% duty cycle set

PSMCxDC<15:0> > PSMCxPR<15:0>.

Note:

When the 64 MHz clock is selected, the

clock continues to operate in Sleep, even

This will prevent a falling edge event from occurring as

the PSMCxDC<15:0> value and the time base value

PSMCxTMR<15:0> will never be equal.

when

the

PSMC

is

disabled

(PSMCxEN = 0). Select a clock other than

the 64 MHz clock to minimize power con-

sumption when the PSMC is not enabled.

24.2.4

TIME BASE INTERRUPT

GENERATION

The Internal 64 MHz clock utilizes the system clock

4x PLL. When the system clock source is external and

the PSMC is using the Internal 64 MHz clock, the

4x PLL should not be used for the system clock.

The Time Base section can generate four unique

interrupts:

• Time Base Counter Overflow Interrupt

• Time Base Phase Register Match Interrupt

• Time Base Duty Cycle Register Match Interrupt

• Time Base Period Register Match Interrupt

 2011-2014 Microchip Technology Inc.

DS40001579E-page 195

PIC16(L)F1782/3

The clock source is selected with the PxCPRE<1:0>

bits of the PSMCx Clock Control (PSMCxCLK) register

(Register 24-5).

24.2.6

CLOCK PRESCALER

There are four prescaler choices available to be

applied to the selected clock:

The prescaler output is psmc_clk, which is the clock

used by all of the other portions of the PSMC module.

• Divide by 1

• Divide by 2

• Divide by 4

• Divide by 8

FIGURE 24-3:

TIME BASE WAVEFORM GENERATION

1

Period

psmc_clk

Counter 0030h 0000h 0001h 0002h 0003h

0027h 0028h 0029h 0030h 0000h

PSMCxPH<15:0>

0002h

0028h

0030h

PSMCxDC<15:0>

PSMCxPR<15:0>

Inputs

Period Event

Rising Edge Event

Falling Edge Event

Output

PWM Output

DS40001579E-page 196

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

The Falling Edge Blanking mode is set with the

PxFEBM<1:0> bits of the PSMCx Blanking Control

(PSMCxBLNK) register (Register 24-8).

24.2.7

ASYNCHRONOUS INPUTS

The PSMC module supports asynchronous inputs

alone or in combination with the synchronous inputs.

asynchronous inputs include:

The Rising Edge Blanking mode is set with the

PxREBM<1:0> bits of the PSMCx Blanking Control

(PSMCxBLNK) register (Register 24-8).

• Analog

- sync_C1OUT

- sync_C2OUT

- sync_C3OUT

• Digital

24.2.8.1

Blanking Disabled

With blanking disabled, the asynchronous inputs are

passed to the PSMC module without any intervention.

- PSMCxIN pin

24.2.8.2

Immediate Blanking

24.2.7.1

Comparator Inputs

With Immediate blanking, a counter is used to

determine the blanking period. The desired blanking

time is measured in psmc_clk periods. A rising edge

event will start incrementing the rising edge blanking

counter. A falling edge event will start incrementing the

falling edge blanking counter.

The outputs of any combination of the synchronized

comparators may be used to trigger any of the three

events as well as auto-shutdown.

The event triggers on the rising edge of the compara-

tor output. Except for auto-shutdown, the event input is

not level sensitive.

The rising edge blanking time is set with the PSMC

Rising Edge Blanking Time (PSMCxBLKR) register

(Register 24-28). The inputs to be blanked are

selected with the PSMC Rising Edge Blanked Source

(PSMCxREBS) register (Register 24-9). During rising

edge blanking, the selected blanked sources are

suppressed for falling edge as well as rising edge,

auto-shutdown and period events.

24.2.7.2

PSMCxIN Pin Input

The PSMCxIN pin may be used to trigger PSMC

events. Data is passed through straight to the PSMC

module without any synchronization to a system clock.

This is so that input blanking may be applied to any

external circuit using the module.

The event triggers on the rising edge of the PSMCxIN

signal.

The falling edge blanking time is set with the PSMC

Falling Edge Blanking Time (PSMCxBLKF) register

(Register 24-29). The inputs to be blanked are

selected with the PSMC Falling Edge Blanked Source

(PSMCxFEBS) register (Register 24-10). During

falling edge blanking, the selected blanked sources

are suppressed for rising edge, as well as falling edge,

auto-shutdown, and period events.

24.2.8

INPUT BLANKING

Input blanking is a function whereby the inputs from

any selected asynchronous input may be driven

inactive for a short period of time. This is to prevent

electrical transients from the turn-on/off of power

components from generating a false event.

The blanking counters are incremented on the rising

edge of psmc_clk. Blanked sources are suppressed

until the counter value equals the blanking time

register causing the blanking to terminate.

Blanking is initiated by either or both:

• Rising event

• Falling event

Blanked inputs are suppressed from causing all

asynchronous events, including:

As the rising and falling edge events are from

asynchronous inputs, there may be some uncertainty

in the actual blanking time implemented in each cycle.

The maximum uncertainty is equal to one psmc_clk

period.

• Rising

• Falling

• Period

• Shutdown

Rising edge and falling edge blanking are controlled

independently. The following features are available for

blanking:

• Blanking enable

• Blanking time counters

• Blanking mode

The following Blanking modes are available:

• Blanking disabled

• Immediate blanking

 2011-2014 Microchip Technology Inc.

DS40001579E-page 197

PIC16(L)F1782/3

24.2.9

OUTPUT WAVEFORM

GENERATION

24.3 Modes of Operation

All modes of operation use the period, rising edge, and

falling edge events to generate the various PWM

output waveforms.

The PSMC PWM output waveform is generated based

upon the different input events. However, there are

several other factors that affect the PWM waveshapes:

The 3-phase 6-step PWM mode makes special use of

the software controlled steering to generate the

required waveform.

• Output Control

- Output Enable

- Output Polarity

Modes of operation are selected with the PSMC

Control (PSMCxCON) register (Register 24-1).

• Waveform Mode Selection

• Dead-band Control

• Steering control

24.3.1

SINGLE-PHASE MODE

The single PWM is the most basic of all the

waveshapes generated by the PSMC module. It

consists of a single output that uses all three events

(rising edge, falling edge and period events) to

generate the waveform.

24.2.10 OUTPUT CONTROL

24.2.10.1 Output Pin Enable

Each PSMC PWM output pin has individual output

enable control.

24.3.1.1

Mode Features

When the PSMC output enable control is disabled, the

module asserts no control over the pin. In this state,

the pin can be used for general purpose I/O or other

associate peripheral use.

• No dead-band control available

• PWM can be steered to any combination of the

following PSMC outputs:

- PSMCxA

- PSMCxB

- PSMCxC

- PSMCxD

- PSMCxE

- PSMCxF

When the PSMC output enable is enabled, the active

PWM waveform is applied to the pin per the port

priority selection.

PSMC output enable selections are made with the

PSMC Output Enable Control (PSMCxOEN) register

(Register 24-6).

• Identical PWM waveform is presented to all pins

for which steering is enabled.

24.2.10.2 Output Steering

PWM output will be presented only on pins for which

output steering is enabled. The PSMC has up to six

PWM outputs. The PWM signal in some modes can be

steered to one or more of these outputs.

24.3.1.2

Waveform Generation

Rising Edge Event

• All outputs with PxSTR enabled are set to the

active state

Steering differs from output enable in the following

manner: When the output is enabled but the PWM

steering to the corresponding output is not enabled,

then general purpose output to the pin is disabled and

the pin level will remain constantly in the inactive PWM

state. Output steering is controlled with the PSMCS

Falling Edge Event

• All outputs with PxSTR enabled are set to the

inactive state

Code for setting up the PSMC generate the

single-phase waveform shown in Figure 24-4, and given

in Example 24-1.

Steering

Control

0

(PSMCxSTR0)

register

(Register 24-30).

Steering operates only in the following modes:

• Single-phase

• Complementary Single-phase

• 3-phase 6-step PWM

24.2.10.3 Polarity Control

Each PSMC output has individual output polarity

control. Polarity is set with the PSMC Polarity Control

(PSMCxPOL) register (Register 24-7).

DS40001579E-page 198

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

EXAMPLE 24-1:

SINGLE-PHASE SETUP

; Single-phase PWM PSMC setup

; Fully synchronous operation

; Period = 10 us

; Duty cycle = 50%

BANKSEL PSMC1CON

MOVLW

MOVWF

MOVLW

MOVWF

MOVLW

MOVWF

MOVLW

MOVWF

CLRF

0x02

PSMC1PRH

0x7F

PSMC1PRL

0x01

PSMC1DCH

0x3F

PSMC1DCL

PSMC1PHH

PSMC1PHL

0x01

; set period

; set duty cycle

; no phase offset

CLRF

MOVLW

MOVWF

; PSMC clock=64 MHz

PSMC1CLK

; output on A, normal polarity

BSF

BCF

BSF

PSMC1STR0,P1STRA

PSMC1POL, P1POLA

PSMC1OEN, P1OEA

; set time base as source for all events

BSF

PSMC1PRS, P1PRST

PSMC1PHS, P1PHST

PSMC1DCS, P1DCST

; enable PSMC in Single-Phase Mode

; this also loads steering and time buffers

MOVLW

MOVWF

B’11000000’

PSMC1CON

BANKSEL TRISC

BCF

TRISC, 0

; enable pin driver

FIGURE 24-4:

SINGLE PWM WAVEFORM – PSMCXSTR0 = 01H

1

2

3

PWM Period Number

Period Event

Rising Edge Event

Falling Edge Event

PSMCxA

 2011-2014 Microchip Technology Inc.

DS40001579E-page 199

PIC16(L)F1782/3

24.3.2

COMPLEMENTARY PWM

EXAMPLE 24-2:

COMPLEMENTARY

SINGLE-PHASE SETUP

The complementary PWM uses the same events as

the single PWM, but two waveforms are generated

instead of only one.

; Complementary Single-phase PWM PSMC setup

; Fully synchronous operation

; Period = 10 us

; Duty cycle = 50%

; Deadband = 93.75 +15.6/-0 ns

BANKSEL PSMC1CON

The two waveforms are opposite in polarity to each

other. The two waveforms may also have dead-band

control as well.

MOVLW

MOVWF

MOVLW

MOVWF

MOVLW

MOVWF

MOVLW

MOVWF

CLRF

0x02

PSMC1PRH

0x7F

PSMC1PRL

0x01

PSMC1DCH

0x3F

PSMC1DCL

PSMC1PHH

PSMC1PHL

0x01

; set period

24.3.2.1

Mode Features and Controls

• Dead-band control available

• PWM primary output can be steered to the

following pins:

; set duty cycle

- PSMCxA

- PSMCxC

- PSMCxE

; no phase offset

CLRF

MOVLW

MOVWF

; PSMC clock=64 MHz

• PWM complementary output can be steered to

the following pins:

PSMC1CLK

; output on A, normal polarity

- PSMCxB

- PSMCxD

- PSMCxE

MOVLW

MOVWF

CLRF

B’00000011’; A and B enables

PSMC1OEN

PSMC1STR0

PSMC1POL

; set time base as source for all events

24.3.2.2

Waveform Generation

BSF

PSMC1PRS, P1PRST

PSMC1PHS, P1PHST

PSMC1DCS, P1DCST

Rising Edge Event

• Complementary output is set inactive

• Optional rising edge dead band is activated

• Primary output is set active

; set rising and falling dead-band times

MOVLW

MOVWF

D’6’

PSMC1DBR

PSMC1DBF

Falling Edge Event

; enable PSMC in Complementary Single Mode

; this also loads steering and time buffers

; and enables rising and falling deadbands

• Primary output is set inactive

• Optional falling edge dead band is activated

• Complementary output is set active

MOVLW

MOVWF

B’11110001’

PSMC1CON

Code for setting up the PSMC generate the

complementary single-phase waveform shown in

Figure 24-5, and given in Example 24-2.

BANKSEL TRISC

BCF

TRISC, 0

TRISC, 1

; enable pin drivers

FIGURE 24-5:

COMPLEMENTARY PWM WAVEFORM – PSMCXSTR0 = 03H

1

2

3

PWM Period Number

Period Event

Rising Edge Event

Falling Edge Event

PSMCxA

(Primary Output)

Rising Edge Dead Band

Falling Edge Dead Band

PSMCxB

(Complementary Output)

DS40001579E-page 200

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Code for setting up the PSMC generate the comple-

mentary single-phase waveform shown in Figure 24-6,

and given in Example 24-3.

24.3.3

PUSH-PULL PWM

The push-pull PWM is used to drive transistor bridge

circuits. It uses at least two outputs and generates

PWM signals that alternate between the two outputs in

even and odd cycles.

EXAMPLE 24-3:

PUSH-PULL SETUP

; Push-Pull PWM PSMC setup

; Fully synchronous operation

; Period = 10 us

; Duty cycle = 50% (25% each phase)

BANKSEL PSMC1CON

Variations of the push-pull waveform include four

outputs with two outputs being complementary or two

sets of two identical outputs. Refer to Sections 24.3.4

through 24.3.6 for the other Push-Pull modes.

MOVLW

MOVWF

MOVLW

MOVWF

MOVLW

MOVWF

MOVLW

MOVWF

CLRF

0x02

PSMC1PRH

0x7F

PSMC1PRL

0x01

PSMC1DCH

0x3F

PSMC1DCL

PSMC1PHH

PSMC1PHL

0x01

; set period

24.3.3.1

Mode Features

• No dead-band control available

• No steering control available

• Output is on the following two pins only:

- PSMCxA

; set duty cycle

- PSMCxB

; no phase offset

CLRF

MOVLW

MOVWF

; PSMC clock=64 MHz

Note: This is a subset of the 6-pin output of the

push-pull PWM output, which is why pin

functions are fixed in these positions, so

they are compatible with that mode. See

Section 24.3.6 “Push-Pull PWM with Four

Full-Bridge and Complementary Out-

puts”

PSMC1CLK

; output on A and B, normal polarity

MOVLW

MOVWF

CLRF

B’00000011’

PSMC1OEN

PSMC1POL

; set time base as source for all events

BSF

PSMC1PRS, P1PRST

PSMC1PHS, P1PHST

PSMC1DCS, P1DCST

24.3.3.2

Waveform Generation

; enable PSMC in Push-Pull Mode

; this also loads steering and time buffers

Odd numbered period rising edge event:

• PSMCxA is set active

MOVLW

MOVWF

B’11000010’

PSMC1CON

BANKSEL TRISC

Odd numbered period falling edge event:

• PSMCxA is set inactive

BCF

TRISC, 0

TRISC, 1

; enable pin drivers

Even numbered period rising edge event:

• PSMCxB is set active

Even numbered period falling edge event:

• PSMCxB is set inactive

FIGURE 24-6:

PUSH-PULL PWM WAVEFORM

1

2

3

PWM Period Number

A Output

Period Event

B Output

Rising Edge Event

Falling Edge Event

PSMCxA

PSMCxB

 2011-2014 Microchip Technology Inc.

DS40001579E-page 201

PIC16(L)F1782/3

24.3.4

PUSH-PULL PWM WITH

24.3.4.2

Waveform Generation

COMPLEMENTARY OUTPUTS

Push-Pull waveforms generate alternating outputs on

the output pairs. Therefore, there are two sets of rising

edge events and two sets of falling edge events

The complementary push-pull PWM is used to drive

transistor bridge circuits as well as synchronous

switches on the secondary side of the bridge. The

PWM waveform is output on four pins presented as

two pairs of two-output signals with a normal and

complementary output in each pair. Dead band can be

inserted between the normal and complementary

outputs at the transition times.

Odd numbered period rising edge event:

• PSMCxE is set inactive

• Dead-band rising is activated (if enabled)

• PSMCxA is set active

Odd numbered period falling edge odd event:

• PSMCxA is set inactive

24.3.4.1

Mode Features

• Dead-band falling is activated (if enabled)

• PSMCxE is set active

• Dead-band control is available

• No steering control available

• Primary PWM output is only on:

- PSMCxA

Even numbered period rising edge event:

• PSMCxF is set inactive

- PSMCxB

• Dead-band rising is activated (if enabled)

• PSMCxB is set active

• Complementary PWM output is only on:

- PSMCxE

Even numbered period falling edge event:

- PSMCxF

• PSMCxB is set inactive

• Dead-band falling is activated (if enabled)

• PSMCxF is set active

Note: This is a subset of the 6-pin output of the

push-pull PWM output, which is why pin func-

tions are fixed in these positions, so they are

compatible

with

that

mode.

See

Section 24.3.6 “Push-Pull PWM with Four

Full-Bridge and Complementary Outputs”.

FIGURE 24-7:

PUSH-PULL WITH COMPLEMENTARY OUTPUTS PWM WAVEFORM

1

2

3

PWM Period Number

Period Event

Rising Edge Event

Falling Edge Event

Rising Edge Dead Band

PSMCxA

Falling Edge Dead Band

PSMCxE

PSMCxB

Falling Edge Dead Band

Rising Edge Dead Band

PSMCxF

DS40001579E-page 202

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

24.3.5

PUSH-PULL PWM WITH FOUR

FULL-BRIDGE OUTPUTS

Note: This is a subset of the 6-pin output of the

push-pull PWM output, which is why pin func-

tions are fixed in these positions, so they are

The full-bridge push-pull PWM is used to drive

transistor bridge circuits as well as synchronous

switches on the secondary side of the bridge.

compatible

with

that

mode.

See

Section 24.3.6 “Push-Pull PWM with Four

24.3.5.1

Mode Features

Full-Bridge and Complementary Outputs”.

• No Dead-band control

• No Steering control available

• PWM is output on the following four pins only:

- PSMCxA

24.3.5.2

Waveform generation

Push-pull waveforms generate alternating outputs on

the output pairs. Therefore, there are two sets of rising

edge events and two sets of falling edge events.

- PSMCxB

Odd numbered period rising edge event:

- PSMCxC

• PSMCxOUT0 and PSMCxOUT2 is set active

Odd numbered period falling edge event:

• PSMCxOUT0 and PSMCxOUT2 is set inactive

Even numbered period rising edge event:

• PSMCxOUT1 and PSMCxOUT3 is set active

Even numbered period falling edge event:

• PSMCxOUT1 and PSMCxOUT3 is set inactive

- PSMCxD

Note: PSMCxA and PSMCxC are identical

waveforms, and PSMCxB and PSMCxD are

identical waveforms.

FIGURE 24-8:

PUSH-PULL PWM WITH 4 FULL-BRIDGE OUTPUTS

1

2

3

PWM Period Number

Period Event

Rising Edge Event

Falling Edge Event

PSMCxA

PSMCxC

PSMCxB

PSMCxD

 2011-2014 Microchip Technology Inc.

DS40001579E-page 203

PIC16(L)F1782/3

24.3.6

PUSH-PULL PWM WITH FOUR

FULL-BRIDGE AND

COMPLEMENTARY OUTPUTS

24.3.6.2

Waveform Generation

Push-pull waveforms generate alternating outputs on

two sets of pin. Therefore, there are two sets of rising

edge events and two sets of falling edge events

The push-pull PWM is used to drive transistor bridge

circuits as well as synchronous switches on the

secondary side of the bridge. It uses six outputs and

generates PWM signals with dead band that alternate

between the six outputs in even and odd cycles.

Odd numbered period rising edge event:

• PSMCxE is set inactive

• Dead-band rising is activated (if enabled)

• PSMCxA and PSMCxC are set active

24.3.6.1

Mode Features and Controls

Odd numbered period falling edge event:

• Dead-band control is available

• No steering control available

• Primary PWM is output on the following four pins:

- PSMCxA

• PSMCxA and PSMCxC are set inactive

• Dead-band falling is activated (if enabled)

• PSMCxE is set active

Even numbered period rising edge event:

- PSMCxB

• PSMCxF is set inactive

- PSMCxC

• Dead-band rising is activated (if enabled)

• PSMCxB and PSMCxD are set active

- PSMCxD

• Complementary PWM is output on the following

two pins:

Even numbered period falling edge event:

- PSMCxE

- PSMCxF

• PSMCxB and PSMCxOUT3 are set inactive

• Dead-band falling is activated (if enabled)

• PSMCxF is set active

Note: PSMCxA and PSMCxC are identical

waveforms, and PSMCxB and PSMCxD are

identical waveforms.

FIGURE 24-9:

PUSH-PULL 4 FULL-BRIDGE AND COMPLEMENTARY PWM

1

2

3

PWM Period Number

Period Event

Rising Edge Event

Falling Edge Event

Rising Edge Dead Band

PSMCxA

PSMCxC

Falling Edge Dead Band

PSMCxE

PSMCxB

PSMCxD

PSMCxF

Falling Edge Dead Band

Rising Edge Dead Band

DS40001579E-page 204

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

24.3.7

PULSE-SKIPPING PWM

24.3.7.2

Waveform Generation

The pulse-skipping PWM is used to generate a series

of fixed-length pulses that can be triggered at each

period event. A rising edge event will be generated

when any enabled asynchronous rising edge input is

active when the period event occurs, otherwise no

event will be generated.

Rising Edge Event

If any enabled asynchronous rising edge event = 1

when there is a period event, then upon the next

synchronous rising edge event:

•

PSMCxA is set active

Falling Edge Event

The rising edge event occurs based upon the value in

the PSMCxPH register pair.

• PSMCxA is set inactive

The falling edge event always occurs according to the

enabled event inputs without qualification between any

two inputs.

Note: To use this mode, an external source must

be used for the determination of whether or

not to generate the set pulse. If the phase

time base is used, it will either always gener-

ate a pulse or never generate a pulse based

on the PSMCxPH value.

24.3.7.1

Mode Features

• No dead-band control available

• No steering control available

• PWM is output to only one pin:

- PSMCxA

FIGURE 24-10:

PULSE-SKIPPING PWM WAVEFORM

1

2

3

4

5

6

7

8

9

10

11

12

PWM Period Number

period_event

Asynchronous

Rising Edge Event

Synchronous

Rising Edge Event

Falling Edge Event

PSMCxA

 2011-2014 Microchip Technology Inc.

DS40001579E-page 205

PIC16(L)F1782/3

24.3.8

PULSE-SKIPPING PWM WITH

COMPLEMENTARY OUTPUTS

24.3.8.2

Waveform Generation

Rising Edge Event

The pulse-skipping PWM is used to generate a series

of fixed-length pulses that may or not be triggered at

each period event. If any of the sources enabled to

generate a rising edge event are high when a period

event occurs, a pulse will be generated. If the rising

edge sources are low at the period event, no pulse will

be generated.

If any enabled asynchronous rising edge event = 1

when there is a period event, then upon the next

synchronous rising edge event:

• Complementary output is set inactive

• Dead-band rising is activated (if enabled)

• Primary output is set active

The rising edge occurs based upon the value in the

PSMCxPH register pair.

Falling Edge Event

• Primary output is set inactive

The falling edge event always occurs according to the

enabled event inputs without qualification between any

two inputs.

• Dead-band falling is activated (if enabled)

• Complementary output is set active

24.3.8.1

Mode Features

Note: To use this mode, an external source must

be used for the determination of whether or

not to generate the set pulse. If the phase

time base is used, it will either always gener-

ate a pulse or never generate a pulse based

on the PSMCxPH value.

• Dead-band control is available

• No steering control available

• Primary PWM is output on only PSMCxA.

• Complementary PWM is output on only PSMCxB.

FIGURE 24-11:

PULSE-SKIPPING WITH COMPLEMENTARY OUTPUT PWM WAVEFORM

1

2

3

4

5

6

7

8

9

10

PWM Period Number

Period Event

Asynchronous

Rising Edge Event

Synchronous

Rising Edge Event

PSMCxA

PSMCxB

Falling Edge Dead Band

Rising Edge Dead Band

DS40001579E-page 206

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

24.3.9

ECCP COMPATIBLE FULL-BRIDGE

PWM

24.3.9.2

Waveform Generation - Forward

In this mode of operation, three of the four pins are

static. PSMCxA is the only output that changes based

on rising edge and falling edge events.

This mode of operation is designed to match the

Full-Bridge mode from the ECCP module. It is called

ECCP compatible as the term “full-bridge” alone has

different connotations in regards to the output

waveforms.

Static Signal Assignment

• Outputs set to active state

- PSMCxD

Full-Bridge Compatible mode uses the same

waveform events as the single PWM mode to

generate the output waveforms.

• Outputs set to inactive state

- PSMCxB

- PSMCxC

There are both Forward and Reverse modes available

for this operation, again to match the ECCP implemen-

tation. Direction is selected with the mode control bits.

Rising Edge Event

• PSMCxA is set active

Falling Edge Event

24.3.9.1

Mode Features

• PSMCxA is set inactive

• Dead-band control available on direction switch

- Changing from forward to reverse uses the

falling edge dead-band counters.

24.3.9.3

Waveform Generation – Reverse

In this mode of operation, three of the four pins are

static. Only PSMCxB toggles based on rising edge

and falling edge events.

- Changing from reverse to forward uses the

rising edge dead-band counters.

• No steering control available

Static Signal Assignment

• PWM is output on the following four pins only:

• Outputs set to active state

- PSMCxC

- PSMCxA

- PSMCxB

- PSMCxC

- PSMCxD

• Outputs set to inactive state

- PSMCxA

- PSMCxD

Rising Edge Event

• PSMCxB is set active

Falling Edge Event

• PSMCxB is set inactive

FIGURE 24-12:

ECCP COMPATIBLE FULL-BRIDGE PWM WAVEFORM – PSMCXSTR0 = 0FH

1

2

3

4

5

6

7

8

9

10

11

12

PWM Period Number

Forward mode operation

Reverse mode operation

Period Event

Falling Edge Event

PSMCxA

PSMCxB

PSMCxC

Rising Edge Dead Band

Falling Edge Dead Band

PSMCxD

 2011-2014 Microchip Technology Inc.

DS40001579E-page 207

PIC16(L)F1782/3

24.3.10 VARIABLE FREQUENCY – FIXED

DUTY CYCLE PWM

24.3.10.2 Waveform Generation

Period Event

This mode of operation is quite different from all of the

other modes. It uses only the period event for

waveform generation. At each period event, the PWM

output is toggled.

• Output of PSMCxA is toggled

• FFA counter is incremented by the 4-bit value in

PSMCxF FA

The rising edge and falling edge events are unused in

this mode.

24.3.10.1 Mode Features

• No dead-band control available

• No steering control available

• Fractional Frequency Adjust

- Fine period adjustments are made with the

PSMC Fractional Frequency Adjust

(PSMCxFFA) register (Register 24-27)

• PWM is output on the following pin only:

- PSMCxA

FIGURE 24-13:

VARIABLE FREQUENCY – FIXED DUTY CYCLE PWM WAVEFORM

1

2

3

4

5

6

7

8

9

10

PWM Period Number

period_event

Rising Edge Event

Falling Edge Event

Unused in this mode

PSMCxA

DS40001579E-page 208

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

24.3.11 VARIABLE FREQUENCY - FIXED

DUTY CYCLE PWM WITH

24.3.11.2 Waveform Generation

Period Event

COMPLEMENTARY OUTPUTS

When output is going inactive to active:

• Complementary output is set inactive

This mode is the same as the single output Fixed Duty

Cycle mode except a complementary output with

dead-band control is generated.

• FFA counter is incremented by the 4-bit value in

PSMCFFA register.

The rising edge and falling edge events are unused in

this mode. Therefore, a different triggering mechanism

is required for the dead-band counters.

• Dead-band rising is activated (if enabled)

• Primary output is set active

When output is going active to inactive:

• Primary output is set inactive

A period events that generate a rising edge on

PSMCxA use the rising edge dead-band counters.

• FFA counter is incremented by the 4-bit value in

PSMCFFA register

A period events that generate a falling edge on

PSMCxA use the falling edge dead-band counters.

• Dead-band falling is activated (if enabled)

• Complementary output is set active

24.3.11.1 Mode Features

• Dead-band control is available

• No steering control available

• Fractional Frequency Adjust

- Fine period adjustments are made with the

PSMC Fractional Frequency Adjust

(PSMCxFFA) register (Register 24-27)

• Primary PWM is output to the following pin:

- PSMCxA

• Complementary PWM is output to the following

pin:

- PSMCxB

FIGURE 24-14:

VARIABLE FREQUENCY – FIXED DUTY CYCLE PWM WITH COMPLEMENTARY

OUTPUTS WAVEFORM

1

2

3

4

5

6

7

8

9

10

PWM Period Number

period_event

Rising Edge Event

Falling Edge Event

Unused in this mode

PSMCxA

PSMCxB

Falling Edge Dead Band

Rising Edge Dead Band

 2011-2014 Microchip Technology Inc.

DS40001579E-page 209

PIC16(L)F1782/3

24.3.12 3-PHASE PWM

24.3.12.2 Waveform Generation

The 3-Phase mode of operation is used in 3-phase

power supply and motor drive applications configured

as three half-bridges. A half-bridge configuration

consists of two power driver devices in series,

between the positive power rail (high side) and nega-

tive power rail (low side). The three outputs come from

the junctions between the two drivers in each

half-bridge. When the steering control selects a phase

drive, power flows from the positive rail through a

high-side power device to the load and back to the

power supply through a low-side power device.

3-phase steering has a more complex waveform

generation scheme than the other modes. There are

several factors which go into what waveforms are

created.

The PSMC outputs are grouped into three sets of

drivers: one for each phase. Each phase has two

associated PWM outputs: one for the high-side drive

and one for the low-side drive.

High Side drives are indicated by 1H, 2H and 3H.

Low Side drives are indicated by 1L, 2L, 3L.

In this mode of operation, all six PSMC outputs are

used, but only two are active at a time.

Phase grouping is mapped as shown in Table 24-1.

There are six possible phase drive combinations.

Each phase drive combination activates two of the six

outputs and deactivates the other four. Phase drive is

selected with the steering control as shown in

Table 24-2.

The two active outputs consist of a high-side driver

and low-side driver output.

24.3.12.1 Mode Features

TABLE 24-1:

PHASE GROUPING

PSMC grouping

• No dead-band control is available

• PWM can be steered to the following six pairs:

- PSMCxA and PSMCxD

PSMCxA

1H

1L

2H

2L

3H

3L

- PSMCxA and PSMCxF

PSMCxB

PSMCxC

PSMCxD

PSMCxE

PSMCxF

- PSMCxC and PSMCxF

- PSMCxC and PSMCxB

- PSMCxE and PSMCxB

- PSMCxE and PSMCxD

TABLE 24-2: 3-PHASE STEERING CONTROL

PSMCxSTR0 Value⁽1⁾

PSMC outputs

00h

01h

02h

04h

08h

10h

20h

PSMCxA

PSMCxB

PSMCxC

PSMCxD

PSMCxE

PSMCxF

1H

inactive

active

inactive

active

inactive

active

inactive

active

inactive

active

inactive

active

inactive

active

1L

2H

2L

3H

3L

active

inactive

active

inactive

active

inactive

active

inactive

Note 1: Steering for any value other than those shown will default to the output combination of the Least Significant

steering bit that is set.

High/Low Side Modulation Enable

When both the PxHSMEN and PxLSMEN bits are

cleared, the active outputs listed in Table 24-2 go

immediately to the rising edge event states and do not

change.

It is also possible to enable the PWM output on the low

side or high side drive independently using the

PxLSMEN and PXHSMEN bits of the PSMC Steering

Control 1 (PSMCxSTR1) register (Register 24-31).

Rising Edge Event

When the PxHSMEN bit is set, the active-high side

output listed in Table 24-2 is modulated using the

normal rising edge and falling edge events.

• Active outputs are set to their active states

Falling Edge Event

• Active outputs are set to their inactive state

When the PxLSMEN bit is set, the active-low side

output listed in Table 24-2 is modulated using the

normal rising edge and falling edge events.

DS40001579E-page 210

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

24.4.3

DEAD-BAND CLOCK SOURCE

24.4 Dead-Band Control

The dead-band counters are incremented on every

rising edge of the psmc_clk signal.

The dead-band control provides non-overlapping

PWM signals to prevent shoot-through current in

series connected power switches. Dead-band control

is available only in modes with complementary drive

and when changing direction in the ECCP compatible

Full-Bridge modes.

24.4.4

DEAD-BAND UNCERTAINTY

When the rising and falling edge events that trigger the

dead-band counters come from asynchronous inputs,

there will be uncertainty in the actual dead-band time of

each cycle. The maximum uncertainty is equal to one

psmc_clk period. The one clock of uncertainty may still

be introduced, even when the dead-band count time is

cleared to zero.

The module contains independent 8-bit dead-band

counters for rising edge and falling edge dead-band

control.

24.4.1

DEAD-BAND TYPES

There are two separate dead-band generators

available, one for rising edge events and the other for

falling edge events.

24.4.5

DEAD-BAND OVERLAP

There are two cases of dead-band overlap and each is

treated differently due to system requirements.

24.4.1.1

Rising Edge Dead Band

24.4.5.1

Rising to Falling Overlap

Rising edge dead-band control is used to delay the

turn-on of the primary switch driver from when the

complementary switch driver is turned off.

In this case, the falling edge event occurs while the

rising edge dead-band counter is still counting. The

following sequence occurs:

Rising edge dead band is initiated with the rising edge

event.

1. Dead-band rising count is terminated.

2. Dead-band falling count is initiated.

3. Primary output is suppressed.

Rising edge dead-band time is adjusted with the

PSMC Rising Edge Dead-Band Time (PSMCxDBR)

register (Register 24-25).

24.4.5.2

Falling to Rising Overlap

If the PSMCxDBR register value is changed when the

PSMC is enabled, the new value does not take effect

until the first period event after the PSMCxLD bit is set.

In this case, the rising edge event occurs while the

falling edge dead-band counter is still counting. The

following sequence occurs:

24.4.1.2

Falling Edge Dead Band

1. Dead-band falling count is terminated.

2. Dead-band rising count is initiated.

3. Complementary output is suppressed.

Falling edge dead-band control is used to delay the

turn-on of the complementary switch driver from when

the primary switch driver is turned off.

24.4.5.3

Rising Edge-to-Rising Edge or

Falling Edge-to-Falling Edge

Falling edge dead band is initiated with the falling

edge event.

In cases where one of the two dead-band counters is

set for a short period, or disabled all together, it is

possible to get rising-to-rising or falling-to-falling

overlap. When this is the case, the following sequence

occurs:

Falling edge dead-band time is adjusted with the

PSMC Falling Edge Dead-Band Time (PSMCxDBF)

register (Register 24-26).

If the PSMCxDBF register value is changed when the

PSMC is enabled, the new value does not take effect

until the first period event after the PSMCxLD bit is set.

1. Dead-band count is terminated.

2. Dead-band count is restarted.

24.4.2

DEAD-BAND ENABLE

3. Output waveform control freezes in the present

state.

When a mode is selected that may use dead-band

control, dead-band timing is enabled by setting one of

the enable bits in the PSMC Control (PSMCxCON)

register (Register 24-1).

4. Restarted dead-band count completes.

5. Output control resumes normally.

Rising edge dead band is enabled with the PxDBRE

bit.

Rising edge dead band is enabled with the PxDBFE

bit.

Enable changes take effect immediately.

DS40001579E-page 212

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

24.5.1

3-PHASE STEERING

24.5 Output Steering

3-phase steering is available in the 3-Phase Modulation

mode only. For more details on 3-phase steering refer to

Section 24.3.12 “3-Phase PWM”.

Output steering allows for PWM signals generated by

the PSMC module to be placed on different pins under

software control. Synchronized steering will hold steer-

ing changes until the first period event after the

PSMCxLD bit is set. Unsynchronized steering

changes will take place immediately.

24.5.2

SINGLE PWM STEERING

In Single PWM Steering mode, the single PWM signal

can be routed to any combination of the PSMC output

pins. Examples of unsynchronized single PWM

steering are shown in Figure 24-16.

Output steering is available in the following modes:

• 3-phase PWM

• Single PWM

• Complementary PWM

FIGURE 24-16:

SINGLE PWM STEERING WAVEFORM (NO SYNCHRONIZATION)

Base_PWM_signal

PxSTRA

PSMCxA

PxSTRB

PSMCxB

PxSTRC

PSMCxC

PxSTRD

PSMCxD

PxSTRE

PSMCxE

PxSTRF

PSMCxF

With synchronization disabled, it is possible to get glitches on the PWM outputs.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 213

PIC16(L)F1782/3

The complementary PWM signal can be steered to any

of the following outputs:

24.5.3

COMPLEMENTARY PWM

STEERING

• PSMCxB

• PSMCxD

• PSMCxE

In Complementary PWM Steering mode, the primary

PWM signal (non-complementary) and complementary

signal can be steered according to their respective type.

Primary PWM signal can be steered to any of the

following outputs:

Examples of unsynchronized complementary steering

are shown in Figure 24-17.

• PSMCxA

• PSMCxC

• PSMCxE

FIGURE 24-17:

COMPLEMENTARY PWM STEERING WAVEFORM (NO SYNCHRONIZATION,

ZERO DEAD-BAND TIME)

Base_PWM_signal

PxSTRA

PSMCxA

PSMCxB

PxSTRB

Arrows indicate where a change in the steering bit automatically

forces a change in the corresponding PSMC output.

PxSTRC

PSMCxC

PSMCxD

PxSTRD

PxSTRE

PSMCxE

PSMCxF

PxSTRF

DS40001579E-page 214

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Examples of synchronized steering are shown in

Figure 24-18.

24.5.4

SYNCHRONIZED PWM STEERING

In Single, Complementary and 3-phase PWM modes,

it is possible to synchronize changes to steering

selections with the period event. This is so that PWM

outputs do not change in the middle of a cycle and

therefore, disrupt operation of the application.

24.5.5

INITIALIZING SYNCHRONIZED

STEERING

If synchronized steering is to be used, special care

should be taken to initialize the PSMC Steering

Control 0 (PSMCxSTR0) register (Register 24-30) in a

safe configuration before setting either the PSMCxEN

or PSMCxLD bits. When either of those bits are set,

the PSMCxSTR0 value at that time is loaded into the

synchronized steering output buffer. The buffer load

occurs even if the PxSSYNC bit is low. When the

PxSSYNC bit is set, the outputs will immediately go to

the drive states in the preloaded buffer.

Steering synchronization is enabled by setting the

PxSSYNC bit of the PSMC Steering Control 1

(PSMCxSTR1) register (Register 24-31).

When synchronized steering is enabled while the

PSMC module is enabled, steering changes do not

take effect until the first period event after the

PSMCxLD bit is set.

FIGURE 24-18:

PWM STEERING WITH SYNCHRONIZATION WAVEFORM

1

2

3

4

5

6

7

Period Number

PWM Signal

PxSTRA

Synchronized PxSTRA

PxSTRB

Synchronized PxSTRB

PSMCxA

PSMCxB

 2011-2014 Microchip Technology Inc.

DS40001579E-page 215

PIC16(L)F1782/3

24.6.2.1

PxMDLBIT Bit

24.6 PSMC Modulation (Burst Mode)

The PxMDLBIT bit of the PSMC Modulation Control

(PSMCxMDL) register (Register 24-2) allows for

software modulation control without having to

enable/disable other module functions.

PSMC modulation is a method to stop/start PWM

operation of the PSMC without having to disable the

module. It also allows other modules to control the

operational period of the PSMC. This is also referred

to as Burst mode.

24.6.3

MODULATION EFFECT ON PWM

SIGNALS

This is a method to implement PWM dimming.

When modulation starts, the PSMC begins operation

on a new period, just as if it had rolled over from one

period to another during continuous operation.

24.6.1

MODULATION ENABLE

The modulation function is enabled by setting the

PxMDLEN bit of PSMC Modulation Control

(PSMCxMDL) register (Register 24-2).

When modulation stops, its operation depends on the

type of waveform being generated.

When modulation is enabled, the modulation source

controls when the PWM signals are active and

inactive.

In operation modes other than Fixed Duty Cycle, the

PSMC completes its current PWM period and then

freezes the module. The PSMC output pins are forced

into the default inactive state ready for use when

modulation starts.

When modulation is disabled, the PWM signals

operate continuously, regardless of the selected

modulation source.

In Fixed Duty Cycle mode operation, the PSMC

continues to operate until the period event changes

the PWM to its inactive state, at which point the PSMC

module is frozen. The PSMC output pins are forced

into the default inactive state ready for use when

modulation starts.

24.6.2

MODULATION SOURCES

There are multiple sources that can be used for

modulating the PSMC. However, unlike the PSMC

input sources, only one modulation source can be

selected at a time. Modulation sources include:

• PSMCxIN pin

• Any CCP output

• Any Comparator output

• PxMDLBIT of the PSMCxMDL register

FIGURE 24-19:

PSMC MODULATION WAVEFORM

1

2

3

4

5

6

7

1

2

3

4

5

Modulation Input

PWM Period

PWM Off

PWM

Off

DS40001579E-page 216

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

24.7.2

PIN OVERRIDE LEVELS

24.7 Auto-Shutdown

The logic levels driven to the output pins during an

auto-shutdown event are determined by the PSMC

Auto-shutdown Output Level (PSMCxASDL) register

(Register 24-15).

Auto-shutdown is a method to immediately override

the PSMC output levels with specific overrides that

allow for safe shutdown of the application.

Auto-shutdown includes a mechanism to allow the

application to restart under different conditions.

24.7.2.1

PIN Override Enable

Auto-shutdown is enabled with the PxASDEN bit of the

PSMC Auto-shutdown Control (PSMCxASDC) register

(Register 24-14). All auto-shutdown features are

enabled when PxASDEN is set and disabled when

cleared.

Setting the PxASDOV bit of the PSMC Auto-shutdown

Control (PSMCxASDC) register (Register 24-14) will

also force the override levels onto the pins, exactly like

what happens when the auto-shutdown is used.

However, whereas setting PxASE causes an

auto-shutdown interrupt, setting PxASDOV does not

generate an interrupt.

24.7.1

SHUTDOWN

There are two ways to generate a shutdown event:

24.7.3

RESTART FROM

AUTO-SHUTDOWN

• Manual

• External Input

After an auto-shutdown event has occurred, there are

two ways for the module to resume operation:

24.7.1.1

Manual Override

• Manual restart

The auto-shutdown control register can be used to

manually override the pin functions. Setting the PxASE

bit of the PSMC Auto-shutdown Control (PSMCxASDC)

• Automatic restart

The restart method is selected with the PxARSEN bit of

the PSMC Auto-shutdown Control (PSMCxASDC)

register (Register 24-14).

register (Register 24-14) generates

shut-down event.

a

software

The auto-shutdown override will persist as long as

PxASE remains set.

24.7.3.1

Manual Restart

When PxARSEN is cleared, and once the PxASDE bit

is set, it will remain set until cleared by software.

24.7.1.2

External Input Source

Any of the given sources that are available for event

generation are also available for system shut-down.

This is so that external circuitry can monitor and force

The PSMC will restart on the period event after

PxASDE bit is cleared in software.

a

shutdown without any software overhead.

24.7.3.2

Auto-Restart

Auto-shutdown sources are selected with the PSMC

Auto-shutdown Source (PSMCxASDS) register

(Register 24-16).

When PxARSEN is set, the PxASDE bit will clear

automatically when the source causing the Reset and

no longer asserts the shut-down condition.

When any of the selected external auto-shutdown

sources go high, the PxASE bit is set and an

auto-shutdown interrupt is generated.

The PSMC will restart on the next period event after

the auto-shutdown condition is removed.

Examples of manual and automatic restart are shown

in Figure 24-20.

Note: The external shutdown sources are level

sensitive, not edge sensitive. The shutdown

condition will persist as long as the circuit is

driving the appropriate logic level.

Note: Whether manual or auto-restart is selected,

the PxASDE bit cannot be cleared in

software when the auto-shutdown condition

is still present.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 217

PIC16(L)F1782/3

FIGURE 24-20:

AUTO-SHUTDOWN AND RESTART WAVEFORM

1

2

3

4

5

Base PWM signal

PxARSEN

Next Period Event

Auto-Shutdown Source

cleared

in software

cleared

in software

PSMCx Auto-shutdown int flag bit

Cleared

in hardware

Next Period Event

PxASE

Cleared

in software

PSMCxA

PSMCxB

Normal

Output

Auto-

shutdown

Auto-

shutdown

Normal

Output

Normal

Output

Operating State

Manual Restart

Auto-restart

DS40001579E-page 218

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

24.8 PSMC Synchronization

It is possible to synchronize the periods of two or more

PSMC modules together, provided that all modules

are on the same device.

Synchronization is achieved by sending a sync signal

from the master PSMC module to the desired slave

modules. This sync signal generates a period event in

each slave module, thereby aligning all slaves with the

master. This is useful when an application requires

different PWM signal generation from each module but

the waveforms must be consistent within a PWM

period.

24.8.1

SYNCHRONIZATION SOURCES

The synchronization source can be any PSMC module

on the same device. For example, in a device with two

PSMC modules, the possible sources for each device

is as shown below:

• Sources for PSMC1

- PSMC2

• Sources for PSMC2

- PSMC1

24.8.1.1

PSMC Internal Connections

The sync signal from the master PSMC module is

essentially that modules period event trigger. The

slave PSMC modules reset their PSMCxTMR with the

sync signal instead of their own period event.

Enabling a module as a slave recipient is done with

the PxSYNC bits of the PSMC Synchronization

Control (PSMCxSYNC) registers; registers 24-3

and 24-4.

24.8.1.2

Synchronization Skid

When the sync_out source is the Period Event, the

slave synchronous rising and falling events will lag by

one psmc_clk period. When the sync_out source is the

Rising Event, the synchronous events will lag by two

clock periods. To compensate for this, the values in

PHH:PHL and DCH:DCL registers can be reduced by

the number of lag cycles.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 219

PIC16(L)F1782/3

psmc_clk period (TPSMC_CLK) every N events, then

the effective resolution of the average event period is

TPSMC_CLK/N.

24.9 Fractional Frequency Adjust (FFA)

FFA is a method by which PWM resolution can be

improved on 50% fixed duty cycle signals. Higher

resolution is achieved by altering the PWM period by a

single count for calculated intervals. This increased

resolution is based upon the PWM frequency

averaged over a large number of PWM periods. For

example, if the period event time is increased by one

When active, after every period event the FFA

hardware adds the PSMCxFFA value with the

previously accumulated result. Each time the addition

causes an overflow, the period event time is increased

by one. Refer to Figure 24-21.

FIGURE 24-21:

FFA BLOCK DIAGRAM.

PSMCxPR<15:0>

PSMCxFFA<3:0>



carry

Comparator

Accumulator<3:0>

=

Period Event

PSMCxTMR<15:0>

psmc_clk

The FFA function is only available when using one of

the two Fixed Duty Cycle modes of operation. In fixed

duty cycle operation each PWM period is comprised of

two period events. That is why the PWM periods in

Table 24-3 example calculations are multiplied by two

as opposed to the normal period calculations for

normal mode operation.

TABLE 24-3: FRACTIONAL FREQUENCY

ADJUST CALCULATIONS

Parameter

Value

FPSMC_CLK

TPSMC_CLK

64 MHz

15.625 ns

PSMCxPR<15:0> 00FFh = 255

TPWM

= (PSMCxPR<15:0>+1)*2*TPSMC_CLK

= 256*2*15.625ns

= 8 us

The extra resolution gained by the FFA is based upon

the number of bits in the FFA register and the psmc_-

clk frequency. The parameters of interest are:

FPWM

125 kHz

• TPWM – this is the lower bound of the PWM period

that will be adjusted

TPWM+1

= (PSMCxPR<15:0>+2)*2*TPSMC_CLK

= 257*2*15.625ns

= 8.03125 us

• TPWM+1 – this is the upper bound of the PWM

period that will be adjusted. This is used to help

determine the step size for each increment of the

FFA register

FPWM+1

= 124.513 kHz

TRESOLUTION

= (TPWM+1-TPWM)/2^FFA-Bits

= (8.03125us - 8.0 us)/16

= 0.03125us/16

~ 1.95 ns

(FPWM+1-FPWM)/2^FFA-Bits

• TRESOLUTION – each increment of the FFA

register will add this amount of period to average

PWM frequency

FRESOLUTION

~ -30.4 Hz

DS40001579E-page 220

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 24-4: SAMPLE FFA OUTPUT PERIODS/FREQUENCIES

FFA number

Output Frequency (kHz)

Step Size (Hz)

0

1

125.000

124.970

124.939

124.909

124.878

124.848

124.818

124.787

124.757

124.726

124.696

124.666

124.635

124.605

124.574

124.544

0

-30.4

2

-60.8

3

-91.2

4

-121.6

-152.0

-182.4

-212.8

-243.2

-273.6

-304.0

-334.4

-364.8

-395.2

-425.6

-456.0

5

6

7

8

9

10

11

12

13

14

15

 2011-2014 Microchip Technology Inc.

DS40001579E-page 221

PIC16(L)F1782/3

24.10 Register Updates

24.11 Operation During Sleep

There are 10 double-buffered registers that can be

updated “on the fly”. However, due to the

asynchronous nature of the potential updates, a

special hardware system is used for the updates.

The PSMC continues to operate in Sleep with the

following clock sources:

• Internal 64 MHz

• External clock

There are two operating cases for the PSMC:

• module is enabled

• module is disabled

24.10.1 DOUBLE BUFFERED REGISTERS

The double-buffered registers that are affected by the

special hardware update system are:

• PSMCxPRL

• PSMCxPRH

• PSMCxDCL

• PSMCxDCH

• PSMCxPHL

• PSMCxPHH

• PSMCxDBR

• PSMCxDBF

• PSMCxBLKR

• PSMCxBLKF

• PSMCxSTR0 (when the PxSSYNC bit is set)

24.10.2 MODULE DISABLED UPDATES

When the PSMC module is disabled (PSMCxEN = 0),

any write to one of the buffered registers will also write

directly to the buffer. This means that all buffers are

loaded and ready for use when the module is enabled.

24.10.3 MODULE ENABLED UPDATES

When the PSMC module is enabled (PSMCxEN = 1),

the PSMCxLD bit of the PSMC Control (PSMCxCON)

register (Register 24-1) must be used.

When the PSMCxLD bit is set, the transfer from the

register to the buffer occurs on the next period event.

The PSMCxLD bit is automatically cleared by hardware

after the transfer to the buffers is complete.

The reason that the PSMCxLD bit is required is that

depending on the customer application and operation

conditions, all 10 registers may not be updated in one

PSMC period. If the buffers are loaded at different

times (i.e., DCL gets updated, but DCH does not OR

DCL and DCL are updated by PRH and PRL are not),

then unintended operation may occur.

The sequence for loading the buffer registers when the

PSMC module is enabled is as follows:

1. Software updates all registers.

2. Software sets the PSMCxLD bit.

3. Hardware updates all buffers on the next period

event.

4. Hardware clears PSMCxLD bit.

DS40001579E-page 222

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

24.12 Register Definitions: PSMC Control

REGISTER 24-1: PSMCxCON: PSMC CONTROL REGISTER

R/W-0/0

R/W/HC-0/0

PSMCxLD

R/W-0/0

PxDBFE

R/W-0/0

PxDBRE

R/W-0/0

bit 0

PSMCxEN

PxMODE<3:0>

bit 7

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

bit 6

bit 5

bit 4

bit 3-0

PSMCxEN: PSMC Module Enable bit

1= PSMCx module is enabled

0= PSMCx module is disabled

PSMCxLD: PSMC Load Buffer Enable bit

1= PSMCx registers are ready to be updated with the appropriate register contents

0= PSMCx buffer update complete

PxDBFE: PSMC Falling Edge Dead-Band Enable bit

1= PSMCx falling edge dead band enabled

0= PSMCx falling edge dead band disabled

PxDBRE: PSMC Rising Edge Dead-Band Enable bit

1= PSMCx rising edge dead band enabled

0= PSMCx rising edge dead band disabled

PxMODE<3:0> PSMC Operating Mode bits

1111= Reserved

1110= Reserved

1101= Reserved

1100= 3-phase steering PWM

1011= Fixed duty cycle, variable frequency, complementary PWM

1010= Fixed duty cycle, variable frequency, single PWM

1001= ECCP compatible Full-Bridge forward output

1000= ECCP compatible Full-Bridge reverse output

0111= Pulse-skipping with complementary output

0110= Pulse-skipping PWM output

0101= Push-pull with four full-bridge outputs and complementary outputs

0100= Push-pull with four full-bridge outputs

0011= Push-pull with complementary outputs

0010= Push-pull output

0001= Single PWM with complementary output (with PWM steering capability)

0000= Single PWM waveform generation (with PWM steering capability)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 223

PIC16(L)F1782/3

REGISTER 24-2: PSMCxMDL: PSMC MODULATION CONTROL REGISTER

R/W-0/0

U-0

—

R/W-0/0

PxMDLEN

PxMDLPOL PxMDLBIT

PxMSRC<3:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

bit 6

bit 5

PxMDLEN: PSMC Periodic Modulation Mode Enable bit

1= PSMCx is active when input signal selected by PxMSRC<3:0> is in its active state (see PxMPOL)

0= PSMCx module is always active

PxMDLPOL: PSMC Periodic Modulation Polarity bit

1= PSMCx is active when the PSMCx Modulation source output equals logic ‘0’ (active-low)

0= PSMCx is active when the PSMCx Modulation source output equals logic ‘1’ (active-high)

PxMDLBIT: PSMC Periodic Modulation Software Control bit

PxMDLEN = 1AND PxMSRC<3:0> = 0000

1= PSMCx is active when the PxMDLPOL equals logic ‘0’

0= PSMCx is active when the PxMDLPOL equals logic ‘1’

PxMDLEN = 0OR (PxMDLEN = 1and PxMSRC<3:0> <> ‘0000’)

Does not affect module operation

bit 4

Unimplemented: Read as ‘0’

bit 3-0

PxMSRC<3:0> PSMC Periodic Modulation Source Selection bits

1111= Reserved

1110= Reserved

1101= Reserved

1100= Reserved

1011= Reserved

1010= Reserved

1001= Reserved

1000= PSMCx Modulation Source is PSMCxIN pin

0111= Reserved

0110= PSMCx Modulation Source is CCP2

0101= PSMCx Modulation Source is CCP1

0100= Reserved

0011= PSMCx Modulation Source is sync_C3OUT

0010= PSMCx Modulation Source is sync_C2OUT

0001= PSMCx Modulation Source is sync_C1OUT

0000= PSMCx Modulation Source is PxMDLBIT register bit

DS40001579E-page 224

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 24-3: PSMC1SYNC: PSMC1 SYNCHRONIZATION CONTROL REGISTER

U-0

—

U-0

—

U-0

—

U-0

—

U-0

—

U-0

—

R/W-0/0

P1SYNC<1:0>

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-2

bit 1-0

Unimplemented: Read as ‘0’

P1SYNC<1:0>: PSMC1 Period Synchronization Mode bits

11= Reserved – Do not use

10= PSMC1 is synchronized with the PSMC2 module

01= Reserved – Do not use

00= PSMC1 is synchronized with period event

REGISTER 24-4: PSMC2SYNC: PSMC2 SYNCHRONIZATION CONTROL REGISTER

U-0

—

U-0

—

U-0

—

U-0

—

U-0

—

U-0

—

R/W-0/0

P2SYNC<1:0>

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-2

bit 1-0

Unimplemented: Read as ‘0’

P2SYNC<1:0>: PSMC2 Period Synchronization Mode bits

11= Reserved – Do not use

10= Reserved – Do not use

01= PSMC2 is synchronized with the PSMC1 module

00= PSMC2 is synchronized with period event

 2011-2014 Microchip Technology Inc.

DS40001579E-page 225

PIC16(L)F1782/3

REGISTER 24-5: PSMCxCLK: PSMC CLOCK CONTROL REGISTER

U-0

—

U-0

—

R/W-0/0

U-0

—

U-0

—

R/W-0/0

PxCPRE<1:0>

PxCSRC<1:0>

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-6

bit 5-4

Unimplemented: Read as ‘0’

PxCPRE<1:0>: PSMCx Clock Prescaler Selection bits

11= PSMCx Clock frequency/8

10= PSMCx Clock frequency/4

01= PSMCx Clock frequency/2

00= PSMCx Clock frequency/1

bit 3-2

bit 1-0

Unimplemented: Read as ‘0’

PxCSRC<1:0>: PSMCx Clock Source Selection bits

11= Reserved

10= PSMCxCLK pin

01= 64 MHz clock in from PLL

00= FOSC system clock

REGISTER 24-6: PSMCxOEN: PSMC OUTPUT ENABLE CONTROL REGISTER

U-0

—

U-0

—

R/W-0/0

PxOEF⁽¹⁾

R/W-0/0

PxOEE⁽¹⁾

R/W-0/0

PxOED⁽¹⁾

R/W-0/0

PxOEC⁽¹⁾

R/W-0/0

PxOEB

R/W-0/0

PxOEA

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-6

bit 5-0

Unimplemented: Read as ‘0’

PxOEy: PSMCx Output y Enable bit⁽¹⁾

1= PWM output is active on PSMCx output y pin

0= PWM output is not active, normal port functions in control of pin

Note 1: These bits are not implemented on PSMC2.

DS40001579E-page 226

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 24-7:

PSMCxPOL: PSMC POLARITY CONTROL REGISTER

U-0

R/W-0/0

PxPOLIN

R/W-0/0

PxPOLF⁽¹⁾

R/W-0/0

PxPOLE⁽¹⁾PxPOLD⁽¹⁾

R/W-0/0

PxPOLC⁽¹⁾

R/W-0/0

PxPOLB

R/W-0/0

PxPOLA

—

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7

bit 6

Unimplemented: Read as ‘0’

PxPOLIN: PSMCxIN Polarity bit

1= PSMCxIN input is active-low

0= PSMCxIN input is active-high

bit 5-0

PxPOLy: PSMCx Output y Polarity bit⁽¹⁾

1= PWM PSMCx output y is active-low

0= PWM PSMCx output y is active-high

Note 1: These bits are not implemented on PSMC2.

REGISTER 24-8: PSMCxBLNK: PSMC BLANKING CONTROL REGISTER

U-0

—

U-0

—

R/W-0/0

U-0

—

U-0

—

R/W-0/0

PxFEBM1

PxFEBM0

PxREBM1

PxREBM0

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-6

bit 5-4

Unimplemented: Read as ‘0’

PxFEBM<1:0> PSMC Falling Edge Blanking Mode bits

11= Reserved – do not use

10= Reserved – do not use

01= Immediate blanking

00= No blanking

bit 3-2

bit 1-0

Unimplemented: Read as ‘0’

PxREBM<1:0> PSMC Rising Edge Blanking Mode bits

11= Reserved – do not use

10= Reserved – do not use

01= Immediate blanking

00= No blanking

 2011-2014 Microchip Technology Inc.

DS40001579E-page 227

PIC16(L)F1782/3

REGISTER 24-9: PSMCxREBS: PSMC RISING EDGE BLANKED SOURCE REGISTER

R/W-0/0

U-0

—

U-0

—

U-0

—

R/W-0/0

U-0

—

PxREBSIN

PxREBSC3

PxREBSC2

PxREBSC1

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7

PxREBSIN: PSMCx Rising Edge Event Blanked from PSMCxIN pin

1= PSMCxIN pin cannot cause a rising or falling event for the duration indicated by the PSMCxBLNK register

0= PSMCxIN pin is not blanked

bit 6-4

bit 3

Unimplemented: Read as ‘0’

PxREBSC3: PSMCx Rising Edge Event Blanked from sync_C3OUT

1= sync_C3OUT cannot cause a rising or falling event for the duration indicated by the PSMCxBLNK register

0 = sync_C3OUT is not blanked

bit 2

bit 1

bit 0

PxREBSC2: PSMCx Rising Edge Event Blanked from sync_C2OUT

1= sync_C2OUT cannot cause a rising or falling event for the duration indicated by the PSMCxBLNK register

0 = sync_C2OUT is not blanked

PxREBSC1: PSMCx Rising Edge Event Blanked from sync_C1OUT

1= sync_C1OUT cannot cause a rising or falling event for the duration indicated by the PSMCxBLNK register

0 = sync_C1OUT is not blanked

Unimplemented: Read as ‘0’

REGISTER 24-10: PSMCxFEBS: PSMC FALLING EDGE BLANKED SOURCE REGISTER

R/W-0/0

U-0

—

U-0

—

U-0

—

R/W-0/0

U-0

—

PxFEBSIN

PxFEBSC3

PxFEBSC2

PxFEBSC1

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7

PxFEBSIN: PSMCx Falling Edge Event Blanked from PSMCxIN pin

1= PSMCxIN pin cannot cause a rising or falling event for the duration indicated by the PSMCxBLNK register

0= PSMCxIN pin is not blanked

bit 6-4

bit 3

Unimplemented: Read as ‘0’

PxFEBSC3: PSMCx Falling Edge Event Blanked from sync_C3OUT

1= sync_C3OUT cannot cause a rising or falling event for the duration indicated by the PSMCxBLNK register

0= sync_C3OUT is not blanked

bit 2

bit 1

bit 0

PxFEBSC2: PSMCx Falling Edge Event Blanked from sync_C2OUT

1= sync_C2OUT cannot cause a rising or falling event for the duration indicated by the PSMCxBLNK register

0= sync_C2OUT is not blanked

PxFEBSC1: PSMCx Falling Edge Event Blanked from sync_C1OUT

1= sync_C1OUT cannot cause a rising or falling event for the duration indicated by the PSMCxBLNK register

0= sync_C1OUT is not blanked

Unimplemented: Read as ‘0’

DS40001579E-page 228

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 24-11: PSMCxPHS: PSMC PHASE SOURCE REGISTER⁽¹⁾

R/W-0/0

U-0

—

U-0

—

U-0

—

R/W-0/0

PxPHST

PxPHSIN

PxPHSC3

PxPHSC2

PxPHSC1

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7

PxPHSIN: PSMCx Rising Edge Event occurs on PSMCxIN pin

1= Rising edge event will occur when PSMCxIN pin goes true

0 = PSMCxIN pin will not cause rising edge event

bit 6-4

bit 3

Unimplemented: Read as ‘0’

PxPHSC3: PSMCx Rising Edge Event occurs on sync_C3OUT output

1= Rising edge event will occur when sync_C3OUT output goes true

0 = sync_C3OUT will not cause rising edge event

bit 2

bit 1

bit 0

PxPHSC2: PSMCx Rising Edge Event occurs on sync_C2OUT output

1= Rising edge event will occur when sync_C2OUT output goes true

0 = sync_C2OUT will not cause rising edge event

PxPHSC1: PSMCx Rising Edge Event occurs on sync_C1OUT output

1= Rising edge event will occur when sync_C1OUT output goes true

0 = sync_C1OUT will not cause rising edge event

PxPHST: PSMCx Rising Edge Event occurs on Time Base match

1= Rising edge event will occur when PSMCxTMR = PSMCxPH

0 = Time base will not cause rising edge event

Note 1: Sources are not mutually exclusive: more than one source can cause a rising edge event.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 229

PIC16(L)F1782/3

REGISTER 24-12: PSMCxDCS: PSMC DUTY CYCLE SOURCE REGISTER⁽¹⁾

R/W-0/0

U-0

—

U-0

—

U-0

—

R/W-0/0

PxDCST

PxDCSIN

PxDCSC3

PxDCSC2

PxDCSC1

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7

PxDCSIN: PSMCx Falling Edge Event occurs on PSMCxIN pin

1= Falling edge event will occur when PSMCxIN pin goes true

0= PSMCxIN pin will not cause falling edge event

bit 6-4

bit 3

Unimplemented: Read as ‘0’

PxDCSC3: PSMCx Falling Edge Event occurs on sync_C3OUT output

1= Falling edge event will occur when sync_C3OUT output goes true

0= sync_C3OUT will not cause falling edge event

bit 2

bit 1

bit 0

PxDCSC2: PSMCx Falling Edge Event occurs on sync_C2OUT output

1= Falling edge event will occur when sync_C2OUT output goes true

0= sync_C2OUT will not cause falling edge event

PxDCSC1: PSMCx Falling Edge Event occurs on sync_C1OUT output

1= Falling edge event will occur when sync_C1OUT output goes true

0= sync_C1OUT will not cause falling edge event

PxDCST: PSMCx Falling Edge Event occurs on Time Base match

1= Falling edge event will occur when PSMCxTMR = PSMCxDC

0= Time base will not cause falling edge event

Note 1: Sources are not mutually exclusive: more than one source can cause a falling edge event.

DS40001579E-page 230

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 24-13: PSMCxPRS: PSMC PERIOD SOURCE REGISTER⁽¹⁾

R/W-0/0

U-0

—

U-0

—

U-0

—

R/W-0/0

PxPRST

PxPRSIN

PxPRSC3

PxPRSC2

PxPRSC1

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7

PxPRSIN: PSMCx Period Event occurs on PSMCxIN pin

1= Period event will occur and PSMCxTMR will reset when PSMCxIN pin goes true

0 = PSMCxIN pin will not cause period event

bit 6-4

bit 3

Unimplemented: Read as ‘0’

PxPRSC3: PSMCx Period Event occurs on sync_C3OUT output

1= Period event will occur and PSMCxTMR will reset when sync_C3OUT output goes true

0= sync_C3OUT will not cause period event

bit 2

bit 1

bit 0

PxPRSC2: PSMCx Period Event occurs on sync_C2OUT output

1= Period event will occur and PSMCxTMR will reset when sync_C2OUT output goes true

0= sync_C2OUT will not cause period event

PxPRSC1: PSMCx Period Event occurs on sync_C1OUT output

1= Period event will occur and PSMCxTMR will reset when sync_C1OUT output goes true

0= sync_C1OUT will not cause period event

PxPRST: PSMCx Period Event occurs on Time Base match

1= Period event will occur and PSMCxTMR will reset when PSMCxTMR = PSMCxPR

0= Time base will not cause period event

Note 1: Sources are not mutually exclusive: more than one source can force the period event and reset the

PSMCxTMR.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 231

PIC16(L)F1782/3

REGISTER 24-14: PSMCxASDC: PSMC AUTO-SHUTDOWN CONTROL REGISTER

R/W-0/0

PxASE

R/W-0/0

U-0

—

U-0

—

U-0

—

U-0

—

R/W-0/0

PxASDEN

PxARSEN

PxASDOV

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7

bit 6

PxASE: PWM Auto-Shutdown Event Status bit⁽¹⁾

1= A shutdown event has occurred, PWM outputs are inactive and in their shutdown states

0= PWM outputs are operating normally

PxASDEN: PWM Auto-Shutdown Enable bit

1= Auto-shutdown is enabled. If any of the sources in PSMCxASDS assert a logic ‘1’, then the out-

puts will go into their auto-shutdown state and PSMCxSIF flag will be set.

0= Auto-shutdown is disabled

bit 5

PxARSEN: PWM Auto-Restart Enable bit

1= PWM restarts automatically when the shutdown condition is removed.

0= The PxASE bit must be cleared in firmware to restart PWM after the auto-shutdown condition is

cleared.

bit 4-1

bit 0

Unimplemented: Read as ‘0’

PxASDOV: PWM Auto-Shutdown Override bit

PxASDEN = 1:

1= Force PxASDL[n] levels on the PSMCx[n] pins without causing a PSMCxSIF interrupt

0= Normal PWM and auto-shutdown execution

PxASDEN = 0:

No effect

Note 1: PASE bit may be set in software. When this occurs the functionality is the same as that caused by

hardware.

DS40001579E-page 232

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 24-15: PSMCxASDL: PSMC AUTO-SHUTDOWN OUTPUT LEVEL REGISTER

U-0

—

U-0

—

R/W-0/0

PxASDLF⁽¹⁾PxASDLE⁽¹⁾PxASDLD⁽¹⁾PxASDLC⁽¹⁾

PxASDLB

PxASDLA

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-6

bit 5

Unimplemented: Read as ‘0’

PxASDLF: PSMCx Output F Auto-Shutdown Pin Level bit⁽¹⁾

1= When auto-shutdown is asserted, pin PSMCxF will drive logic ‘1’

0= When auto-shutdown is asserted, pin PSMCxF will drive logic ‘0’

bit 4

bit 3

bit 2

bit 1

bit 0

PxASDLE: PSMCx Output E Auto-Shutdown Pin Level bit⁽¹⁾

1= When auto-shutdown is asserted, pin PSMCxE will drive logic ‘1’

0= When auto-shutdown is asserted, pin PSMCxE will drive logic ‘0’

PxASDLD: PSMCx Output D Auto-Shutdown Pin Level bit⁽¹⁾

1= When auto-shutdown is asserted, pin PSMCxD will drive logic ‘1’

0= When auto-shutdown is asserted, pin PSMCxD will drive logic ‘0’

PxASDLC: PSMCx Output C Auto-Shutdown Pin Level bit⁽¹⁾

1= When auto-shutdown is asserted, pin PSMCxC will drive logic ‘1’

0= When auto-shutdown is asserted, pin PSMCxC will drive logic ‘0’

PxASDLB: PSMCx Output B Auto-Shutdown Pin Level bit

1= When auto-shutdown is asserted, pin PSMCxB will drive logic ‘1’

0= When auto-shutdown is asserted, pin PSMCxB will drive logic ‘0’

PxASDLA: PSMCx Output A Auto-Shutdown Pin Level bit

1= When auto-shutdown is asserted, pin PSMCxA will drive logic ‘1’

0= When auto-shutdown is asserted, pin PSMCxA will drive logic ‘0’

Note 1: These bits are not implemented on PSMC2.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 233

PIC16(L)F1782/3

REGISTER 24-16: PSMCxASDS: PSMC AUTO-SHUTDOWN SOURCE REGISTER

R/W-0/0

U-0

—

U-0

—

U-0

—

R/W-0/0

U-0

—

PxASDSIN

PxASDSC3

PxASDSC2

PxASDSC1

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7

PxASDSIN: Auto-shutdown occurs on PSMCxIN pin

1= Auto-shutdown will occur when PSMCxIN pin goes true

0= PSMCxIN pin will not cause auto-shutdown

bit 6-4

bit 3

Unimplemented: Read as ‘0’

PxASDSC3: Auto-shutdown occurs on sync_C3OUT output

1= Auto-shutdown will occur when sync_C3OUT output goes true

0= sync_C3OUT will not cause auto-shutdown

bit 2

bit 1

bit 0

PxASDSC2: Auto-shutdown occurs on sync_C2OUT output

1= Auto-shutdown will occur when sync_C2OUT output goes true

0= sync_C2OUT will not cause auto-shutdown

PxASDSC1: Auto-shutdown occurs on sync_C1OUT output

1= Auto-shutdown will occur when sync_C1OU output goes true

0= sync_C1OU will not cause auto-shutdown

Unimplemented: Read as ‘0’

DS40001579E-page 234

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 24-17: PSMCxTMRL: PSMC TIME BASE COUNTER LOW REGISTER

R/W-0/0

bit 0

PSMCxTMRL<7:0>

bit 7

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7-0

PSMCxTMRL<7:0>: 16-bit PSMCx Time Base Counter Least Significant bits

= PSMCxTMR<7:0>

REGISTER 24-18: PSMCxTMRH: PSMC TIME BASE COUNTER HIGH REGISTER

R/W-0/0

R/W-1/1

PSMCxTMRH<7:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7-0

PSMCxTMRH<7:0>: 16-bit PSMCx Time Base Counter Most Significant bits

= PSMCxTMR<15:8>

 2011-2014 Microchip Technology Inc.

DS40001579E-page 235

PIC16(L)F1782/3

REGISTER 24-19: PSMCxPHL: PSMC PHASE COUNT LOW BYTE REGISTER

R/W-0/0

PSMCxPHL<7:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

PSMCxPHL<7:0>: 16-bit Phase Count Least Significant bits

PSMCxPH<7:0>

=

REGISTER 24-20: PSMCxPHH: PSMC PHASE COUNT HIGH BYTE REGISTER

R/W-0/0

PSMCxPHH<7:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7-0

PSMCxPHH<7:0>: 16-bit Phase Count Most Significant bits

PSMCxPH<15:8>

=

DS40001579E-page 236

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 24-21: PSMCxDCL: PSMC DUTY CYCLE COUNT LOW BYTE REGISTER

R/W-0/0

PSMCxDCL<7:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7-0

PSMCxDCL<7:0>: 16-bit Duty Cycle Count Least Significant bits

PSMCxDC<7:0>

=

REGISTER 24-22: PSMCxDCH: PSMC DUTY CYCLE COUNT HIGH REGISTER

R/W-0/0

PSMCxDCH<7:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7-0

PSMCxDCH<7:0>: 16-bit Duty Cycle Count Most Significant bits

PSMCxDC<15:8>

=

 2011-2014 Microchip Technology Inc.

DS40001579E-page 237

PIC16(L)F1782/3

REGISTER 24-23: PSMCxPRL: PSMC PERIOD COUNT LOW BYTE REGISTER

R/W-0/0

PSMCxPRL<7:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-0

PSMCxPRL<7:0>: 16-bit Period Time Least Significant bits

PSMCxPR<7:0>

=

REGISTER 24-24: PSMCxPRH: PSMC PERIOD COUNT HIGH BYTE REGISTER

R/W-0/0

PSMCxPRH<7:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7-0

PSMCxPRH<7:0>: 16-bit Period Time Most Significant bits

PSMCxPR<15:8>

=

DS40001579E-page 238

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 24-25: PSMCxDBR: PSMC RISING EDGE DEAD-BAND TIME REGISTER

R/W-0/0

PSMCxDBR<7:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7-0

PSMCxDBR<7:0>: Rising Edge Dead-Band Time bits

= Unsigned number of PSMCx psmc_clk clock periods in rising edge dead band

REGISTER 24-26: PSMCxDBF: PSMC FALLING EDGE DEAD-BAND TIME REGISTER

R/W-0/0

PSMCxDBF<7:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7-0

PSMCxDBF<7:0>: Falling Edge Dead-Band Time bits

Unsigned number of PSMCx psmc_clk clock periods in falling edge dead band

=

REGISTER 24-27: PSMCxFFA: PSMC FRACTIONAL FREQUENCY ADJUST REGISTER

U-0

—

U-0

—

U-0

—

U-0

—

R/W-0/0

PSMCxFFA<3:0>

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-4

bit 3-0

Unimplemented: Read as ‘0’

PSMCxFFA<3:0>: Fractional Frequency Adjustment bits

=

Unsigned number of fractional PSMCx psmc_clk clock periods to add to each period event time.

The fractional time period = 1/(16*psmc_clk)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 239

PIC16(L)F1782/3

REGISTER 24-28: PSMCxBLKR: PSMC RISING EDGE BLANKING TIME REGISTER

R/W-0/0

PSMCxBLKR<7:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7-0

PSMCxBLKR<7:0>: Rising Edge Blanking Time bits

Unsigned number of PSMCx psmc_clk clock periods in rising edge blanking

=

REGISTER 24-29: PSMCxBLKF: PSMC FALLING EDGE BLANKING TIME REGISTER

R/W-0/0

PSMCxBLKF<7:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

bit 7-0

PSMCxBLKF<7:0>: Falling Edge Blanking Time bits

Unsigned number of PSMCx psmc_clk clock periods in falling edge blanking

=

DS40001579E-page 240

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 24-30: PSMCxSTR0: PSMC STEERING CONTROL REGISTER 0

U-0

—

U-0

—

R/W-0/0

PxSTRF⁽²⁾

R/W-0/0

PxSTRE⁽²⁾PxSTRD⁽²⁾

R/W-0/0

PxSTRC⁽²⁾

R/W-0/0

PxSTRB

R/W-1/1

PxSTRA

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7-6

bit 5

Unimplemented: Read as ‘0’

PxSTRF: PWM Steering PSMCxF Output Enable bit⁽²⁾

If PxMODE<3:0> = 0000 (Single-phase PWM):

1= Single PWM output is active on pin PSMCxF

0= Single PWM output is not active on pin PSMCxF. PWM drive is in inactive state

If PxMODE<3:0> = 0001 (Complementary Single-phase PWM):

1= Complementary PWM output is active on pin PSMCxF

0= Complementary PWM output is not active on pin PSMCxOUT5. PWM drive is in inactive state

IF PxMODE<3:0> = 1100 (3-phase Steering):⁽¹⁾

1= PSMCxD and PSMCxE are high. PSMCxA, PMSCxB, PSMCxC and PMSCxF are low.

0= 3-phase output combination is not active

bit 4

PxSTRE: PWM Steering PSMCxE Output Enable bit⁽²⁾

If PxMODE<3:0> = 000x (single-phase PWM or Complementary PWM):

1= Single PWM output is active on pin PSMCxE

0= Single PWM output is not active on pin PSMCxE. PWM drive is in inactive state

IF PxMODE<3:0> = 1100 (3-phase Steering):⁽¹⁾

1= PSMCxB and PSMCxE are high. PSMCxA, PMSCxC, PSMCxD and PMSCxF are low.

0= 3-phase output combination is not active

bit 3

PxSTRD: PWM Steering PSMCxD Output Enable bit⁽²⁾

If PxMODE<3:0> = 0000 (Single-phase PWM):

1= Single PWM output is active on pin PSMCxD

0= Single PWM output is not active on pin PSMCxD. PWM drive is in inactive state

If PxMODE<3:0> = 0001 (Complementary single-phase PWM):

1= Complementary PWM output is active on pin PSMCxD

0= Complementary PWM output is not active on pin PSMCxD. PWM drive is in inactive state

IF PxMODE<3:0> = 1100 (3-phase Steering):⁽¹⁾

1= PSMCxB and PSMCxC are high. PSMCxA, PMSCxD, PSMCxE and PMSCxF are low.

0= 3-phase output combination is not active

bit 2

PxSTRC: PWM Steering PSMCxC Output Enable bit⁽²⁾

If PxMODE<3:0> = 000x (Single-phase PWM or Complementary PWM):

1= Single PWM output is active on pin PSMCxC

0= Single PWM output is not active on pin PSMCxC. PWM drive is in inactive state

IF PxMODE<3:0> = 1100 (3-phase Steering):⁽¹⁾

1= PSMCxC and PSMCxF are high. PSMCxA, PMSCxB, PSMCxD and PMSCxE are low.

0= 3-phase output combination is not active

 2011-2014 Microchip Technology Inc.

DS40001579E-page 241

PIC16(L)F1782/3

REGISTER 24-30: PSMCxSTR0: PSMC STEERING CONTROL REGISTER 0

bit 1

PxSTRB: PWM Steering PSMCxB Output Enable bit

If PxMODE<3:0> = 0000 (Single-phase PWM):

1= Single PWM output is active on pin PSMCxOUT1

0= Single PWM output is not active on pin PSMCxOUT1. PWM drive is in inactive state

If PxMODE<3:0> = 0001 (Complementary Single-phase PWM):

1= Complementary PWM output is active on pin PSMCxB

0= Complementary PWM output is not active on pin PSMCxB. PWM drive is in inactive state

IF PxMODE<3:0> = 1100 (3-phase Steering):⁽¹⁾

1= PSMCxA and PSMCxF are high. PSMCxB, PMSCxC, PSMCxD and PMSCxE are low.

0= 3-phase output combination is not active

bit 0

PxSTRA: PWM Steering PSMCxA Output Enable bit

If PxMODE<3:0> = 000x (Single-phase PWM or Complementary PWM):

1= Single PWM output is active on pin PSMCxA

0= Single PWM output is not active on pin PSMCxA. PWM drive is in inactive state

IF PxMODE<3:0> = 1100 (3-phase Steering):⁽¹⁾

1= PSMCxA and PSMCxD are high. PSMCxB, PMSCxC, PSMCxE and PMSCxF are low.

0= 3-phase output combination is not active

Note 1: In 3-phase Steering mode, only one PSTRx bit should be set at a time. If more than one is set, then the

lowest bit number steering combination has precedence.

2: These bits are not implemented on PSMC2.

DS40001579E-page 242

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 24-31: PSMCxSTR1: PSMC STEERING CONTROL REGISTER 1

R/W-0/0

U-0

—

U-0

—

U-0

—

U-0

—

U-0

—

R/W-0/0

PxSSYNC

PxLSMEN

PxHSMEN

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7

PxSSYNC: PWM Steering Synchronization bit

1= PWM outputs are updated on period boundary

0= PWM outputs are updated immediately

bit 6-2

bit 1

Unimplemented: Read as ‘0’

PxLSMEN: 3-Phase Steering Low Side Modulation Enable bit

PxMODE = 1100:

1= Low side driver PSMCxB, PSMCxD and PSMCxF outputs are modulated according to

PSMCxMDL when the output is high and driven low without modulation when the output is low.

0= PSMCxB, PSMCxD, and PSMCxF outputs are driven high and low by PSMCxSTR0 control

without modulation.

PxMODE <> 1100:

No effect on output

bit 0

PxHSMEN: 3-Phase Steering High Side Modulation Enable bit

PxMODE = 1100:

1= High side driver PSMCxA, PSMCxC and PSMCxE outputs are modulated according to

PSMCxMDL when the output is high and driven low without modulation when the output is low.

0= PSMCxA, PSMCxC and PSMCxE outputs are driven high and low by PSMCxSTR0 control

without modulation.

PxMODE <> 1100:

No effect on output

 2011-2014 Microchip Technology Inc.

DS40001579E-page 243

PIC16(L)F1782/3

REGISTER 24-32: PSMCxINT: PSMC TIME BASE INTERRUPT CONTROL REGISTER

R/W-0/0

PxTOVIE

PxTPHIE

PxTDCIE

PxTPRIE

PxTOVIF

PxTPHIF

PxTDCIF

PxTPRIF

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

bit 6

bit 5

bit 4

bit 3

bit 2

bit 1

bit 0

PxTOVIE: PSMC Time Base Counter Overflow Interrupt Enable bit

1= Time base counter overflow interrupts are enabled

0= Time base counter overflow interrupts are disabled

PxTPHIE: PSMC Time Base Phase Interrupt Enable bit

1= Time base phase match interrupts are enabled

0= Time base phase match interrupts are disabled

PxTDCIE: PSMC Time Base Duty Cycle Interrupt Enable bit

1= Time base duty cycle match interrupts are enabled

0= Time base duty cycle match interrupts are disabled

PxTPRIE: PSMC Time Base Period Interrupt Enable bit

1= Time base period match interrupts are enabled

0= Time base period match Interrupts are disabled

PxTOVIF: PSMC Time Base Counter Overflow Interrupt Flag bit

1= The 16-bit PSMCxTMR has overflowed from FFFFh to 0000h

0= The 16-bit PSMCxTMR counter has not overflowed

PxTPHIF: PSMC Time Base Phase Interrupt Flag bit

1= The 16-bit PSMCxTMR counter has matched PSMCxPH<15:0>

0= The 16-bit PSMCxTMR counter has not matched PSMCxPH<15:0>

PxTDCIF: PSMC Time Base Duty Cycle Interrupt Flag bit

1= The 16-bit PSMCxTMR counter has matched PSMCxDC<15:0>

0= The 16-bit PSMCxTMR counter has not matched PSMCxDC<15:0>

PxTPRIF: PSMC Time Base Period Interrupt Flag bit

1= The 16-bit PSMCxTMR counter has matched PSMCxPR<15:0>

0= The 16-bit PSMCxTMR counter has not matched PSMCxPR<15:0>

DS40001579E-page 244

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 24-5: SUMMARY OF REGISTERS ASSOCIATED WITH PSMC

Register

on Page

Name

INTCON

Bit7

Bit6

Bit5

Bit4

BIt3

Bit2

Bit1

Bit0

GIE

ODC7

—

PEIE

TMR0IE

ODC5

INTE

IOCIE

ODC3

—

TMR0IF

ODC2

—

INTF

IOCIF

ODC0

79

ODCONC

ODC6

ODC4

ODC1

126

82

PIE4

—

PSMC2TIE PSMC1TIE

PSMC2SIE PSMC1SIE

PSMC2SIF PSMC1SIF

PIR4

—

PxASDEN

—

PSMC2TIF

PxARSEN

PSMC1TIF

—

85

PSMCxASDC

PSMCxASDL

PSMCxASDS

PSMCxBLKF

PSMCxBLKR

PSMCxBLNK

PSMCxCLK

PSMCxCON

PSMCxDBF

PSMCxDBR

PSMCxDCH

PSMCxDCL

PSMCxDCS

PSMCxFEBS

PSMCxFFA

PSMCxINT

PSMCxMDL

PSMCxOEN

PSMCxPHH

PSMCxPHL

PSMCxPHS

PSMCxPOL

PSMCxPRH

PSMCxPRL

PSMCxPRS

PSMCxREBS

PSMCxSTR0

PSMCxSTR1

PSMCxSYNC

PSMCxTMRH

PSMCxTMRL

SLRCONC

TRISC

PxASE

—

PxASDOV

PxASDLA

—

232

233

234

240

227

226

223

239

237

230

228

239

244

224

226

236

229

227

238

231

228

241

243

225

235

126

125

(1)

PxASDLF

—

PxASDLE

—

PxASDLD

PxASDLC

PxASDLB

PxASDSIN

—

PxASDSC3 PxASDSC2 PxASDSC1

PSMCxBLKF<7:0>

PSMCxBLKR<7:0>

—

PxFEBM1

PxFEBM0

—

PxREBM1

PxREBM0

PxCPRE<1:0>

PxCSRC<1:0>

PSMCxEN

PSMCxLD

PxDBFE

PxDBRE

PxMODE<3:0>

PSMCxDBF<7:0>

PSMCxDBR<7:0>

PSMCxDC<15:8>

PSMCxDC<7:0>

PxDCSIN

PxFEBSIN

—

PxDCSC3

PxDCSC2

PxDCSC1

PxDCST

—

PxFEBSC3 PxFEBSC2 PxFEBSC1

PSMCxFFA<3:0>

—

PxTOVIE

PxTPHIE

PxTDCIE

PxTPRIE

—

PxTOVIF

PxTPHIF

PxTDCIF

PxTPRIF

PxOEA

PxMDLEN PxMDLPOL PxMDLBIT

PxMSRC<3:0>

(1)

—

PxOEF

PxOEE

PxOED

PxOEC

PxOEB

PSMCxPH<15:8>

PSMCxPH<7:0>

PxPHSIN

—

PxPHSC3

PxPHSC2

PxPHSC1

PxPOLB

PxPHST

PxPOLA

(1)

PxPOLIN

PxPOLF

PxPOLE

PxPOLD

PxPOLC

PSMCxPR<15:8>

PSMCxPR<7:0>

PxPRSIN

PxREBSIN

—

PxPRSC3

PxPRSC2

PxPRSC1

PxPRST

—

PxREBSC3 PxREBSC2 PxREBSC1

(1)

PxSTRF

—

PxSTRE

—

PxSTRD

PxSTRC

PxSTRB

PxSTRA

PxHSMEN

PxSSYNC

—

PxLSMEN

—

PxSYNC<1:0>

PSMCxTMR<15:8>

PSMCxTMR<7:0>

SLRC7

SLRC6

TRISC6

SLRC5

SLRC4

SLRC3

TRISC3

SLCR2

TRISC2

SRC1

SLRC0

TRISC7

TRISC5

TRISC4

TRISC1

TRISC0

Legend:

Note 1:

— = unimplemented location, read as ‘0’. Shaded cells are not used by PSMC module.

Unimplemented in PSMC2.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 245

PIC16(L)F1782/3

25.0 CAPTURE/COMPARE/PWM

MODULES

The Capture/Compare/PWM module is a peripheral

that allows the user to time and control different events,

and to generate Pulse-Width Modulation (PWM)

signals. In Capture mode, the peripheral allows the

timing of the duration of an event. The Compare mode

allows the user to trigger an external event when a

predetermined amount of time has expired. The PWM

mode can generate Pulse-Width Modulated signals of

varying frequency and duty cycle.

This family of devices contains two standard

Capture/Compare/PWM modules (CCP1 and CCP2).

The Capture and Compare functions are identical for all

CCP modules.

Note 1: In devices with more than one CCP

module, it is very important to pay close

attention to the register names used. A

number placed after the module acronym

is used to distinguish between separate

modules. For example, the CCP1CON

and CCP2CON control the same

operational aspects of two completely

different CCP modules.

2: Throughout

this

section,

generic

references to a CCP module in any of its

operating modes may be interpreted as

being equally applicable to CCPx module.

Register names, module signals, I/O pins,

and bit names may use the generic

designator ‘x’ to indicate the use of a

numeral to distinguish a particular module,

when required.

DS40001579E-page 246

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

25.1.2

TIMER1 MODE RESOURCE

25.1 Capture Mode

Timer1 must be running in Timer mode or Synchronized

Counter mode for the CCP module to use the capture

feature. In Asynchronous Counter mode, the capture

operation may not work.

The Capture mode function described in this section is

available and identical for all CCP modules.

Capture mode makes use of the 16-bit Timer1

resource. When an event occurs on the CCPx pin, the

16-bit CCPRxH:CCPRxL register pair captures and

stores the 16-bit value of the TMR1H:TMR1L register

pair, respectively. An event is defined as one of the

following and is configured by the CCPxM<3:0> bits of

the CCPxCON register:

See Section 22.0 “Timer1 Module with Gate

Control” for more information on configuring Timer1.

25.1.3

SOFTWARE INTERRUPT MODE

When the Capture mode is changed, a false capture

interrupt may be generated. The user should keep the

CCPxIE interrupt enable bit of the PIEx register clear to

avoid false interrupts. Additionally, the user should

clear the CCPxIF interrupt flag bit of the PIRx register

following any change in Operating mode.

• Every falling edge

• Every rising edge

• Every 4th rising edge

• Every 16th rising edge

When a capture is made, the Interrupt Request Flag bit

CCPxIF of the PIRx register is set. The interrupt flag

must be cleared in software. If another capture occurs

before the value in the CCPRxH, CCPRxL register pair

is read, the old captured value is overwritten by the new

captured value.

Note:

Clocking Timer1 from the system clock

(FOSC) should not be used in Capture

mode. In order for Capture mode to

recognize the trigger event on the CCPx

pin, Timer1 must be clocked from the

instruction clock (FOSC/4) or from an

external clock source.

Figure 25-1 shows a simplified diagram of the capture

operation.

25.1.4

CCP PRESCALER

25.1.1

CCP PIN CONFIGURATION

There are four prescaler settings specified by the

CCPxM<3:0> bits of the CCPxCON register. Whenever

the CCP module is turned off, or the CCP module is not

in Capture mode, the prescaler counter is cleared. Any

Reset will clear the prescaler counter.

In Capture mode, the CCPx pin should be configured

as an input by setting the associated TRIS control bit.

Also, the CCP2 pin function can be moved to

alternative pins using the APFCON register. Refer to

Section 13.1 “Alternate Pin Function” for more

details.

Switching from one capture prescaler to another does not

clear the prescaler and may generate a false interrupt. To

avoid this unexpected operation, turn the module off by

clearing the CCPxCON register before changing the

prescaler. Equation 25-1 demonstrates the code to

perform this function.

Note:

If the CCPx pin is configured as an output,

a write to the port can cause a capture

condition.

FIGURE 25-1:

CAPTURE MODE

OPERATION BLOCK

DIAGRAM

EXAMPLE 25-1:

CHANGING BETWEEN

CAPTURE PRESCALERS

BANKSELCCPxCON

;Set Bank bits to point

;to CCPxCON

;Turn CCP module off

Set Flag bit CCPxIF

(PIRx register)

Prescaler

 1, 4, 16

CLRF

CCPxCON

MOVLW

NEW_CAPT_PS;Load the W reg with

;the new prescaler

CCPx

CCPRxH

CCPRxL

;move value and CCP ON

Capture

Enable

MOVWF

CCPxCON

;Load CCPxCON with this

;value

and

Edge Detect

TMR1H

TMR1L

CCPxM<3:0>

System Clock (FOSC)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 247

PIC16(L)F1782/3

25.1.5

CAPTURE DURING SLEEP

Capture mode depends upon the Timer1 module for

proper operation. There are two options for driving the

Timer1 module in Capture mode. It can be driven by the

instruction clock (FOSC/4), or by an external clock source.

When Timer1 is clocked by FOSC/4, Timer1 will not

increment during Sleep. When the device wakes from

Sleep, Timer1 will continue from its previous state.

Capture mode will operate during Sleep when Timer1

is clocked by an external clock source.

25.1.6

ALTERNATE PIN LOCATIONS

This module incorporates I/O pins that can be moved to

other locations with the use of the alternate pin function

register APFCON. To determine which pins can be

moved and what their default locations are upon a

Reset, see Section 13.1 “Alternate Pin Function” for

more information.

DS40001579E-page 248

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

See Section 22.0 “Timer1 Module with Gate Control”

for more information on configuring Timer1.

25.2 Compare Mode

The Compare mode function described in this section

is available and identical for all CCP modules.

Note:

Clocking Timer1 from the system clock

(FOSC) should not be used in Compare

mode. In order for Compare mode to

recognize the trigger event on the CCPx

pin, TImer1 must be clocked from the

instruction clock (FOSC/4) or from an

external clock source.

Compare mode makes use of the 16-bit Timer1

resource. The 16-bit value of the CCPRxH:CCPRxL

register pair is constantly compared against the 16-bit

value of the TMR1H:TMR1L register pair. When a

match occurs, one of the following events can occur:

• Toggle the CCPx output

25.2.3

SOFTWARE INTERRUPT MODE

• Set the CCPx output

• Clear the CCPx output

When Generate Software Interrupt mode is chosen

(CCPxM<3:0> = 1010), the CCPx module does not

assert control of the CCPx pin (see the CCPxCON

register).

• Generate an Auto-conversion Trigger

• Generate a Software Interrupt

The action on the pin is based on the value of the

CCPxM<3:0> control bits of the CCPxCON register. At

the same time, the interrupt flag CCPxIF bit is set.

25.2.4

AUTO-CONVERSION TRIGGER

When Auto-conversion Trigger mode is chosen

(CCPxM<3:0> = 1011), the CCPx module does the

following:

All Compare modes can generate an interrupt.

Figure 25-2 shows a simplified diagram of the compare

operation.

• Resets Timer1

• Starts an ADC conversion if ADC is enabled

FIGURE 25-2:

COMPARE MODE

OPERATION BLOCK

DIAGRAM

The CCPx module does not assert control of the CCPx

pin in this mode.

The Auto-conversion Trigger output of the CCP occurs

immediately upon a match between the TMR1H,

TMR1L register pair and the CCPRxH, CCPRxL

register pair. The TMR1H, TMR1L register pair is not

reset until the next rising edge of the Timer1 clock. The

Auto-conversion Trigger output starts an ADC conver-

sion (if the ADC module is enabled). This allows the

CCPRxH, CCPRxL register pair to effectively provide a

16-bit programmable period register for Timer1.

CCPxM<3:0>

Mode Select

Set CCPxIF Interrupt Flag

(PIRx)

4

CCPx

CCPRxH CCPRxL

Comparator

Q

S

R

Output

Logic

Match

TMR1H TMR1L

Refer to Section 17.2.5 “Auto-Conversion Trigger”

for more information.

TRIS

Output Enable

Auto-conversion Trigger

Note 1: The Auto-conversion Trigger from the

CCP module does not set interrupt flag

bit TMR1IF of the PIR1 register.

25.2.1

CCPX PIN CONFIGURATION

2: Removing the match condition by

changing the contents of the CCPRxH

and CCPRxL register pair, between the

The user must configure the CCPx pin as an output by

clearing the associated TRIS bit.

clock

edge that

generates

the

The CCP2 pin function can be moved to alternate pins

using the APFCON register (Register 13-1). Refer to

Section 13.1 “Alternate Pin Function” for more

details.

Auto-conversion Trigger and the clock

edge that generates the Timer1 Reset,

will preclude the Reset from occurring.

Note:

Clearing the CCPxCON register will force

the CCPx compare output latch to the

default low level. This is not the PORT I/O

data latch.

25.2.5

COMPARE DURING SLEEP

The Compare mode is dependent upon the system

clock (FOSC) for proper operation. Since FOSC is shut

down during Sleep mode, the Compare mode will not

function properly during Sleep.

25.2.2

TIMER1 MODE RESOURCE

In Compare mode, Timer1 must be running in either

Timer mode or Synchronized Counter mode. The

compare operation may not work in Asynchronous

Counter mode.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 249

PIC16(L)F1782/3

25.2.6

ALTERNATE PIN LOCATIONS

This module incorporates I/O pins that can be moved to

other locations with the use of the alternate pin function

register APFCON. To determine which pins can be

moved and what their default locations are upon a

Reset, see Section 13.1 “Alternate Pin Function”for

more information.

DS40001579E-page 250

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 25-3:

CCP PWM OUTPUT SIGNAL

25.3 PWM Overview

Pulse-Width Modulation (PWM) is a scheme that

provides power to a load by switching quickly between

fully on and fully off states. The PWM signal resembles

a square wave where the high portion of the signal is

considered the on state and the low portion of the signal

is considered the off state. The high portion, also known

as the pulse width, can vary in time and is defined in

steps. A larger number of steps applied, which

lengthens the pulse width, also supplies more power to

the load. Lowering the number of steps applied, which

shortens the pulse width, supplies less power. The

PWM period is defined as the duration of one complete

cycle or the total amount of on and off time combined.

Period

Pulse Width

TMR2 = PR2

TMR2 = CCPRxH:CCPxCON<5:4>

TMR2 = 0

FIGURE 25-4:

SIMPLIFIED PWM BLOCK

DIAGRAM

CCP1CON<5:4>

Duty Cycle Registers

CCPR1L

PWM resolution defines the maximum number of steps

that can be present in a single PWM period. A higher

resolution allows for more precise control of the pulse

width time and in turn the power that is applied to the

load.

To PSMC module

CCP1

CCPR1H⁽²⁾(Slave)

Comparator

The term duty cycle describes the proportion of the on

time to the off time and is expressed in percentages,

where 0% is fully off and 100% is fully on. A lower duty

cycle corresponds to less power applied and a higher

duty cycle corresponds to more power applied.

R

S

Q

(1)

TMR2

TRIS

Figure 25-3 shows a typical waveform of the PWM

signal.

Comparator

PR2

Clear Timer,

toggle CCP1 pin and

latch duty cycle

25.3.1

STANDARD PWM OPERATION

The standard PWM function described in this section is

available and identical for all CCP modules.

Note 1: The 8-bit timer TMR2 register is

concatenated with the 2-bit internal system

The standard PWM mode generates a Pulse-Width

Modulation (PWM) signal on the CCPx pin with up to 10

bits of resolution. The period, duty cycle, and resolution

are controlled by the following registers:

clock (FOSC), or 2 bits of the prescaler, to

create the 10-bit time base.

2: In PWM mode, CCPR1H is a read-only

register.

• PR2 registers

• T2CON registers

• CCPRxL registers

• CCPxCON registers

Figure 25-4 shows a simplified block diagram of PWM

operation.

Note 1: The corresponding TRIS bit must be

cleared to enable the PWM output on the

CCPx pin.

2: Clearing the CCPxCON register will

relinquish control of the CCPx pin.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 251

PIC16(L)F1782/3

25.3.2

SETUP FOR PWM OPERATION

25.3.4

PWM PERIOD

The following steps should be taken when configuring

the CCP module for standard PWM operation:

The PWM period is specified by the PR2 register of

Timer2. The PWM period can be calculated using the

formula of Equation 25-1.

1. Disable the CCPx pin output driver by setting the

associated TRIS bit.

EQUATION 25-1: PWM PERIOD

2. Load the PR2 register with the PWM period

value.

PWM Period = PR2 + 1  4  TOSC 

3. Configure the CCP module for the PWM mode

by loading the CCPxCON register with the

appropriate values.

(TMR2 Prescale Value)

Note 1: TOSC = 1/FOSC

4. Load the CCPRxL register and the DCxBx bits

of the CCPxCON register, with the PWM duty

cycle value.

When TMR2 is equal to PR2, the following three events

occur on the next increment cycle:

5. Configure and start Timer2:

• TMR2 is cleared

• Clear the TMR2IF interrupt flag bit of the

PIRx register. See Note below.

• The CCPx pin is set. (Exception: If the PWM duty

cycle = 0%, the pin will not be set.)

• Configure the T2CKPS bits of the T2CON

register with the Timer prescale value.

• The PWM duty cycle is latched from CCPRxL into

CCPRxH.

• Enable the Timer by setting the TMR2ON

bit of the T2CON register.

Note:

The Timer postscaler (see Section 23.1

“Timer2 Operation”) is not used in the

determination of the PWM frequency.

6. Enable PWM output pin:

• Wait until the Timer overflows and the

TMR2IF bit of the PIR1 register is set. See

Note below.

25.3.5

PWM DUTY CYCLE

• Enable the CCPx pin output driver by

clearing the associated TRIS bit.

The PWM duty cycle is specified by writing a 10-bit

value to multiple registers: CCPRxL register and

DCxB<1:0> bits of the CCPxCON register. The

CCPRxL contains the eight MSbs and the DCxB<1:0>

bits of the CCPxCON register contain the two LSbs.

CCPRxL and DCxB<1:0> bits of the CCPxCON

register can be written to at any time. The duty cycle

value is not latched into CCPRxH until after the period

completes (i.e., a match between PR2 and TMR2

registers occurs). While using the PWM, the CCPRxH

register is read-only.

Note:

In order to send a complete duty cycle and

period on the first PWM output, the above

steps must be included in the setup

sequence. If it is not critical to start with a

complete PWM signal on the first output,

then step 6 may be ignored.

25.3.3

TIMER2 TIMER RESOURCE

Equation 25-2 is used to calculate the PWM pulse

width.

The PWM standard mode makes use of the 8-bit

Timer2 timer resources to specify the PWM period.

Equation 25-3 is used to calculate the PWM duty cycle

ratio.

EQUATION 25-2: PULSE WIDTH

Pulse Width = CCPRxL:CCPxCON<5:4> 

TOSC  (TMR2 Prescale Value)

EQUATION 25-3: DUTY CYCLE RATIO

CCPRxL:CCPxCON<5:4>

Duty Cycle Ratio = ----------------------------------------------------------------------

4PR2 + 1

The CCPRxH register and a 2-bit internal latch are

used to double buffer the PWM duty cycle. This double

buffering is essential for glitchless PWM operation.

DS40001579E-page 252

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

The 8-bit timer TMR2 register is concatenated with

either the 2-bit internal system clock (FOSC), or 2 bits of

the prescaler, to create the 10-bit time base. The system

clock is used if the Timer2 prescaler is set to 1:1.

The maximum PWM resolution is 10 bits when PR2 is

255. The resolution is a function of the PR2 register

value as shown by Equation 25-4.

EQUATION 25-4: PWM RESOLUTION

When the 10-bit time base matches the CCPRxH and

2-bit latch, then the CCPx pin is cleared (see

Figure 25-4).

log4PR2 + 1

Resolution = ----------------------------------------- bits

log2

25.3.6

PWM RESOLUTION

The resolution determines the number of available duty

cycles for a given period. For example, a 10-bit resolution

will result in 1024 discrete duty cycles, whereas an 8-bit

resolution will result in 256 discrete duty cycles.

Note:

If the pulse width value is greater than the

period the assigned PWM pin(s) will

remain unchanged.

TABLE 25-1: EXAMPLE PWM FREQUENCIES AND RESOLUTIONS (FOSC = 20 MHz)

PWM Frequency

Timer Prescale

1.22 kHz

4.88 kHz

19.53 kHz

78.12 kHz

156.3 kHz

208.3 kHz

16

0xFF

10

4

1

0x3F

8

1

0x1F

7

1

PR2 Value

0xFF

10

0xFF

10

0x17

6.6

Maximum Resolution (bits)

TABLE 25-2: EXAMPLE PWM FREQUENCIES AND RESOLUTIONS (FOSC = 8 MHz)

PWM Frequency

Timer Prescale

1.22 kHz

4.90 kHz

19.61 kHz

76.92 kHz

153.85 kHz 200.0 kHz

16

0x65

8

4

0x65

8

1

0x65

8

1

0x19

6

1

0x0C

5

1

0x09

5

PR2 Value

Maximum Resolution (bits)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 253

PIC16(L)F1782/3

25.3.7

OPERATION IN SLEEP MODE

In Sleep mode, the TMR2 register will not increment

and the state of the module will not change. If the CCPx

pin is driving a value, it will continue to drive that value.

When the device wakes up, TMR2 will continue from its

previous state.

25.3.8

CHANGES IN SYSTEM CLOCK

FREQUENCY

The PWM frequency is derived from the system clock

frequency. Any changes in the system clock frequency

will result in changes to the PWM frequency. See

Section 6.0 “Oscillator Module (with Fail-Safe

Clock Monitor)” for additional details.

25.3.9

EFFECTS OF RESET

Any Reset will force all ports to Input mode and the

CCP registers to their Reset states.

TABLE 25-3: SUMMARY OF REGISTERS ASSOCIATED WITH STANDARD PWM

Registeron

Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

APFCON

CCP1CON

CCP2CON

INTCON

PIE1

C2OUTSEL

CC1PSEL

—

SDOSEL

SCKSEL

SDISEL

TXSEL

RXSEL

CCP2SEL

111

255

79

—

DC1B<1:0>

DC2B<1:0>

CCP1M<3:0>

CCP2M<3:0>

—

GIE

PEIE

ADIE

TMR0IE

INTE

TXIE

IOCIE

TMR0IF

INTF

IOCIF

TMR1GIE

RCIE

SSP1IE

CCP1IE

TMR2IE

TMR1IE

79

81

PIE2

OSEIE

TMR1GIF

OSFIF

C2IE

ADIF

C2IF

C1IE

RCIF

C1IF

EEIE

TXIF

EEIF

BCL1IE

SSP1IF

BCL1IF

—

CCP1IF

—

C3IE

TMR2IF

C3IF

CCP2IE

TMR1IF

CCP2IF

PIR1

PIR2

PR2

83

84

Timer2 Period Register

—

186*

T2CON

T2OUTPS<3:0>

TMR2ON

TRISA2

T2CKPS<1:0>

188

186

114

TMR2

TRISA

Timer2 Module Register

TRISA7

TRISA6

TRISA5

TRISA4

TRISA3

TRISA1

TRISA0

Legend: — = Unimplemented location, read as ‘0’. Shaded cells are not used by the PWM.

Page provides register information.

*

DS40001579E-page 254

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

25.4 Register Definitions: CCP Control

REGISTER 25-1: CCPxCON: CCPx CONTROL REGISTER

R/W-0/0

U-0

—

U-0

—

R/W-0/0

DCxB<1:0>

CCPxM<3:0>

bit 0

bit 7

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Reset

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-6

bit 5-4

Unimplemented: Read as ‘0’

DCxB<1:0>: PWM Duty Cycle Least Significant bits

Capture mode:

Unused

Compare mode:

Unused

PWM mode:

These bits are the two LSbs of the PWM duty cycle. The eight MSbs are found in CCPRxL.

bit 3-0

CCPxM<3:0>: CCPx Mode Select bits

11xx= PWM mode

1011= Compare mode: Auto-conversion Trigger (sets CCPxIF bit (CCP2), starts ADC conversion if

ADC module is enabled)⁽¹⁾

1010= Compare mode: generate software interrupt only

1001= Compare mode: clear output on compare match (set CCPxIF)

1000= Compare mode: set output on compare match (set CCPxIF)

0111= Capture mode: every 16th rising edge

0110= Capture mode: every 4th rising edge

0101= Capture mode: every rising edge

0100= Capture mode: every falling edge

0011= Reserved

0010= Compare mode: toggle output on match

0001= Reserved

0000= Capture/Compare/PWM off (resets CCPx module)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 255

PIC16(L)F1782/3

26.0 MASTER SYNCHRONOUS

SERIAL PORT (MSSP)

MODULE

26.1 Master SSP (MSSP) Module

Overview

The Master Synchronous Serial Port (MSSP) module is

a serial interface useful for communicating with other

peripheral or microcontroller devices. These peripheral

devices may be serial EEPROMs, shift registers,

display drivers, A/D converters, etc. The MSSP module

can operate in one of two modes:

• Serial Peripheral Interface (SPI)

• Inter-Integrated Circuit (I²C™)

The SPI interface supports the following modes and

features:

• Master mode

• Slave mode

• Clock Parity

• Slave Select Synchronization (Slave mode only)

• Daisy-chain connection of slave devices

Figure 26-1 is a block diagram of the SPI interface

module.

FIGURE 26-1:

MSSP BLOCK DIAGRAM (SPI MODE)

Data Bus

Write

Read

SSPBUF Reg

SSPSR Reg

SDI

Shift

Clock

bit 0

SDO

SS

Control

Enable

SS

2 (CKP, CKE)

Clock Select

Edge

Select

SSPM<3:0>

4

TMR2 Output

(

)

2

SCK

TOSC

Prescaler

4, 16, 64

Edge

Select

Baud Rate

Generator

(SSPADD)

TRIS bit

DS40001579E-page 256

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

The I²C interface supports the following modes and

features:

• Master mode

• Slave mode

• Byte NACKing (Slave mode)

• Limited multi-master support

• 7-bit and 10-bit addressing

• Start and Stop interrupts

• Interrupt masking

• Clock stretching

• Bus collision detection

• General call address matching

• Address masking

• Address Hold and Data Hold modes

• Selectable SDA hold times

Figure 26-2 is a block diagram of the I²C interface

module in Master mode. Figure 26-3 is a diagram of the

I²C interface module in Slave mode.

FIGURE 26-2:

MSSP BLOCK DIAGRAM (I²C™ MASTER MODE)

Internal

data bus

[SSPM<3:0>]

Read

Write

SSP1BUF

SSPSR

Baud rate

generator

(SSPADD)

SDA

Shift

Clock

SDA in

MSb

LSb

Start bit, Stop bit,

Acknowledge

Generate (SSPCON2)

SCL

Start bit detect,

Stop bit detect

SCL in

Bus Collision

Write collision detect

Clock arbitration

State counter for

Set/Reset: S, P, SSPSTAT, WCOL, SSPOV

Reset SEN, PEN (SSPCON2)

Set SSP1IF, BCL1IF

end of XMIT/RCV

Address Match detect

 2011-2014 Microchip Technology Inc.

DS40001579E-page 257

PIC16(L)F1782/3

FIGURE 26-3:

MSSP BLOCK DIAGRAM (I²C™ SLAVE MODE)

Internal

Data Bus

Read

Write

SSPBUF Reg

SSPSR Reg

SCL

SDA

Shift

Clock

MSb

LSb

SSPMSK Reg

Match Detect

SSPADD Reg

Addr Match

Set, Reset

S, P bits

(SSPSTAT Reg)

Start and

Stop bit Detect

DS40001579E-page 258

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

During each SPI clock cycle, a full-duplex data

transmission occurs. This means that while the master

device is sending out the MSb from its shift register (on

its SDO pin) and the slave device is reading this bit and

saving it as the LSb of its shift register, that the slave

device is also sending out the MSb from its shift register

(on its SDO pin) and the master device is reading this

bit and saving it as the LSb of its shift register.

26.2 SPI Mode Overview

The Serial Peripheral Interface (SPI) bus is a

synchronous serial data communication bus that

operates in Full-Duplex mode. Devices communicate

in a master/slave environment where the master device

initiates the communication.

A slave device is

controlled through a Chip Select known as Slave

Select.

After 8 bits have been shifted out, the master and slave

have exchanged register values.

The SPI bus specifies four signal connections:

• Serial Clock (SCK)

• Serial Data Out (SDO)

• Serial Data In (SDI)

• Slave Select (SS)

If there is more data to exchange, the shift registers are

loaded with new data and the process repeats itself.

Whether the data is meaningful or not (dummy data),

depends on the application software. This leads to

three scenarios for data transmission:

Figure 26-1 shows the block diagram of the MSSP

module when operating in SPI mode.

• Master sends useful data and slave sends dummy

data.

The SPI bus operates with a single master device and

one or more slave devices. When multiple slave

devices are used, an independent Slave Select

connection is required from the master device to each

slave device.

• Master sends useful data and slave sends useful

data.

• Master sends dummy data and slave sends useful

data.

Figure 26-4 shows a typical connection between a

master device and multiple slave devices.

Transmissions may involve any number of clock

cycles. When there is no more data to be transmitted,

the master stops sending the clock signal and it

deselects the slave.

The master selects only one slave at a time. Most slave

devices have tri-state outputs so their output signal

appears disconnected from the bus when they are not

selected.

Every slave device connected to the bus that has not

been selected through its slave select line must

disregard the clock and transmission signals and must

not transmit out any data of its own.

Transmissions involve two shift registers, 8 bits in size,

one in the master and one in the slave. With either the

master or the slave device, data is always shifted out

one bit at a time, with the Most Significant bit (MSb)

shifted out first. At the same time, a new Least

Significant bit (LSb) is shifted into the same register.

Figure 26-5 shows a typical connection between two

processors configured as master and slave devices.

Data is shifted out of both shift registers on the

programmed clock edge and latched on the opposite

edge of the clock.

The master device transmits information out on its SDO

output pin which is connected to, and received by, the

slave’s SDI input pin. The slave device transmits

information out on its SDO output pin, which is

connected to, and received by, the master’s SDI input

pin.

To begin communication, the master device first sends

out the clock signal. Both the master and the slave

devices should be configured for the same clock

polarity.

The master device starts a transmission by sending out

the MSb from its shift register. The slave device reads

this bit from that same line and saves it into the LSb

position of its shift register.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 259

PIC16(L)F1782/3

FIGURE 26-4:

SPI MASTER AND MULTIPLE SLAVE CONNECTION

SCK

SDO

SCK

SDI

SDO

SS

SPI Master

SPI Slave

#1

SDI

General I/O

SCK

SDI

SDO

SS

SPI Slave

#2

SCK

SDI

SDO

SS

SPI Slave

#3

26.2.1 SPI MODE REGISTERS

The MSSP module has five registers for SPI mode

operation. These are:

• MSSP STATUS register (SSPSTAT)

• MSSP Control register 1 (SSPCON1)

• MSSP Control register 3 (SSPCON3)

• MSSP Data Buffer register (SSPBUF)

• MSSP Address register (SSPADD)

• MSSP Shift register (SSPSR)

(Not directly accessible)

SSPCON1 and SSPSTAT are the control and STATUS

registers in SPI mode operation. The SSPCON1

register is readable and writable. The lower 6 bits of

the SSPSTAT are read-only. The upper 2 bits of the

SSPSTAT are read/write.

In one SPI master mode, SSPADD can be loaded with

a value used in the Baud Rate Generator. More

information on the Baud Rate Generator is available in

Section 26.7 “Baud Rate Generator”.

SSPSR is the shift register used for shifting data in and

out. SSPBUF provides indirect access to the SSPSR

register. SSPBUF is the buffer register to which data

bytes are written, and from which data bytes are read.

In receive operations, SSPSR and SSPBUF together

create a buffered receiver. When SSPSR receives a

complete byte, it is transferred to SSPBUF and the

SSP1IF interrupt is set.

During transmission, the SSPBUF is not buffered. A

write to SSPBUF will write to both SSPBUF and

SSPSR.

DS40001579E-page 260

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

26.2.2 SPI MODE OPERATION

Any serial port function that is not desired may be

overridden by programming the corresponding data

direction (TRIS) register to the opposite value.

When initializing the SPI, several options need to be

specified. This is done by programming the appropriate

control bits (SSPCON1<5:0> and SSPSTAT<7:6>).

These control bits allow the following to be specified:

The MSSP consists of a transmit/receive shift register

(SSPSR) and a buffer register (SSPBUF). The SSPSR

shifts the data in and out of the device, MSb first. The

SSPBUF holds the data that was written to the SSPSR

until the received data is ready. Once the 8 bits of data

have been received, that byte is moved to the SSPBUF

register. Then, the Buffer Full Detect bit, BF of the

SSPSTAT register, and the interrupt flag bit, SSP1IF,

are set. This double-buffering of the received data

(SSPBUF) allows the next byte to start reception before

reading the data that was just received. Any write to the

SSPBUF register during transmission/reception of data

will be ignored and the write collision detect bit WCOL

of the SSPCON1 register, will be set. User software

must clear the WCOL bit to allow the following write(s)

to the SSPBUF register to complete successfully.

• Master mode (SCK is the clock output)

• Slave mode (SCK is the clock input)

• Clock Polarity (Idle state of SCK)

• Data Input Sample Phase (middle or end of data

output time)

• Clock Edge (output data on rising/falling edge of

SCK)

• Clock Rate (Master mode only)

• Slave Select mode (Slave mode only)

To enable the serial port, SSP Enable bit, SSPEN of the

SSPCON1 register, must be set. To reset or reconfig-

ure SPI mode, clear the SSPEN bit, re-initialize the

SSPCONx registers and then set the SSPEN bit. This

configures the SDI, SDO, SCK and SS pins as serial

port pins. For the pins to behave as the serial port

function, some must have their data direction bits (in

the TRIS register) appropriately programmed as

follows:

When the application software is expecting to receive

valid data, the SSPBUF should be read before the next

byte of data to transfer is written to the SSPBUF. The

Buffer Full bit, BF of the SSPSTAT register, indicates

when SSPBUF has been loaded with the received data

(transmission is complete). When the SSPBUF is read,

the BF bit is cleared. This data may be irrelevant if the

SPI is only a transmitter. Generally, the MSSP interrupt

is used to determine when the transmission/reception

has completed. If the interrupt method is not going to

be used, then software polling can be done to ensure

that a write collision does not occur.

• SDI must have corresponding TRIS bit set

• SDO must have corresponding TRIS bit cleared

• SCK (Master mode) must have corresponding

TRIS bit cleared

• SCK (Slave mode) must have corresponding

TRIS bit set

The SSPSR is not directly readable or writable and can

• SS must have corresponding TRIS bit set

FIGURE 26-5:

SPI MASTER/SLAVE CONNECTION

SPI Master SSPM<3:0> = 00xx

= 1010

SPI Slave SSPM<3:0> = 010x

SDO

SDI

Serial Input Buffer

(SSPBUF)

(BUF)

SDI

SDO

Shift Register

(SSPSR)

Shift Register

(SSPSR)

LSb

MSb

LSb

Serial Clock

SCK

SS

Slave Select

(optional)

General I/O

Processor 2

Processor 1

 2011-2014 Microchip Technology Inc.

DS40001579E-page 261

PIC16(L)F1782/3

The clock polarity is selected by appropriately

programming the CKP bit of the SSPCON1 register

and the CKE bit of the SSPSTAT register. This then,

would give waveforms for SPI communication as

shown in Figure 26-6, Figure 26-8 and Figure 26-9,

where the MSB is transmitted first. In Master mode, the

SPI clock rate (bit rate) is user programmable to be one

of the following:

26.2.3

SPI MASTER MODE

The master can initiate the data transfer at any time

because it controls the SCK line. The master

determines when the slave (Processor 2, Figure 26-5)

is to broadcast data by the software protocol.

In Master mode, the data is transmitted/received as

soon as the SSPBUF register is written to. If the SPI is

only going to receive, the SDO output could be

disabled (programmed as an input). The SSPSR

register will continue to shift in the signal present on the

SDI pin at the programmed clock rate. As each byte is

received, it will be loaded into the SSPBUF register as

if a normal received byte (interrupts and Status bits

appropriately set).

• FOSC/4 (or TCY)

• FOSC/16 (or 4 * TCY)

• FOSC/64 (or 16 * TCY)

• Timer2 output/2

• Fosc/(4 * (SSPADD + 1))

Figure 26-6 shows the waveforms for Master mode.

When the CKE bit is set, the SDO data is valid before

there is a clock edge on SCK. The change of the input

sample is shown based on the state of the SMP bit. The

time when the SSPBUF is loaded with the received

data is shown.

FIGURE 26-6:

SPI MODE WAVEFORM (MASTER MODE)

Write to

SSPBUF

SCK

(CKP = 0

CKE = 0)

SCK

(CKP = 1

CKE = 0)

4 Clock

Modes

SCK

(CKP = 0

CKE = 1)

SCK

(CKP = 1

CKE = 1)

bit 6

bit 2

bit 5

bit 4

bit 1

bit 0

SDO

(CKE = 0)

bit 7

bit 3

SDO

(CKE = 1)

SDI

(SMP = 0)

bit 0

bit 7

Input

Sample

(SMP = 0)

SDI

(SMP = 1)

bit 0

bit 7

Input

Sample

(SMP = 1)

SSP1IF

SSPSR to

SSPBUF

DS40001579E-page 262

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

26.2.4

SPI SLAVE MODE

26.2.5

SLAVE SELECT

SYNCHRONIZATION

In Slave mode, the data is transmitted and received as

external clock pulses appear on SCK. When the last

bit is latched, the SSP1IF interrupt flag bit is set.

The Slave Select can also be used to synchronize

communication. The Slave Select line is held high until

the master device is ready to communicate. When the

Slave Select line is pulled low, the slave knows that a

new transmission is starting.

Before enabling the module in SPI Slave mode, the clock

line must match the proper Idle state. The clock line can

be observed by reading the SCK pin. The Idle state is

determined by the CKP bit of the SSPCON1 register.

If the slave fails to receive the communication properly,

it will be reset at the end of the transmission, when the

Slave Select line returns to a high state. The slave is

then ready to receive a new transmission when the

Slave Select line is pulled low again. If the Slave Select

line is not used, there is a risk that the slave will

eventually become out of sync with the master. If the

slave misses a bit, it will always be one bit off in future

transmissions. Use of the Slave Select line allows the

slave and master to align themselves at the beginning

of each transmission.

While in Slave mode, the external clock is supplied by

the external clock source on the SCK pin. This external

clock must meet the minimum high and low times as

specified in the electrical specifications.

While in Sleep mode, the slave can transmit/receive

data. The shift register is clocked from the SCK pin

input and when a byte is received, the device will

generate an interrupt. If enabled, the device will

wake-up from Sleep.

26.2.4.1 Daisy-Chain Configuration

The SS pin allows a Synchronous Slave mode. The

SPI must be in Slave mode with SS pin control enabled

(SSPCON1<3:0> = 0100).

The SPI bus can sometimes be connected in a

daisy-chain configuration. The first slave output is con-

nected to the second slave input, the second slave

output is connected to the third slave input, and so on.

The final slave output is connected to the master input.

Each slave sends out, during a second group of clock

pulses, an exact copy of what was received during the

first group of clock pulses. The whole chain acts as

one large communication shift register. The

daisy-chain feature only requires a single Slave Select

line from the master device.

When the SS pin is low, transmission and reception are

enabled and the SDO pin is driven.

When the SS pin goes high, the SDO pin is no longer

driven, even if in the middle of a transmitted byte and

becomes a floating output. External pull-up/pull-down

resistors may be desirable depending on the

application.

Note 1: When the SPI is in Slave mode with SS pin

control enabled (SSPCON1<3:0>

=

Figure 26-7 shows the block diagram of a typical

daisy-chain connection when operating in SPI mode.

0100), the SPI module will reset if the SS

pin is set to VDD.

In a daisy-chain configuration, only the most recent

byte on the bus is required by the slave. Setting the

BOEN bit of the SSPCON3 register will enable writes

to the SSPBUF register, even if the previous byte has

not been read. This allows the software to ignore data

that may not apply to it.

2: When the SPI is used in Slave mode with

CKE set; the user must enable SS pin

control.

3: While operated in SPI Slave mode the

SMP bit of the SSPSTAT register must

remain clear.

When the SPI module resets, the bit counter is forced

to ‘0’. This can be done by either forcing the SS pin to

a high level or clearing the SSPEN bit.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 263

PIC16(L)F1782/3

FIGURE 26-7:

SPI DAISY-CHAIN CONNECTION

SCK

SDO

SCK

SDI

SDO

SS

SPI Master

SPI Slave

#1

SDI

General I/O

SCK

SDI

SDO

SS

SPI Slave

#2

SCK

SDI

SDO

SS

SPI Slave

#3

FIGURE 26-8:

SLAVE SELECT SYNCHRONOUS WAVEFORM

SS

SCK

(CKP = 0

CKE = 0)

SCK

(CKP = 1

CKE = 0)

Write to

SSPBUF

Shift register SSPSR

and bit count are reset

SSPBUF to

SSPSR

bit 6

bit 7

bit 0

SDO

SDI

bit 7

bit 0

bit 7

Input

Sample

SSP1IF

Interrupt

Flag

SSPSR to

SSPBUF

DS40001579E-page 264

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 26-9:

SPI MODE WAVEFORM (SLAVE MODE WITH CKE = 0)

SS

Optional

SCK

(CKP = 0

CKE = 0)

SCK

(CKP = 1

CKE = 0)

Write to

SSPBUF

Valid

bit 6

bit 2

bit 5

bit 4

bit 3

bit 1

bit 0

SDO

bit 7

SDI

bit 0

bit 7

Input

Sample

SSP1IF

Interrupt

Flag

SSPSR to

SSPBUF

Write Collision

detection active

FIGURE 26-10:

SPI MODE WAVEFORM (SLAVE MODE WITH CKE = 1)

SS

Not Optional

SCK

(CKP = 0

CKE = 1)

SCK

(CKP = 1

CKE = 1)

Write to

SSPBUF

Valid

bit 6

bit 3

bit 2

bit 5

bit 4

bit 1

bit 0

SDO

bit 7

SDI

bit 0

Input

Sample

SSP1IF

Interrupt

Flag

SSPSR to

SSPBUF

Write Collision

detection active

 2011-2014 Microchip Technology Inc.

DS40001579E-page 265

PIC16(L)F1782/3

26.2.6 SPI OPERATION IN SLEEP MODE

In SPI Master mode, when the Sleep mode is selected,

all module clocks are halted and the transmis-

sion/reception will remain in that state until the device

wakes. After the device returns to Run mode, the

module will resume transmitting and receiving data.

In SPI Master mode, module clocks may be operating

at a different speed than when in Full-Power mode; in

the case of the Sleep mode, all clocks are halted.

Special care must be taken by the user when the MSSP

clock is much faster than the system clock.

In SPI Slave mode, the SPI Transmit/Receive Shift

register operates asynchronously to the device. This

allows the device to be placed in Sleep mode and data

to be shifted into the SPI Transmit/Receive Shift

register. When all 8 bits have been received, the MSSP

interrupt flag bit will be set and if enabled, will wake the

device.

In Slave mode, when MSSP interrupts are enabled,

after the master completes sending data, an MSSP

interrupt will wake the controller from Sleep.

If an exit from Sleep mode is not desired, MSSP

interrupts should be disabled.

TABLE 26-1: SUMMARY OF REGISTERS ASSOCIATED WITH SPI OPERATION

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

ANSELA

APFCON

INTCON

ANSA7

—

ANSA5

SDOSEL

TMR0IE

ANSA4

SCKSEL

INTE

ANSA3

SDISEL

IOCIE

ANSA2

TXSEL

TMR0IF

ANSA1

RXSEL

INTF

ANSA0

CCP2SEL

IOCIF

115

111

79

C2OUTSEL CCP1SEL

GIE

PEIE

ADIE

ADIF

PIE1

TMR1GIE

TMR1GIF

RCIE

RCIF

TXIE

TXIF

SSP1IE

SSP1IF

CCP1IE

CCP1IF

TMR2IE

TMR2IF

TMR1IE

TMR1IF

80

PIR1

83

SSP1BUF

SSP1CON1

Synchronous Serial Port Receive Buffer/Transmit Register

260*

306

308

304

114

125

WCOL

SSPOV

PCIE

SSPEN

SCIE

CKP

SSPM<3:0>

SSP1CON3 ACKTIM

BOEN

SDAHT

SBCDE

AHEN

DHEN

SSP1STAT

TRISA

SMP

CKE

D/A

P

S

R/W

UA

BF

TRISA7

TRISC7

TRISA6

TRISC6

TRISA5

TRISC5

TRISA4

TRISC4

TRISA3

TRISC3

TRISA2

TRISC2

TRISA1

TRISC1

TRISA0

TRISC

Legend:

— = Unimplemented location, read as ‘0’. Shaded cells are not used by the MSSP in SPI mode.

*

Page provides register information.

Note 1: PIC16(L)F1783 only.

DS40001579E-page 266

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

I²C MASTER/

26.3 I²C MODE OVERVIEW

FIGURE 26-11:

SLAVE CONNECTION

The Inter-Integrated Circuit Bus (I²C) is a multi-master

serial data communication bus. Devices communicate

in a master/slave environment where the master

devices initiate the communication. A Slave device is

controlled through addressing.

VDD

SCL

SDA

SCL

The I²C bus specifies two signal connections:

VDD

• Serial Clock (SCL)

• Serial Data (SDA)

Master

Slave

SDA

Figure 26-11 shows the block diagram of the MSSP

module when operating in I²C mode.

Both the SCL and SDA connections are bidirectional

open-drain lines, each requiring pull-up resistors for the

supply voltage. Pulling the line to ground is considered

a logical zero and letting the line float is considered a

logical one.

The Acknowledge bit (ACK) is an active-low signal,

which holds the SDA line low to indicate to the transmit-

ter that the slave device has received the transmitted

data and is ready to receive more.

Figure 26-11 shows a typical connection between two

processors configured as master and slave devices.

The I²C bus can operate with one or more master

devices and one or more slave devices.

The transition of a data bit is always performed while

the SCL line is held low. Transitions that occur while the

SCL line is held high are used to indicate Start and Stop

bits.

If the master intends to write to the slave, then it repeat-

edly sends out a byte of data, with the slave responding

after each byte with an ACK bit. In this example, the

master device is in Master Transmit mode and the

slave is in Slave Receive mode.

There are four potential modes of operation for a given

device:

• Master Transmit mode

(master is transmitting data to a slave)

• Master Receive mode

If the master intends to read from the slave, then it

repeatedly receives a byte of data from the slave, and

responds after each byte with an ACK bit. In this

example, the master device is in Master Receive mode

and the slave is Slave Transmit mode.

(master is receiving data from a slave)

• Slave Transmit mode

(slave is transmitting data to a master)

• Slave Receive mode

(slave is receiving data from the master)

On the last byte of data communicated, the master

device may end the transmission by sending a Stop bit.

If the master device is in Receive mode, it sends the

Stop bit in place of the last ACK bit. A Stop bit is

indicated by a low-to-high transition of the SDA line

while the SCL line is held high.

To begin communication, a master device starts out in

Master Transmit mode. The master device sends out a

Start bit followed by the address byte of the slave it

intends to communicate with. This is followed by a

single Read/Write bit, which determines whether the

master intends to transmit to or receive data from the

slave device.

In some cases, the master may want to maintain

control of the bus and re-initiate another transmission.

If so, the master device may send another Start bit in

place of the Stop bit or last ACK bit when it is in receive

mode.

If the requested slave exists on the bus, it will respond

with an Acknowledge bit, otherwise known as an ACK.

The master then continues in either Transmit mode or

Receive mode and the slave continues in the comple-

ment, either in Receive mode or Transmit mode,

respectively.

The I²C bus specifies three message protocols;

• Single message where a master writes data to a

slave.

A Start bit is indicated by a high-to-low transition of the

SDA line while the SCL line is held high. Address and

data bytes are sent out, Most Significant bit (MSb) first.

The Read/Write bit is sent out as a logical one when the

master intends to read data from the slave, and is sent

out as a logical zero when it intends to write data to the

slave.

• Single message where a master reads data from

a slave.

• Combined message where a master initiates a

minimum of two writes, or two reads, or a

combination of writes and reads, to one or more

slaves.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 267

PIC16(L)F1782/3

When one device is transmitting a logical one, or letting

the line float, and a second device is transmitting a

logical zero, or holding the line low, the first device can

detect that the line is not a logical one. This detection,

when used on the SCL line, is called clock stretching.

Clock stretching gives slave devices a mechanism to

control the flow of data. When this detection is used on

the SDA line, it is called arbitration. Arbitration ensures

that there is only one master device communicating at

any single time.

26.3.2

ARBITRATION

Each master device must monitor the bus for Start and

Stop bits. If the device detects that the bus is busy, it

cannot begin a new message until the bus returns to an

Idle state.

However, two master devices may try to initiate a trans-

mission on or about the same time. When this occurs,

the process of arbitration begins. Each transmitter

checks the level of the SDA data line and compares it

to the level that it expects to find. The first transmitter to

observe that the two levels do not match, loses arbitra-

tion, and must stop transmitting on the SDA line.

26.3.1

CLOCK STRETCHING

When a slave device has not completed processing

data, it can delay the transfer of more data through the

process of clock stretching. An addressed slave device

may hold the SCL clock line low after receiving or send-

ing a bit, indicating that it is not yet ready to continue.

The master that is communicating with the slave will

attempt to raise the SCL line in order to transfer the

next bit, but will detect that the clock line has not yet

been released. Because the SCL connection is

open-drain, the slave has the ability to hold that line low

until it is ready to continue communicating.

For example, if one transmitter holds the SDA line to a

logical one (lets it float) and a second transmitter holds

it to a logical zero (pulls it low), the result is that the

SDA line will be low. The first transmitter then observes

that the level of the line is different than expected and

concludes that another transmitter is communicating.

The first transmitter to notice this difference is the one

that loses arbitration and must stop driving the SDA

line. If this transmitter is also a master device, it also

must stop driving the SCL line. It then can monitor the

lines for a Stop condition before trying to reissue its

transmission. In the meantime, the other device that

has not noticed any difference between the expected

and actual levels on the SDA line continues with its

original transmission. It can do so without any compli-

cations, because so far, the transmission appears

exactly as expected with no other transmitter disturbing

the message.

Clock stretching allows receivers that cannot keep up

with a transmitter to control the flow of incoming data.

Slave Transmit mode can also be arbitrated, when a

master addresses multiple slaves, but this is less

common.

If two master devices are sending a message to two

different slave devices at the address stage, the master

sending the lower slave address always wins arbitra-

tion. When two master devices send messages to the

same slave address, and addresses can sometimes

refer to multiple slaves, the arbitration process must

continue into the data stage.

Arbitration usually occurs very rarely, but it is a

necessary process for proper multi-master support.

DS40001579E-page 268

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 26-2: I²C BUS TERMS

26.4 I²C MODE OPERATION

TERM

Description

All MSSP I²C communication is byte oriented and

shifted out MSb first. Six SFR registers and two

interrupt flags interface the module with the PIC^®

microcontroller and user software. Two pins, SDA and

SCL, are exercised by the module to communicate

with other external I²C devices.

Transmitter

The device which shifts data out

onto the bus.

Receiver

Master

The device which shifts data in

from the bus.

The device that initiates a transfer,

generates clock signals and

terminates a transfer.

26.4.1 BYTE FORMAT

All communication in I²C is done in 9-bit segments. A

byte is sent from a master to a slave or vice-versa,

followed by an Acknowledge bit sent back. After the

8th falling edge of the SCL line, the device outputting

data on the SDA changes that pin to an input and

reads in an acknowledge value on the next clock

pulse.

Slave

The device addressed by the

master.

Multi-master

Arbitration

A bus with more than one device

that can initiate data transfers.

Procedure to ensure that only one

master at a time controls the bus.

Winning arbitration ensures that

the message is not corrupted.

The clock signal, SCL, is provided by the master. Data

is valid to change while the SCL signal is low, and

sampled on the rising edge of the clock. Changes on

the SDA line while the SCL line is high define special

conditions on the bus, explained below.

Synchronization Procedure to synchronize the

clocks of two or more devices on

the bus.

Idle

No master is controlling the bus,

and both SDA and SCL lines are

high.

26.4.2 DEFINITION OF I²C TERMINOLOGY

There is language and terminology in the description

of I²C communication that have definitions specific to

I²C. That word usage is defined below and may be

used in the rest of this document without explanation.

This table was adapted from the Philips I²C

specification.

Active

Any time one or more master

devices are controlling the bus.

Addressed

Slave

Slave device that has received a

matching address and is actively

being clocked by a master.

Matching

Address

Address byte that is clocked into a

slave that matches the value

stored in SSPADD.

26.4.3 SDA AND SCL PINS

Selection of any I²C mode with the SSPEN bit set,

forces the SCL and SDA pins to be open-drain. These

pins should be set by the user to inputs by setting the

appropriate TRIS bits.

Write Request

Read Request

Slave receives a matching

address with R/W bit clear, and is

ready to clock in data.

Master sends an address byte with

the R/W bit set, indicating that it

wishes to clock data out of the

Slave. This data is the next and all

following bytes until a Restart or

Stop.

Note: Data is tied to output zero when an I²C

mode is enabled.

26.4.4 SDA HOLD TIME

The hold time of the SDA pin is selected by the SDAHT

bit of the SSPCON3 register. Hold time is the time SDA

is held valid after the falling edge of SCL. Setting the

SDAHT bit selects a longer 300 ns minimum hold time

and may help on buses with large capacitance.

Clock Stretching When a device on the bus hold

SCL low to stall communication.

Bus Collision

Any time the SDA line is sampled

low by the module while it is out-

putting and expected high state.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 269

PIC16(L)F1782/3

26.4.5 START CONDITION

26.4.7 RESTART CONDITION

The I²C specification defines a Start condition as a

transition of SDA from a high to a low state while SCL

line is high. A Start condition is always generated by

the master and signifies the transition of the bus from

an Idle to an Active state. Figure 26-10 shows wave

forms for Start and Stop conditions.

A Restart is valid any time that a Stop would be valid.

A master can issue a Restart if it wishes to hold the

bus after terminating the current transfer. A Restart

has the same effect on the slave that a Start would,

resetting all slave logic and preparing it to clock in an

address. The master may want to address the same or

another slave.

A bus collision can occur on a Start condition if the

module samples the SDA line low before asserting it

low. This does not conform to the I²C Specification that

states no bus collision can occur on a Start.

In 10-bit Addressing Slave mode a Restart is required

for the master to clock data out of the addressed

slave. Once a slave has been fully addressed, match-

ing both high and low address bytes, the master can

issue a Restart and the high address byte with the

R/W bit set. The slave logic will then hold the clock

and prepare to clock out data.

26.4.6 STOP CONDITION

A Stop condition is a transition of the SDA line from

low-to-high state while the SCL line is high.

After a full match with R/W clear in 10-bit mode, a prior

match flag is set and maintained. Until a Stop

condition, a high address with R/W clear, or high

address match fails.

Note: At least one SCL low time must appear

before a Stop is valid, therefore, if the SDA

line goes low then high again while the SCL

line stays high, only the Start condition is

detected.

26.4.8 START/STOP CONDITION INTERRUPT

MASKING

The SCIE and PCIE bits of the SSPCON3 register can

enable the generation of an interrupt in Slave modes

that do not typically support this function. Slave modes

where interrupt on Start and Stop detect are already

enabled, these bits will have no effect.

FIGURE 26-12:

I²C START AND STOP CONDITIONS

SDA

SCL

S

P

Change of

Data Allowed

Stop

Start

Condition

FIGURE 26-13:

I²C RESTART CONDITION

Sr

Change of

Data Allowed

Restart

Condition

DS40001579E-page 270

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

26.5 I²C SLAVE MODE OPERATION

26.4.9 ACKNOWLEDGE SEQUENCE

The 9th SCL pulse for any transferred byte in I²C is

dedicated as an Acknowledge. It allows receiving

devices to respond back to the transmitter by pulling

the SDA line low. The transmitter must release control

of the line during this time to shift in the response. The

Acknowledge (ACK) is an active-low signal, pulling the

SDA line low indicated to the transmitter that the

device has received the transmitted data and is ready

to receive more.

The MSSP Slave mode operates in one of four modes

selected in the SSPM bits of SSPCON1 register. The

modes can be divided into 7-bit and 10-bit Addressing

mode. 10-bit Addressing modes operate the same as

7-bit with some additional overhead for handling the

larger addresses.

Modes with Start and Stop bit interrupts operated the

same as the other modes with SSP1IF additionally

getting set upon detection of a Start, Restart, or Stop

condition.

The result of an ACK is placed in the ACKSTAT bit of

the SSPCON2 register.

26.5.1 SLAVE MODE ADDRESSES

Slave software, when the AHEN and DHEN bits are

set, allow the user to set the ACK value sent back to

the transmitter. The ACKDT bit of the SSPCON2

register is set/cleared to determine the response.

The SSPADD register (Register 26-6) contains the

Slave mode address. The first byte received after a

Start or Restart condition is compared against the

value stored in this register. If the byte matches, the

value is loaded into the SSPBUF register and an

interrupt is generated. If the value does not match, the

module goes idle and no indication is given to the

software that anything happened.

Slave hardware will generate an ACK response if the

AHEN and DHEN bits of the SSPCON3 register are

clear.

There are certain conditions where an ACK will not be

sent by the slave. If the BF bit of the SSPSTAT register

or the SSPOV bit of the SSPCON1 register are set

when a byte is received.

The SSP Mask register (Register 26-5) affects the

address matching process. See Section 26.5.9 “SSP

Mask Register” for more information.

When the module is addressed, after the 8th falling

edge of SCL on the bus, the ACKTIM bit of the SSP-

CON3 register is set. The ACKTIM bit indicates the

acknowledge time of the active bus. The ACKTIM Sta-

tus bit is only active when the AHEN bit or DHEN bit is

enabled.

26.5.1.1 I²C Slave 7-bit Addressing Mode

In 7-bit Addressing mode, the LSb of the received data

byte is ignored when determining if there is an address

match.

26.5.1.2 I²C Slave 10-bit Addressing Mode

In 10-bit Addressing mode, the first received byte is

compared to the binary value of ‘1 1 1 1 0 A9 A8 0’. A9

and A8 are the two MSb of the 10-bit address and

stored in bits 2 and 1 of the SSPADD register.

After the acknowledge of the high byte the UA bit is set

and SCL is held low until the user updates SSPADD

with the low address. The low address byte is clocked

in and all 8 bits are compared to the low address value

in SSPADD. Even if there is not an address match;

SSP1IF and UA are set, and SCL is held low until

SSPADD is updated to receive a high byte again.

When SSPADD is updated the UA bit is cleared. This

ensures the module is ready to receive the high

address byte on the next communication.

A high and low address match as a write request is

required at the start of all 10-bit addressing communi-

cation. A transmission can be initiated by issuing a

Restart once the slave is addressed, and clocking in

the high address with the R/W bit set. The slave hard-

ware will then acknowledge the read request and

prepare to clock out data. This is only valid for a slave

after it has received a complete high and low address

byte match.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 271

PIC16(L)F1782/3

26.5.2 SLAVE RECEPTION

26.5.2.2 7-bit Reception with AHEN and DHEN

When the R/W bit of a matching received address byte

is clear, the R/W bit of the SSPSTAT register is cleared.

The received address is loaded into the SSPBUF

register and acknowledged.

Slave device reception with AHEN and DHEN set

operate the same as without these options with extra

interrupts and clock stretching added after the 8th

falling edge of SCL. These additional interrupts allow

the slave software to decide whether it wants to ACK

the receive address or data byte, rather than the hard-

ware. This functionality adds support for PMBus™ that

was not present on previous versions of this module.

When the overflow condition exists for a received

address, then not Acknowledge is given. An overflow

condition is defined as either bit BF of the SSPSTAT

register is set, or bit SSPOV of the SSPCON1 register

is set. The BOEN bit of the SSPCON3 register modifies

this operation. For more information see Register 26-4.

This list describes the steps that need to be taken by

slave software to use these options for I²C communi-

cation. Figure 26-15 displays a module using both

address and data holding. Figure 26-16 includes the

operation with the SEN bit of the SSPCON2 register

set.

An MSSP interrupt is generated for each transferred

data byte. Flag bit, SSP1IF, must be cleared by soft-

ware.

When the SEN bit of the SSPCON2 register is set, SCL

will be held low (clock stretch) following each received

byte. The clock must be released by setting the CKP

bit of the SSPCON1 register, except sometimes in

10-bit mode. See Section 26.2.3 “SPI Master Mode”

for more detail.

1. S bit of SSPSTAT is set; SSP1IF is set if inter-

rupt on Start detect is enabled.

2. Matching address with R/W bit clear is clocked

in. SSP1IF is set and CKP cleared after the 8th

falling edge of SCL.

3. Slave clears the SSP1IF.

26.5.2.1 7-bit Addressing Reception

4. Slave can look at the ACKTIM bit of the

SSPCON3 register to determine if the SSP1IF

was after or before the ACK.

This section describes a standard sequence of events

for the MSSP module configured as an I²C Slave in

7-bit Addressing mode. All decisions made by hard-

ware or software and their effect on reception.

Figure 26-13 and Figure 26-14 is used as a visual

reference for this description.

5. Slave reads the address value from SSPBUF,

clearing the BF flag.

6. Slave sets ACK value clocked out to the master

by setting ACKDT.

This is a step by step process of what typically must

be done to accomplish I²C communication.

7. Slave releases the clock by setting CKP.

8. SSP1IF is set after an ACK, not after a NACK.

1. Start bit detected.

9. If SEN = 1 the slave hardware will stretch the

clock after the ACK.

2. S bit of SSPSTAT is set; SSP1IF is set if inter-

rupt on Start detect is enabled.

10. Slave clears SSP1IF.

3. Matching address with R/W bit clear is received.

Note: SSP1IF is still set after the 9th falling edge

of SCL even if there is no clock stretching

and BF has been cleared. Only if NACK is

sent to master is SSP1IF not set

4. The slave pulls SDA low sending an ACK to the

master, and sets SSP1IF bit.

5. Software clears the SSP1IF bit.

6. Software reads received address from SSPBUF

clearing the BF flag.

11. SSP1IF set and CKP cleared after 8th falling

edge of SCL for a received data byte.

7. If SEN = 1; Slave software sets CKP bit to

12. Slave looks at ACKTIM bit of SSPCON3 to

determine the source of the interrupt.

release the SCL line.

8. The master clocks out a data byte.

13. Slave reads the received data from SSPBUF

clearing BF.

9. Slave drives SDA low sending an ACK to the

master, and sets SSP1IF bit.

14. Steps 7-14 are the same for each received data

byte.

10. Software clears SSP1IF.

15. Communication is ended by either the slave

sending an ACK = 1, or the master sending a

Stop condition. If a Stop is sent and Interrupt on

Stop Detect is disabled, the slave will only know

by polling the P bit of the SSTSTAT register.

11. Software reads the received byte from SSPBUF

clearing BF.

12. Steps 8-12 are repeated for all received bytes

from the master.

13. Master sends Stop condition, setting P bit of

SSPSTAT, and the bus goes idle.

DS40001579E-page 272

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 26-14:

I²C SLAVE, 7-BIT ADDRESS, RECEPTION (SEN = 0, AHEN = 0, DHEN = 0)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 273

PIC16(L)F1782/3

FIGURE 26-15:

I²C SLAVE, 7-BIT ADDRESS, RECEPTION (SEN = 1, AHEN = 0, DHEN = 0)

DS40001579E-page 274

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 26-16:

I²C SLAVE, 7-BIT ADDRESS, RECEPTION (SEN = 0, AHEN = 1, DHEN = 1)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 275

PIC16(L)F1782/3

FIGURE 26-17:

I²C SLAVE, 7-BIT ADDRESS, RECEPTION (SEN = 1, AHEN = 1, DHEN = 1)

DS40001579E-page 276

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

26.5.3

SLAVE TRANSMISSION

26.5.3.2

7-bit Transmission

When the R/W bit of the incoming address byte is set

and an address match occurs, the R/W bit of the

SSPSTAT register is set. The received address is

loaded into the SSPBUF register, and an ACK pulse is

sent by the slave on the ninth bit.

A master device can transmit a read request to a

slave, and then clock data out of the slave. The list

below outlines what software for a slave will need to

do to accomplish

a

standard transmission.

Figure 26-17 can be used as a reference to this list.

Following the ACK, slave hardware clears the CKP bit

and the SCL pin is held low (see Section 26.5.6

“Clock Stretching” for more detail). By stretching the

clock, the master will be unable to assert another clock

pulse until the slave is done preparing the transmit

data.

1. Master sends a Start condition on SDA and

SCL.

2. S bit of SSPSTAT is set; SSP1IF is set if inter-

rupt on Start detect is enabled.

3. Matching address with R/W bit set is received by

the Slave setting SSP1IF bit.

The transmit data must be loaded into the SSPBUF

register which also loads the SSPSR register. Then the

SCL pin should be released by setting the CKP bit of

the SSPCON1 register. The eight data bits are shifted

out on the falling edge of the SCL input. This ensures

that the SDA signal is valid during the SCL high time.

4. Slave hardware generates an ACK and sets

SSP1IF.

5. SSP1IF bit is cleared by user.

6. Software reads the received address from

SSPBUF, clearing BF.

7. R/W is set so CKP was automatically cleared

after the ACK.

The ACK pulse from the master-receiver is latched on

the rising edge of the ninth SCL input pulse. This ACK

value is copied to the ACKSTAT bit of the SSPCON2

register. If ACKSTAT is set (not ACK), then the data

transfer is complete. In this case, when the not ACK is

latched by the slave, the slave goes idle and waits for

another occurrence of the Start bit. If the SDA line was

low (ACK), the next transmit data must be loaded into

the SSPBUF register. Again, the SCL pin must be

released by setting bit CKP.

8. The slave software loads the transmit data into

SSPBUF.

9. CKP bit is set releasing SCL, allowing the

master to clock the data out of the slave.

10. SSP1IF is set after the ACK response from the

master is loaded into the ACKSTAT register.

11. SSP1IF bit is cleared.

12. The slave software checks the ACKSTAT bit to

see if the master wants to clock out more data.

An MSSP interrupt is generated for each data transfer

byte. The SSP1IF bit must be cleared by software and

the SSPSTAT register is used to determine the status

of the byte. The SSP1IF bit is set on the falling edge of

the ninth clock pulse.

Note 1: If the master ACKs the clock will be

stretched.

2: ACKSTAT is the only bit updated on the

rising edge of SCL (9th) rather than the

falling.

26.5.3.1

Slave Mode Bus Collision

13. Steps 9-13 are repeated for each transmitted

byte.

A slave receives a Read request and begins shifting

data out on the SDA line. If a bus collision is detected

and the SBCDE bit of the SSPCON3 register is set, the

BCL1IF bit of the PIR register is set. Once a bus colli-

sion is detected, the slave goes idle and waits to be

addressed again. User software can use the BCL1IF bit

to handle a slave bus collision.

14. If the master sends a not ACK; the clock is not

held, but SSP1IF is still set.

15. The master sends a Restart condition or a Stop.

16. The slave is no longer addressed.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 277

PIC16(L)F1782/3

FIGURE 26-18:

I²C SLAVE, 7-BIT ADDRESS, TRANSMISSION (AHEN = 0)

DS40001579E-page 278

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

26.5.3.3

7-bit Transmission with Address

Hold Enabled

Setting the AHEN bit of the SSPCON3 register

enables additional clock stretching and interrupt

generation after the 8th falling edge of a received

matching address. Once a matching address has

been clocked in, CKP is cleared and the SSP1IF

interrupt is set.

Figure 26-18 displays a standard waveform of a 7-bit

Address Slave Transmission with AHEN enabled.

1. Bus starts Idle.

2. Master sends Start condition; the S bit of

SSPSTAT is set; SSP1IF is set if interrupt on

Start detect is enabled.

3. Master sends matching address with R/W bit

set. After the 8th falling edge of the SCL line the

CKP bit is cleared and SSP1IF interrupt is

generated.

4. Slave software clears SSP1IF.

5. Slave software reads ACKTIM bit of SSPCON3

register, and R/W and D/A of the SSPSTAT

register to determine the source of the interrupt.

6. Slave reads the address value from the

SSPBUF register clearing the BF bit.

7. Slave software decides from this information if it

wishes to ACK or not ACK and sets the ACKDT

bit of the SSPCON2 register accordingly.

8. Slave sets the CKP bit releasing SCL.

9. Master clocks in the ACK value from the slave.

10. Slave hardware automatically clears the CKP bit

and sets SSP1IF after the ACK if the R/W bit is

set.

11. Slave software clears SSP1IF.

12. Slave loads value to transmit to the master into

SSPBUF setting the BF bit.

Note: SSPBUF cannot be loaded until after the

ACK.

13. Slave sets the CKP bit releasing the clock.

14. Master clocks out the data from the slave and

sends an ACK value on the 9th SCL pulse.

15. Slave hardware copies the ACK value into the

ACKSTAT bit of the SSPCON2 register.

16. Steps 10-15 are repeated for each byte transmit-

ted to the master from the slave.

17. If the master sends a not ACK the slave

releases the bus allowing the master to send a

Stop and end the communication.

Note: Master must send a not ACK on the last

byte to ensure that the slave releases the

SCL line to receive a Stop.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 279

PIC16(L)F1782/3

FIGURE 26-19:

I²C SLAVE, 7-BIT ADDRESS, TRANSMISSION (AHEN = 1)

DS40001579E-page 280

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

26.5.4 SLAVE MODE 10-BIT ADDRESS

RECEPTION

26.5.5 10-BIT ADDRESSING WITH ADDRESS OR

DATA HOLD

This section describes a standard sequence of events

for the MSSP module configured as an I²C slave in

10-bit Addressing mode.

Reception using 10-bit addressing with AHEN or

DHEN set is the same as with 7-bit modes. The only

difference is the need to update the SSPADD register

using the UA bit. All functionality, specifically when the

CKP bit is cleared and SCL line is held low are the

same. Figure 26-20 can be used as a reference of a

slave in 10-bit addressing with AHEN set.

Figure 26-19 is used as a visual reference for this

description.

This is a step by step process of what must be done by

slave software to accomplish I²C communication.

Figure 26-21 shows a standard waveform for a slave

transmitter in 10-bit Addressing mode.

1. Bus starts Idle.

2. Master sends Start condition; S bit of SSPSTAT

is set; SSP1IF is set if interrupt on Start detect is

enabled.

3. Master sends matching high address with R/W

bit clear; UA bit of the SSPSTAT register is set.

4. Slave sends ACK and SSP1IF is set.

5. Software clears the SSP1IF bit.

6. Software reads received address from SSPBUF

clearing the BF flag.

7. Slave loads low address into SSPADD,

releasing SCL.

8. Master sends matching low address byte to the

slave; UA bit is set.

Note: Updates to the SSPADD register are not

allowed until after the ACK sequence.

9. Slave sends ACK and SSP1IF is set.

Note: If the low address does not match, SSP1IF

and UA are still set so that the slave soft-

ware can set SSPADD back to the high

address. BF is not set because there is no

match. CKP is unaffected.

10. Slave clears SSP1IF.

11. Slave reads the received matching address

from SSPBUF clearing BF.

12. Slave loads high address into SSPADD.

13. Master clocks a data byte to the slave and

clocks out the slaves ACK on the 9th SCL pulse;

SSP1IF is set.

14. If SEN bit of SSPCON2 is set, CKP is cleared by

hardware and the clock is stretched.

15. Slave clears SSP1IF.

16. Slave reads the received byte from SSPBUF

clearing BF.

17. If SEN is set the slave sets CKP to release the

SCL.

18. Steps 13-17 repeat for each received byte.

19. Master sends Stop to end the transmission.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 281

PIC16(L)F1782/3

FIGURE 26-20:

I²C SLAVE, 10-BIT ADDRESS, RECEPTION (SEN = 1, AHEN = 0, DHEN = 0)

DS40001579E-page 282

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 26-21:

I²C SLAVE, 10-BIT ADDRESS, RECEPTION (SEN = 0, AHEN = 1, DHEN = 0)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 283

PIC16(L)F1782/3

FIGURE 26-22:

I²C SLAVE, 10-BIT ADDRESS, TRANSMISSION (SEN = 0, AHEN = 0, DHEN = 0)

DS40001579E-page 284

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

26.5.6 CLOCK STRETCHING

26.5.6.2 10-bit Addressing Mode

Clock stretching occurs when a device on the bus

holds the SCL line low effectively pausing communica-

tion. The slave may stretch the clock to allow more

time to handle data or prepare a response for the

master device. A master device is not concerned with

stretching as anytime it is active on the bus and not

transferring data it is stretching. Any stretching done

by a slave is invisible to the master software and

handled by the hardware that generates SCL.

In 10-bit Addressing mode, when the UA bit is set the

clock is always stretched. This is the only time the SCL

is stretched without CKP being cleared. SCL is

released immediately after a write to SSPADD.

Note: Previous versions of the module did not

stretch the clock if the second address byte

did not match.

26.5.6.3 Byte NACKing

The CKP bit of the SSPCON1 register is used to

control stretching in software. Any time the CKP bit is

cleared, the module will wait for the SCL line to go low

and then hold it. Setting CKP will release SCL and

allow more communication.

When AHEN bit of SSPCON3 is set; CKP is cleared by

hardware after the 8th falling edge of SCL for a

received matching address byte. When DHEN bit of

SSPCON3 is set; CKP is cleared after the 8th falling

edge of SCL for received data.

26.5.6.1 Normal Clock Stretching

Stretching after the 8th falling edge of SCL allows the

slave to look at the received address or data and

decide if it wants to ACK the received data.

Following an ACK if the R/W bit of SSPSTAT is set, a

read request, the slave hardware will clear CKP. This

allows the slave time to update SSPBUF with data to

transfer to the master. If the SEN bit of SSPCON2 is

set, the slave hardware will always stretch the clock

after the ACK sequence. Once the slave is ready; CKP

is set by software and communication resumes.

26.5.7 CLOCK SYNCHRONIZATION AND

THE CKP BIT

Any time the CKP bit is cleared, the module will wait

for the SCL line to go low and then hold it. However,

clearing the CKP bit will not assert the SCL output low

until the SCL output is already sampled low. There-

fore, the CKP bit will not assert the SCL line until an

external I²C master device has already asserted the

SCL line. The SCL output will remain low until the CKP

bit is set and all other devices on the I²C bus have

released SCL. This ensures that a write to the CKP bit

will not violate the minimum high time requirement for

SCL (see Figure 26-22).

Note 1: The BF bit has no effect on if the clock will

be stretched or not. This is different than

previous versions of the module that

would not stretch the clock, clear CKP, if

SSPBUF was read before the 9th falling

edge of SCL.

2: Previous versions of the module did not

stretch the clock for a transmission if

SSPBUF was loaded before the 9th fall-

ing edge of SCL. It is now always cleared

for read requests.

FIGURE 26-23:

CLOCK SYNCHRONIZATION TIMING

Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4

SDA

SCL

DX

DX ‚ – 1

Master device

asserts clock

CKP

Master device

releases clock

WR

SSPCON1

 2011-2014 Microchip Technology Inc.

DS40001579E-page 285

PIC16(L)F1782/3

26.5.8 GENERAL CALL ADDRESS SUPPORT

In 10-bit Address mode, the UA bit will not be set on

the reception of the general call address. The slave

will prepare to receive the second byte as data, just as

it would in 7-bit mode.

The addressing procedure for the I²C bus is such that

the first byte after the Start condition usually

determines which device will be the slave addressed

by the master device. The exception is the general call

address which can address all devices. When this

address is used, all devices should, in theory, respond

with an acknowledge.

If the AHEN bit of the SSPCON3 register is set, just as

with any other address reception, the slave hardware

will stretch the clock after the 8th falling edge of SCL.

The slave must then set its ACKDT value and release

the clock with communication progressing as it would

normally.

The general call address is a reserved address in the

I²C protocol, defined as address 0x00. When the

GCEN bit of the SSPCON2 register is set, the slave

module will automatically ACK the reception of this

address regardless of the value stored in SSPADD.

After the slave clocks in an address of all zeros with

the R/W bit clear, an interrupt is generated and slave

software can read SSPBUF and respond.

Figure 26-23 shows

sequence.

a

general call reception

FIGURE 26-24:

SLAVE MODE GENERAL CALL ADDRESS SEQUENCE

Address is compared to General Call Address

after ACK, set interrupt

Receiving Data

D5 D4 D3 D2 D1 D0

ACK

9

R/W = 0

General Call Address

ACK

SDA

D7 D6

SCL

1

2

3

4

5

6

7

8

9

1

2

3

4

5

6

7

8

S

SSP1IF

BF (SSPSTAT<0>)

Cleared by software

SSPBUF is read

GCEN (SSPCON2<7>)

’1’

26.5.9 SSP MASK REGISTER

An SSP Mask (SSPMSK) register (Register 26-5) is

available in I²C Slave mode as a mask for the value

held in the SSPSR register during an address

comparison operation. A zero (‘0’) bit in the SSPMSK

register has the effect of making the corresponding bit

of the received address a “don’t care”.

This register is reset to all ‘1’s upon any Reset

condition and, therefore, has no effect on standard

SSP operation until written with a mask value.

The SSP Mask register is active during:

• 7-bit Address mode: address compare of A<7:1>.

• 10-bit Address mode: address compare of A<7:0>

only. The SSP mask has no effect during the

reception of the first (high) byte of the address.

DS40001579E-page 286

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

26.6.1 I²C MASTER MODE OPERATION

2

26.6 I C Master Mode

The master device generates all of the serial clock

pulses and the Start and Stop conditions. A transfer is

ended with a Stop condition or with a Repeated Start

condition. Since the Repeated Start condition is also

the beginning of the next serial transfer, the I²C bus will

not be released.

Master mode is enabled by setting and clearing the

appropriate SSPM bits in the SSPCON1 register and

by setting the SSPEN bit. In Master mode, the SDA and

SCK pins must be configured as inputs. The MSSP

peripheral hardware will override the output driver TRIS

controls when necessary to drive the pins low.

In Master Transmitter mode, serial data is output

through SDA, while SCL outputs the serial clock. The

first byte transmitted contains the slave address of the

receiving device (7 bits) and the Read/Write (R/W) bit.

In this case, the R/W bit will be logic ‘0’. Serial data is

transmitted 8 bits at a time. After each byte is transmit-

ted, an Acknowledge bit is received. Start and Stop

conditions are output to indicate the beginning and the

end of a serial transfer.

Master mode of operation is supported by interrupt

generation on the detection of the Start and Stop

conditions. The Stop (P) and Start (S) bits are cleared

from a Reset or when the MSSP module is disabled.

Control of the I²C bus may be taken when the P bit is

set, or the bus is Idle.

In Firmware Controlled Master mode, user code

conducts all I²C bus operations based on Start and

Stop bit condition detection. Start and Stop condition

detection is the only active circuitry in this mode. All

other communication is done by the user software

directly manipulating the SDA and SCL lines.

In Master Receive mode, the first byte transmitted

contains the slave address of the transmitting device

(7 bits) and the R/W bit. In this case, the R/W bit will be

logic ‘1’. Thus, the first byte transmitted is a 7-bit slave

address followed by a ‘1’ to indicate the receive bit.

Serial data is received via SDA, while SCL outputs the

serial clock. Serial data is received 8 bits at a time. After

each byte is received, an Acknowledge bit is transmit-

ted. Start and Stop conditions indicate the beginning

and end of transmission.

The following events will cause the SSP Interrupt Flag

bit, SSP1IF, to be set (SSP interrupt, if enabled):

• Start condition detected

• Stop condition detected

• Data transfer byte transmitted/received

• Acknowledge transmitted/received

• Repeated Start generated

A Baud Rate Generator is used to set the clock

frequency output on SCL. See Section 26.7 “Baud

Rate Generator” for more detail.

Note 1: The MSSP module, when configured in

I²C Master mode, does not allow queue-

ing of events. For instance, the user is not

allowed to initiate a Start condition and

immediately write the SSPBUF register to

initiate transmission before the Start

condition is complete. In this case, the

SSPBUF will not be written to and the

WCOL bit will be set, indicating that a

write to the SSPBUF did not occur

2: When in Master mode, Start/Stop

detection is masked and an interrupt is

generated when the SEN/PEN bit is

cleared and the generation is complete.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 287

PIC16(L)F1782/3

26.6.2 CLOCK ARBITRATION

Clock arbitration occurs when the master, during any

receive, transmit or Repeated Start/Stop condition,

releases the SCL pin (SCL allowed to float high). When

the SCL pin is allowed to float high, the Baud Rate

Generator (BRG) is suspended from counting until the

SCL pin is actually sampled high. When the SCL pin is

sampled high, the Baud Rate Generator is reloaded

with the contents of SSPADD<7:0> and begins count-

ing. This ensures that the SCL high time will always be

at least one BRG rollover count in the event that the

clock is held low by an external device (Figure 26-25).

FIGURE 26-25:

BAUD RATE GENERATOR TIMING WITH CLOCK ARBITRATION

SDA

DX

DX ‚ – 1

SCL allowed to transition high

SCL deasserted but slave holds

SCL low (clock arbitration)

SCL

BRG decrements on

Q2 and Q4 cycles

BRG

Value

03h

02h

01h

00h (hold off)

03h

02h

SCL is sampled high, reload takes

place and BRG starts its count

BRG

Reload

26.6.3 WCOL STATUS FLAG

If the user writes the SSPBUF when a Start, Restart,

Stop, Receive or Transmit sequence is in progress, the

WCOL is set and the contents of the buffer are

unchanged (the write does not occur). Any time the

WCOL bit is set it indicates that an action on SSPBUF

was attempted while the module was not idle.

Note:

Because queuing of events is not allowed,

writing to the lower 5 bits of SSPCON2 is

disabled until the Start condition is

complete.

DS40001579E-page 288

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

2

26.6.4 I C MASTER MODE START

CONDITION TIMING

Note 1: If at the beginning of the Start condition,

the SDA and SCL pins are already

sampled low, or if during the Start condi-

tion, the SCL line is sampled low before

the SDA line is driven low, a bus collision

occurs, the Bus Collision Interrupt Flag,

BCL1IF, is set, the Start condition is

aborted and the I²C module is reset into

its Idle state.

To initiate a Start condition, the user sets the Start

Enable bit, SEN bit of the SSPCON2 register. If the

SDA and SCL pins are sampled high, the Baud Rate

Generator is reloaded with the contents of

SSPADD<7:0> and starts its count. If SCL and SDA

are both sampled high when the Baud Rate Generator

times out (TBRG), the SDA pin is driven low. The action

of the SDA being driven low while SCL is high is the

Start condition and causes the S bit of the SSPSTAT1

register to be set. Following this, the Baud Rate

Generator is reloaded with the contents of

SSPADD<7:0> and resumes its count. When the Baud

Rate Generator times out (TBRG), the SEN bit of the

SSPCON2 register will be automatically cleared by

hardware; the Baud Rate Generator is suspended,

leaving the SDA line held low and the Start condition is

complete.

2: The Philips I²C specification states that a

bus collision cannot occur on a Start.

FIGURE 26-26:

FIRST START BIT TIMING

Set S bit (SSPSTAT<3>)

Write to SEN bit occurs here

At completion of Start bit,

hardware clears SEN bit

and sets SSP1IF bit

SDA = 1,

SCL = 1

TBRG

Write to SSPBUF occurs here

1st bit

2nd bit

SDA

TBRG

SCL

S

TBRG

 2011-2014 Microchip Technology Inc.

DS40001579E-page 289

PIC16(L)F1782/3

2

26.6.5 I C MASTER MODE REPEATED

CON2 register will be automatically cleared and the

Baud Rate Generator will not be reloaded, leaving the

SDA pin held low. As soon as a Start condition is

detected on the SDA and SCL pins, the S bit of the

SSPSTAT register will be set. The SSP1IF bit will not

be set until the Baud Rate Generator has timed out.

START CONDITION TIMING

A Repeated Start condition occurs when the RSEN bit

of the SSPCON2 register is programmed high and the

master state machine is no longer active. When the

RSEN bit is set, the SCL pin is asserted low. When the

SCL pin is sampled low, the Baud Rate Generator is

loaded and begins counting. The SDA pin is released

(brought high) for one Baud Rate Generator count

(TBRG). When the Baud Rate Generator times out, if

SDA is sampled high, the SCL pin will be deasserted

(brought high). When SCL is sampled high, the Baud

Rate Generator is reloaded and begins counting. SDA

and SCL must be sampled high for one TBRG. This

action is then followed by assertion of the SDA pin

(SDA = 0) for one TBRG while SCL is high. SCL is

asserted low. Following this, the RSEN bit of the SSP-

Note 1: If RSEN is programmed while any other

event is in progress, it will not take effect.

2: A bus collision during the Repeated Start

condition occurs if:

• SDA is sampled low when SCL

goes from low-to-high.

• SCL goes low before SDA is

asserted low. This may indicate

that another master is attempting

to transmit a data ‘1’.

FIGURE 26-27:

REPEAT START CONDITION WAVEFORM

S bit set by hardware

Write to SSPCON2

occurs here

SDA = 1,

At completion of Start bit,

hardware clears RSEN bit

and sets SSP1IF

SDA = 1,

SCL = 1

SCL (no change)

TBRG

1st bit

SDA

SCL

Write to SSPBUF occurs here

TBRG

Sr

Repeated Start

TBRG

DS40001579E-page 290

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

26.6.6 I²C MASTER MODE TRANSMISSION

26.6.6.3

ACKSTAT Status Flag

In Transmit mode, the ACKSTAT bit of the SSPCON2

register is cleared when the slave has sent an Acknowl-

edge (ACK = 0) and is set when the slave does not

Acknowledge (ACK = 1). A slave sends an Acknowl-

edge when it has recognized its address (including a

general call), or when the slave has properly received

its data.

Transmission of a data byte, a 7-bit address or the

other half of a 10-bit address is accomplished by simply

writing a value to the SSPBUF register. This action will

set the Buffer Full flag bit, BF and allow the Baud Rate

Generator to begin counting and start the next trans-

mission. Each bit of address/data will be shifted out

onto the SDA pin after the falling edge of SCL is

asserted. SCL is held low for one Baud Rate Generator

rollover count (TBRG). Data should be valid before SCL

is released high. When the SCL pin is released high, it

is held that way for TBRG. The data on the SDA pin

must remain stable for that duration and some hold

time after the next falling edge of SCL. After the eighth

bit is shifted out (the falling edge of the eighth clock),

the BF flag is cleared and the master releases SDA.

This allows the slave device being addressed to

respond with an ACK bit during the ninth bit time if an

address match occurred, or if data was received

properly. The status of ACK is written into the

ACKSTAT bit on the rising edge of the ninth clock. If the

master receives an Acknowledge, the Acknowledge

Status bit, ACKSTAT, is cleared. If not, the bit is set.

After the ninth clock, the SSP1IF bit is set and the mas-

ter clock (Baud Rate Generator) is suspended until the

next data byte is loaded into the SSPBUF, leaving SCL

low and SDA unchanged (Figure 26-27).

26.6.6.4 Typical transmit sequence:

1. The user generates a Start condition by setting

the SEN bit of the SSPCON2 register.

2. SSP1IF is set by hardware on completion of the

Start.

3. SSP1IF is cleared by software.

4. The MSSP module will wait the required start

time before any other operation takes place.

5. The user loads the SSPBUF with the slave

address to transmit.

6. Address is shifted out the SDA pin until all 8 bits

are transmitted. Transmission begins as soon

as SSPBUF is written to.

7. The MSSP module shifts in the ACK bit from the

slave device and writes its value into the

ACKSTAT bit of the SSPCON2 register.

8. The MSSP module generates an interrupt at the

end of the ninth clock cycle by setting the

SSP1IF bit.

After the write to the SSPBUF, each bit of the address

will be shifted out on the falling edge of SCL until all

seven address bits and the R/W bit are completed. On

the falling edge of the eighth clock, the master will

release the SDA pin, allowing the slave to respond with

an Acknowledge. On the falling edge of the ninth clock,

the master will sample the SDA pin to see if the address

was recognized by a slave. The status of the ACK bit is

loaded into the ACKSTAT Status bit of the SSPCON2

register. Following the falling edge of the ninth clock

transmission of the address, the SSP1IF is set, the BF

flag is cleared and the Baud Rate Generator is turned

off until another write to the SSPBUF takes place,

holding SCL low and allowing SDA to float.

9. The user loads the SSPBUF with eight bits of

data.

10. Data is shifted out the SDA pin until all 8 bits are

transmitted.

11. The MSSP module shifts in the ACK bit from the

slave device and writes its value into the

ACKSTAT bit of the SSPCON2 register.

12. Steps 8-11 are repeated for all transmitted data

bytes.

13. The user generates a Stop or Restart condition

by setting the PEN or RSEN bits of the SSP-

CON2 register. Interrupt is generated once the

Stop/Restart condition is complete.

26.6.6.1

BF Status Flag

In Transmit mode, the BF bit of the SSPSTAT register

is set when the CPU writes to SSPBUF and is cleared

when all 8 bits are shifted out.

26.6.6.2

WCOL Status Flag

If the user writes the SSPBUF when a transmit is

already in progress (i.e., SSPSR is still shifting out a

data byte), the WCOL is set and the contents of the

buffer are unchanged (the write does not occur).

WCOL must be cleared by software before the next

transmission.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 291

PIC16(L)F1782/3

2

FIGURE 26-28:

I C MASTER MODE WAVEFORM (TRANSMISSION, 7 OR 10-BIT ADDRESS)

DS40001579E-page 292

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

I²C MASTER MODE RECEPTION

26.6.7.4 Typical Receive Sequence:

26.6.7

Master mode reception is enabled by programming the

Receive Enable bit, RCEN bit of the SSPCON2

register.

1. The user generates a Start condition by setting

the SEN bit of the SSPCON2 register.

2. SSP1IF is set by hardware on completion of the

Start.

Note:

The MSSP module must be in an Idle

state before the RCEN bit is set or the

RCEN bit will be disregarded.

3. SSP1IF is cleared by software.

4. User writes SSPBUF with the slave address to

transmit and the R/W bit set.

The Baud Rate Generator begins counting and on each

rollover, the state of the SCL pin changes

(high-to-low/low-to-high) and data is shifted into the

SSPSR. After the falling edge of the eighth clock, the

receive enable flag is automatically cleared, the

contents of the SSPSR are loaded into the SSPBUF,

the BF flag bit is set, the SSP1IF flag bit is set and the

Baud Rate Generator is suspended from counting,

holding SCL low. The MSSP is now in Idle state

awaiting the next command. When the buffer is read by

the CPU, the BF flag bit is automatically cleared. The

user can then send an Acknowledge bit at the end of

reception by setting the Acknowledge Sequence

Enable, ACKEN bit of the SSPCON2 register.

5. Address is shifted out the SDA pin until all 8 bits

are transmitted. Transmission begins as soon

as SSPBUF is written to.

6. The MSSP module shifts in the ACK bit from the

slave device and writes its value into the

ACKSTAT bit of the SSPCON2 register.

7. The MSSP module generates an interrupt at the

end of the ninth clock cycle by setting the

SSP1IF bit.

8. User sets the RCEN bit of the SSPCON2 register

and the master clocks in a byte from the slave.

9. After the 8th falling edge of SCL, SSP1IF and

BF are set.

10. User clears the SSP1IF bit and reads the received

byte from SSPUF, which clears the BF flag.

26.6.7.1

BF Status Flag

In receive operation, the BF bit is set when an address

or data byte is loaded into SSPBUF from SSPSR. It is

cleared when the SSPBUF register is read.

11. The user either clears the SSPCON2 register’s

ACKDT bit to receive another byte or sets the

ADKDT bit to suppress further data and then initi-

ates the acknowledge sequence by setting the

ACKEN bit.

26.6.7.2

SSPOV Status Flag

In receive operation, the SSPOV bit is set when 8 bits

are received into the SSPSR and the BF flag bit is

already set from a previous reception.

12. Master’s ACK or ACK is clocked out to the slave

and SSP1IF is set.

13. User clears SSP1IF.

26.6.7.3

WCOL Status Flag

14. Steps 8-13 are repeated for each received byte

from the slave.

If the user writes the SSPBUF when a receive is

already in progress (i.e., SSPSR is still shifting in a data

byte), the WCOL bit is set and the contents of the buffer

are unchanged (the write does not occur).

15. If the ACKST bit was set in step 11 then the user

can send a STOP to release the bus.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 293

PIC16(L)F1782/3

2

FIGURE 26-29:

I C MASTER MODE WAVEFORM (RECEPTION, 7-BIT ADDRESS)

DS40001579E-page 294

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

26.6.8

ACKNOWLEDGE SEQUENCE

TIMING

26.6.9

STOP CONDITION TIMING

A Stop bit is asserted on the SDA pin at the end of a

receive/transmit by setting the Stop Sequence Enable

bit, PEN bit of the SSPCON2 register. At the end of a

receive/transmit, the SCL line is held low after the

falling edge of the ninth clock. When the PEN bit is set,

the master will assert the SDA line low. When the SDA

line is sampled low, the Baud Rate Generator is

reloaded and counts down to ‘0’. When the Baud Rate

Generator times out, the SCL pin will be brought high

and one TBRG (Baud Rate Generator rollover count)

later, the SDA pin will be deasserted. When the SDA

pin is sampled high while SCL is high, the P bit of the

SSPSTAT register is set. A TBRG later, the PEN bit is

cleared and the SSP1IF bit is set (Figure 26-30).

An Acknowledge sequence is enabled by setting the

Acknowledge Sequence Enable bit, ACKEN bit of the

SSPCON2 register. When this bit is set, the SCL pin is

pulled low and the contents of the Acknowledge data bit

are presented on the SDA pin. If the user wishes to

generate an Acknowledge, then the ACKDT bit should

be cleared. If not, the user should set the ACKDT bit

before starting an Acknowledge sequence. The Baud

Rate Generator then counts for one rollover period

(TBRG) and the SCL pin is deasserted (pulled high).

When the SCL pin is sampled high (clock arbitration),

the Baud Rate Generator counts for TBRG. The SCL pin

is then pulled low. Following this, the ACKEN bit is auto-

matically cleared, the Baud Rate Generator is turned off

and the MSSP module then goes into Idle mode

(Figure 26-29).

26.6.9.1

WCOL Status Flag

If the user writes the SSPBUF when a Stop sequence

is in progress, then the WCOL bit is set and the

contents of the buffer are unchanged (the write does

not occur).

26.6.8.1

WCOL Status Flag

If the user writes the SSPBUF when an Acknowledge

sequence is in progress, then WCOL is set and the

contents of the buffer are unchanged (the write does

not occur).

FIGURE 26-30:

ACKNOWLEDGE SEQUENCE WAVEFORM

Acknowledge sequence starts here,

write to SSPCON2

ACKEN automatically cleared

ACKEN = 1, ACKDT = 0

TBRG

ACK

TBRG

SDA

SCL

D0

8

9

SSP1IF

Cleared in

SSP1IF set at

the end of receive

software

Cleared in

software

SSP1IF set at the end

of Acknowledge sequence

Note: TBRG = one Baud Rate Generator period.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 295

PIC16(L)F1782/3

FIGURE 26-31:

STOP CONDITION RECEIVE OR TRANSMIT MODE

SCL = 1for TBRG, followed by SDA = 1for TBRG

after SDA sampled high. P bit (SSPSTAT<4>) is set.

Write to SSPCON2,

set PEN

PEN bit (SSPCON2<2>) is cleared by

hardware and the SSP1IF bit is set

Falling edge of

9th clock

TBRG

SCL

SDA

ACK

P

TBRG

SCL brought high after TBRG

SDA asserted low before rising edge of clock

to setup Stop condition

Note: TBRG = one Baud Rate Generator period.

26.6.10 SLEEP OPERATION

26.6.13 MULTI -MASTER COMMUNICATION,

BUS COLLISION AND BUS

While in Sleep mode, the I²C slave module can receive

addresses or data and when an address match or

complete byte transfer occurs, wake the processor

from Sleep (if the MSSP interrupt is enabled).

ARBITRATION

Multi-Master mode support is achieved by bus arbitra-

tion. When the master outputs address/data bits onto

the SDA pin, arbitration takes place when the master

outputs a ‘1’ on SDA, by letting SDA float high and

another master asserts a ‘0’. When the SCL pin floats

high, data should be stable. If the expected data on

SDA is a ‘1’ and the data sampled on the SDA pin is ‘0’,

then a bus collision has taken place. The master will set

the Bus Collision Interrupt Flag, BCL1IF and reset the

I²C port to its Idle state (Figure 26-31).

26.6.11 EFFECTS OF A RESET

A Reset disables the MSSP module and terminates the

current transfer.

26.6.12 MULTI-MASTER MODE

In Multi-Master mode, the interrupt generation on the

detection of the Start and Stop conditions allows the

determination of when the bus is free. The Stop (P) and

Start (S) bits are cleared from a Reset or when the

MSSP module is disabled. Control of the I²C bus may

be taken when the P bit of the SSPSTAT register is set,

or the bus is Idle, with both the S and P bits clear. When

the bus is busy, enabling the SSP interrupt will

generate the interrupt when the Stop condition occurs.

If a transmit was in progress when the bus collision

occurred, the transmission is halted, the BF flag is

cleared, the SDA and SCL lines are deasserted and the

SSPBUF can be written to. When the user services the

bus collision Interrupt Service Routine and if the I²C

bus is free, the user can resume communication by

asserting a Start condition.

In multi-master operation, the SDA line must be

monitored for arbitration to see if the signal level is the

expected output level. This check is performed by

hardware with the result placed in the BCL1IF bit.

If a Start, Repeated Start, Stop or Acknowledge

condition was in progress when the bus collision

occurred, the condition is aborted, the SDA and SCL

lines are deasserted and the respective control bits in

the SSPCON2 register are cleared. When the user

services the bus collision Interrupt Service Routine and

if the I²C bus is free, the user can resume communica-

tion by asserting a Start condition.

The states where arbitration can be lost are:

• Address Transfer

• Data Transfer

• A Start Condition

The master will continue to monitor the SDA and SCL

pins. If a Stop condition occurs, the SSP1IF bit will be set.

• A Repeated Start Condition

• An Acknowledge Condition

A write to the SSPBUF will start the transmission of

data at the first data bit, regardless of where the

transmitter left off when the bus collision occurred.

In Multi-Master mode, the interrupt generation on the

detection of Start and Stop conditions allows the deter-

mination of when the bus is free. Control of the I²C bus

can be taken when the P bit is set in the SSPSTAT

register, or the bus is Idle and the S and P bits are

cleared.

DS40001579E-page 296

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 26-32:

BUS COLLISION TIMING FOR TRANSMIT AND ACKNOWLEDGE

Sample SDA. While SCL is high,

data does not match what is driven

by the master.

Data changes

while SCL = 0

SDA line pulled low

by another source

Bus collision has occurred.

SDA released

by master

SDA

SCL

Set bus collision

interrupt (BCL1IF)

BCL1IF

 2011-2014 Microchip Technology Inc.

DS40001579E-page 297

PIC16(L)F1782/3

If the SDA pin is sampled low during this count, the

BRG is reset and the SDA line is asserted early

(Figure 26-34). If, however, a ‘1’ is sampled on the SDA

pin, the SDA pin is asserted low at the end of the BRG

count. The Baud Rate Generator is then reloaded and

counts down to zero; if the SCL pin is sampled as ‘0’

during this time, a bus collision does not occur. At the

end of the BRG count, the SCL pin is asserted low.

26.6.13.1 Bus Collision During a Start

Condition

During a Start condition, a bus collision occurs if:

a) SDA or SCL are sampled low at the beginning of

the Start condition (Figure 26-32).

b) SCL is sampled low before SDA is asserted low

(Figure 26-33).

During a Start condition, both the SDA and the SCL

pins are monitored.

Note:

The reason that bus collision is not a fac-

tor during a Start condition is that no two

bus masters can assert a Start condition

at the exact same time. Therefore, one

master will always assert SDA before the

other. This condition does not cause a bus

collision because the two masters must be

allowed to arbitrate the first address

following the Start condition. If the address

is the same, arbitration must be allowed to

continue into the data portion, Repeated

Start or Stop conditions.

If the SDA pin is already low, or the SCL pin is already

low, then all of the following occur:

• the Start condition is aborted,

• the BCL1IF flag is set and

•

the MSSP module is reset to its Idle state

(Figure 26-32).

The Start condition begins with the SDA and SCL pins

deasserted. When the SDA pin is sampled high, the

Baud Rate Generator is loaded and counts down. If the

SCL pin is sampled low while SDA is high, a bus colli-

sion occurs because it is assumed that another master

is attempting to drive a data ‘1’ during the Start

condition.

FIGURE 26-33:

BUS COLLISION DURING START CONDITION (SDA ONLY)

SDA goes low before the SEN bit is set.

Set BCL1IF,

S bit and SSP1IF set because

SDA = 0, SCL = 1.

SDA

SCL

SEN

Set SEN, enable Start

condition if SDA = 1, SCL = 1

SEN cleared automatically because of bus collision.

SSP module reset into Idle state.

SDA sampled low before

Start condition. Set BCL1IF.

S bit and SSP1IF set because

SDA = 0, SCL = 1.

BCL1IF

SSP1IF and BCL1IF are

cleared by software

S

SSP1IF

SSP1IF and BCL1IF are

cleared by software

DS40001579E-page 298

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 26-34:

BUS COLLISION DURING START CONDITION (SCL = 0)

SDA = 0, SCL = 1

TBRG

SDA

Set SEN, enable Start

sequence if SDA = 1, SCL = 1

SCL

SEN

SCL = 0before SDA = 0,

bus collision occurs. Set BCL1IF.

SCL = 0before BRG time-out,

bus collision occurs. Set BCL1IF.

BCL1IF

Interrupt cleared

by software

S

’0’

SSP1IF

FIGURE 26-35:

BRG RESET DUE TO SDA ARBITRATION DURING START CONDITION

SDA = 0, SCL = 1

Set S

Set SSP1IF

Less than TBRG

TBRG

SDA pulled low by other master.

Reset BRG and assert SDA.

SDA

SCL

S

SCL pulled low after BRG

time-out

SEN

Set SEN, enable Start

sequence if SDA = 1, SCL = 1

’0’

BCL1IF

S

SSP1IF

Interrupts cleared

by software

SDA = 0, SCL = 1,

set SSP1IF

 2011-2014 Microchip Technology Inc.

DS40001579E-page 299

PIC16(L)F1782/3

If SDA is low, a bus collision has occurred (i.e., another

master is attempting to transmit a data ‘0’, Figure 26-35).

If SDA is sampled high, the BRG is reloaded and begins

counting. If SDA goes from high-to-low before the BRG

times out, no bus collision occurs because no two

masters can assert SDA at exactly the same time.

26.6.13.2 Bus Collision During a Repeated

Start Condition

During a Repeated Start condition, a bus collision

occurs if:

a) A low level is sampled on SDA when SCL goes

from low level to high level.

If SCL goes from high-to-low before the BRG times out

and SDA has not already been asserted, a bus collision

occurs. In this case, another master is attempting to

transmit a data ‘1’ during the Repeated Start condition,

see Figure 26-36.

b) SCL goes low before SDA is asserted low,

indicating that another master is attempting to

transmit a data ‘1’.

When the user releases SDA and the pin is allowed to

float high, the BRG is loaded with SSPADD and counts

down to zero. The SCL pin is then deasserted and

when sampled high, the SDA pin is sampled.

If, at the end of the BRG time-out, both SCL and SDA

are still high, the SDA pin is driven low and the BRG is

reloaded and begins counting. At the end of the count,

regardless of the status of the SCL pin, the SCL pin is

driven low and the Repeated Start condition is

complete.

FIGURE 26-36:

BUS COLLISION DURING A REPEATED START CONDITION (CASE 1)

SDA

SCL

Sample SDA when SCL goes high.

If SDA = 0, set BCL1IF and release SDA and SCL.

RSEN

BCL1IF

Cleared by software

’0’

S

’0’

SSP1IF

FIGURE 26-37:

BUS COLLISION DURING REPEATED START CONDITION (CASE 2)

TBRG

SDA

SCL

SCL goes low before SDA,

set BCL1IF. Release SDA and SCL.

BCL1IF

RSEN

Interrupt cleared

by software

’0’

S

SSP1IF

DS40001579E-page 300

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

The Stop condition begins with SDA asserted low.

When SDA is sampled low, the SCL pin is allowed to

float. When the pin is sampled high (clock arbitration),

the Baud Rate Generator is loaded with SSPADD and

counts down to 0. After the BRG times out, SDA is

sampled. If SDA is sampled low, a bus collision has

occurred. This is due to another master attempting to

drive a data ‘0’ (Figure 26-37). If the SCL pin is sampled

low before SDA is allowed to float high, a bus collision

occurs. This is another case of another master

attempting to drive a data ‘0’ (Figure 26-38).

26.6.13.3 Bus Collision During a Stop

Condition

Bus collision occurs during a Stop condition if:

a) After the SDA pin has been deasserted and

allowed to float high, SDA is sampled low after

the BRG has timed out.

b) After the SCL pin is deasserted, SCL is sampled

low before SDA goes high.

FIGURE 26-38:

BUS COLLISION DURING A STOP CONDITION (CASE 1)

SDA sampled

low after TBRG,

set BCL1IF

TBRG

SDA

SDA asserted low

SCL

PEN

BCL1IF

P

’0’

SSP1IF

FIGURE 26-39:

BUS COLLISION DURING A STOP CONDITION (CASE 2)

TBRG

SDA

SCL goes low before SDA goes high,

set BCL1IF

Assert SDA

SCL

PEN

BCL1IF

P

’0’

SSP1IF

 2011-2014 Microchip Technology Inc.

DS40001579E-page 301

PIC16(L)F1782/3

TABLE 26-3: SUMMARY OF REGISTERS ASSOCIATED WITH I²C™ OPERATION

Reset

Valueson

Page:

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

APFCON

INTCON

PIE1

C2OUTSEL CCP1SEL

SDOSEL

TMR0IE

RCIE

SCKSEL

INTE

SDISEL

IOCIE

TXSEL

TMR0IF

CCP1IE

RXSEL

INTF

CCP2SEL

IOCIF

111

79

GIE

PEIE

ADIE

TMR1GIE

TXIE

SSP1IE

TMR2IE

TMR1IE

80

81

PIE2

PIR1

OSFIE

C2IE

ADIF

C1IE

RCIF

EEIE

TXIF

BCL1IE

SSP1IF

—

C3IE

CCP2IE

TMR1IF

TMR1GIF

CCP1IF

TMR2IF

83

84

PIR2

OSFIF

C2IF

C1IF

EEIF

BCL1IF

—

C3IF

CCP2IF

SSP1ADD

SSP1BUF

309

ADD<7:0>

Synchronous Serial Port Receive Buffer/Transmit Register

260*

306

307

306

309

304

125

SSP1CON1

SSP1CON2

SSP1CON3

SSP1MSK

SSP1STAT

TRISC

WCOL

GCEN

SSPOV

ACKSTAT

PCIE

SSPEN

ACKDT

SCIE

CKP

ACKEN

BOEN

SSPM<3:0>

RCEN

PEN

RSEN

AHEN

SEN

ACKTIM

SDAHT

SBCDE

DHEN

MSK<7:0>

SMP

CKE

D/A

P

S

R/W

UA

BF

TRISC7

TRISC6

TRISC5

TRISC4

TRISC3

TRISC2

TRISC1

TRISA0

Legend:

— = unimplemented location, read as ‘0’. Shaded cells are not used by the MSSP module in I²C™ mode.

*

Page provides register information.

Note 1: PIC16(L)F1783 only.

DS40001579E-page 302

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

clock line. The logic dictating when the reload signal is

asserted depends on the mode the MSSP is being

operated in.

26.7 BAUD RATE GENERATOR

The MSSP module has a Baud Rate Generator

available for clock generation in both I²C and SPI

Master modes. The Baud Rate Generator (BRG)

reload value is placed in the SSPADD register

(Register 26-6). When a write occurs to SSPBUF, the

Baud Rate Generator will automatically begin counting

down.

Table 26-4 demonstrates clock rates based on

instruction cycles and the BRG value loaded into

SSPADD.

EQUATION 26-1:

Once the given operation is complete, the internal clock

will automatically stop counting and the clock pin will

remain in its last state.

FOSC

FCLOCK = -------------------------------------------------

SSPxADD + 14

An internal signal “Reload” in Figure 26-39 triggers the

value from SSPADD to be loaded into the BRG counter.

This occurs twice for each oscillation of the module

FIGURE 26-40:

BAUD RATE GENERATOR BLOCK DIAGRAM

SSPM<3:0>

SSPADD<7:0>

SSPM<3:0>

SCL

Reload

Control

Reload

BRG Down Counter

SSPCLK

FOSC/2

Note: Values of 0x00, 0x01 and 0x02 are not valid

for SSPADD when used as a Baud Rate

Generator for I²C. This is an implementation

limitation.

TABLE 26-4: MSSP CLOCK RATE W/BRG

FCLOCK

(2 Rollovers of BRG)

FOSC

FCY

BRG Value

32 MHz

16 MHz

4 MHz

8 MHz

4 MHz

1 MHz

13h

19h

4Fh

09h

0Ch

27h

09h

400 kHz⁽¹⁾

308 kHz

100 kHz

400 kHz⁽¹⁾

308 kHz

100 kHz

Note 1: The I²C interface does not conform to the 400 kHz I²C specification (which applies to rates greater than

100 kHz) in all details, but may be used with care where higher rates are required by the application.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 303

PIC16(L)F1782/3

26.8 Register Definitions: MSSP Control

REGISTER 26-1: SSPSTAT: SSP STATUS REGISTER

R/W-0/0

SMP

R/W-0/0

CKE

R-0/0

D/A

R-0/0

P

R-0/0

S

R-0/0

R/W

R-0/0

UA

R-0/0

BF

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

bit 7

SMP: SPI Data Input Sample bit

SPI Master mode:

1= Input data sampled at end of data output time

0= Input data sampled at middle of data output time

SPI Slave mode:

SMP must be cleared when SPI is used in Slave mode

In I²C Master or Slave mode:

1 = Slew rate control disabled for standard speed mode (100 kHz and 1 MHz)

0 = Slew rate control enabled for high speed mode (400 kHz)

bit 6

CKE: SPI Clock Edge Select bit (SPI mode only)

In SPI Master or Slave mode:

1= Transmit occurs on transition from active to Idle clock state

0= Transmit occurs on transition from Idle to active clock state

In I²C™ mode only:

1= Enable input logic so that thresholds are compliant with SMBus specification

0= Disable SMBus specific inputs

bit 5

bit 4

D/A: Data/Address bit (I²C mode only)

1= Indicates that the last byte received or transmitted was data

0= Indicates that the last byte received or transmitted was address

P: Stop bit

(I²C mode only. This bit is cleared when the MSSP module is disabled, SSPEN is cleared.)

1= Indicates that a Stop bit has been detected last (this bit is ‘0’ on Reset)

0= Stop bit was not detected last

bit 3

bit 2

S: Start bit

(I²C mode only. This bit is cleared when the MSSP module is disabled, SSPEN is cleared.)

1= Indicates that a Start bit has been detected last (this bit is ‘0’ on Reset)

0= Start bit was not detected last

R/W: Read/Write bit information (I²C mode only)

This bit holds the R/W bit information following the last address match. This bit is only valid from the address match

to the next Start bit, Stop bit, or not ACK bit.

In I²C Slave mode:

1= Read

0= Write

In I²C Master mode:

1= Transmit is in progress

0= Transmit is not in progress

OR-ing this bit with SEN, RSEN, PEN, RCEN or ACKEN will indicate if the MSSP is in Idle mode.

bit 1

UA: Update Address bit (10-bit I²C mode only)

1= Indicates that the user needs to update the address in the SSPADD register

0= Address does not need to be updated

DS40001579E-page 304

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 26-1: SSPSTAT: SSP STATUS REGISTER (CONTINUED)

bit 0

BF: Buffer Full Status bit

Receive (SPI and I²C modes):

1= Receive complete, SSPBUF is full

0= Receive not complete, SSPBUF is empty

Transmit (I²C mode only):

1= Data transmit in progress (does not include the ACK and Stop bits), SSPBUF is full

0= Data transmit complete (does not include the ACK and Stop bits), SSPBUF is empty

 2011-2014 Microchip Technology Inc.

DS40001579E-page 305

PIC16(L)F1782/3

REGISTER 26-2: SSPCON1: SSP CONTROL REGISTER 1

R/C/HS-0/0

WCOL

R/C/HS-0/0

SSPOV

R/W-0/0

SSPEN

R/W-0/0

CKP

R/W-0/0

SSPM<3:0>

bit 7

bit 0

Legend:

R = Readable bit

u = Bit is unchanged

‘1’ = Bit is set

W = Writable bit

x = Bit is unknown

‘0’ = Bit is cleared

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

HS = Bit is set by hardware C = User cleared

bit 7

WCOL: Write Collision Detect bit

Master mode:

1= A write to the SSPBUF register was attempted while the I²C conditions were not valid for a transmission to be started

0= No collision

Slave mode:

1= The SSPBUF register is written while it is still transmitting the previous word (must be cleared in software)

0= No collision

bit 6

SSPOV: Receive Overflow Indicator bit⁽¹⁾

In SPI mode:

1= A new byte is received while the SSPBUF register is still holding the previous data. In case of overflow, the data in SSPSR is lost.

Overflow can only occur in Slave mode. In Slave mode, the user must read the SSPBUF, even if only transmitting data, to avoid

setting overflow. In Master mode, the overflow bit is not set since each new reception (and transmission) is initiated by writing to the

SSPBUF register (must be cleared in software).

0= No overflow

In I²C mode:

1= A byte is received while the SSPBUF register is still holding the previous byte. SSPOV is a “don’t care” in Transmit mode

(must be cleared in software).

0= No overflow

bit 5

SSPEN: Synchronous Serial Port Enable bit

In both modes, when enabled, these pins must be properly configured as input or output

In SPI mode:

1= Enables serial port and configures SCK, SDO, SDI and SS as the source of the serial port pins⁽²⁾

0= Disables serial port and configures these pins as I/O port pins

In I²C mode:

1= Enables the serial port and configures the SDA and SCL pins as the source of the serial port pins⁽³⁾

0= Disables serial port and configures these pins as I/O port pins

bit 4

CKP: Clock Polarity Select bit

In SPI mode:

1= Idle state for clock is a high level

0= Idle state for clock is a low level

In I²C Slave mode:

SCL release control

1= Enable clock

0= Holds clock low (clock stretch). (Used to ensure data setup time.)

In I²C Master mode:

Unused in this mode

bit 3-0

SSPM<3:0>: Synchronous Serial Port Mode Select bits

0000= SPI Master mode, clock = FOSC/4

0001= SPI Master mode, clock = FOSC/16

0010= SPI Master mode, clock = FOSC/64

0011= SPI Master mode, clock = TMR2 output/2

0100= SPI Slave mode, clock = SCK pin, SS pin control enabled

0101= SPI Slave mode, clock = SCK pin, SS pin control disabled, SS can be used as I/O pin

0110= I²C Slave mode, 7-bit address

0111= I²C Slave mode, 10-bit address

1000= I²C Master mode, clock = FOSC / (4 * (SSPADD+1))⁽⁴⁾

1001= Reserved

1010= SPI Master mode, clock = FOSC/(4 * (SSPADD+1))⁽⁵⁾

1011= I²C firmware controlled Master mode (Slave idle)

1100= Reserved

1101= Reserved

1110= I²C Slave mode, 7-bit address with Start and Stop bit interrupts enabled

1111= I²C Slave mode, 10-bit address with Start and Stop bit interrupts enabled

Note 1:

In Master mode, the overflow bit is not set since each new reception (and transmission) is initiated by writing to the SSPBUF register.

When enabled, these pins must be properly configured as input or output.

When enabled, the SDA and SCL pins must be configured as inputs.

2:

3:

4:

5:

SSPADD values of 0, 1 or 2 are not supported for I²C mode.

SSPADD value of ‘0’ is not supported. Use SSPM = 0000instead.

DS40001579E-page 306

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 26-3: SSPCON2: SSP CONTROL REGISTER 2

R/W-0/0

GCEN

R-0/0

R/W-0/0

ACKDT

R/S/HS-0/0 R/S/HS-0/0

ACKEN RCEN

R/S/HS-0/0

PEN

R/S/HS-0/0 R/W/HS-0/0

RSEN SEN

bit 0

ACKSTAT

bit 7

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

-n/n = Value at POR and BOR/Value at all other Resets

HC = Cleared by hardware S = User set

bit 7

bit 6

bit 5

GCEN: General Call Enable bit (in I²C Slave mode only)

1= Enable interrupt when a general call address (0x00 or 00h) is received in the SSPSR

0= General call address disabled

ACKSTAT: Acknowledge Status bit (in I²C mode only)

1= Acknowledge was not received

0= Acknowledge was received

ACKDT: Acknowledge Data bit (in I²C mode only)

In Receive mode:

Value transmitted when the user initiates an Acknowledge sequence at the end of a receive

1= Not Acknowledge

0= Acknowledge

bit 4

ACKEN: Acknowledge Sequence Enable bit (in I²C Master mode only)

In Master Receive mode:

1= Initiate Acknowledge sequence on SDA and SCL pins, and transmit ACKDT data bit.

Automatically cleared by hardware.

0= Acknowledge sequence idle

bit 3

bit 2

RCEN: Receive Enable bit (in I²C Master mode only)

1= Enables Receive mode for I²C

0= Receive idle

PEN: Stop Condition Enable bit (in I²C Master mode only)

SCKMSSP Release Control:

1= Initiate Stop condition on SDA and SCL pins. Automatically cleared by hardware.

0= Stop condition Idle

bit 1

bit 0

RSEN: Repeated Start Condition Enable bit (in I²C Master mode only)

1= Initiate Repeated Start condition on SDA and SCL pins. Automatically cleared by hardware.

0= Repeated Start condition Idle

SEN: Start Condition Enable/Stretch Enable bit

In Master mode:

1= Initiate Start condition on SDA and SCL pins. Automatically cleared by hardware.

0= Start condition Idle

In Slave mode:

1= Clock stretching is enabled for both slave transmit and slave receive (stretch enabled)

0= Clock stretching is disabled

Note 1: For bits ACKEN, RCEN, PEN, RSEN, SEN: If the I²C module is not in the Idle mode, this bit may not be

set (no spooling) and the SSPBUF may not be written (or writes to the SSPBUF are disabled).

 2011-2014 Microchip Technology Inc.

DS40001579E-page 307

PIC16(L)F1782/3

REGISTER 26-4: SSPCON3: SSP CONTROL REGISTER 3

R-0/0

R/W-0/0

PCIE

R/W-0/0

SCIE

R/W-0/0

BOEN

R/W-0/0

SDAHT

R/W-0/0

SBCDE

R/W-0/0

AHEN

R/W-0/0

DHEN

ACKTIM

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

bit 6

bit 5

bit 4

ACKTIM: Acknowledge Time Status bit (I²C mode only)⁽³⁾

1= Indicates the I²C bus is in an Acknowledge sequence, set on 8^THfalling edge of SCL clock

0= Not an Acknowledge sequence, cleared on 9^THrising edge of SCL clock

PCIE: Stop Condition Interrupt Enable bit (I²C mode only)

1= Enable interrupt on detection of Stop condition

0= Stop detection interrupts are disabled⁽²⁾

SCIE: Start Condition Interrupt Enable bit (I²C mode only)

1= Enable interrupt on detection of Start or Restart conditions

0= Start detection interrupts are disabled⁽²⁾

BOEN: Buffer Overwrite Enable bit

In SPI Slave mode:⁽¹⁾

1= SSPBUF updates every time that a new data byte is shifted in ignoring the BF bit

0 = If new byte is received with BF bit of the SSPSTAT register already set, SSPOV bit of the

SSPCON1 register is set, and the buffer is not updated

In I²C Master mode and SPI Master mode:

This bit is ignored.

In I²C Slave mode:

1= SSPBUF is updated and ACK is generated for a received address/data byte, ignoring the state

of the SSPOV bit only if the BF bit = 0.

0= SSPBUF is only updated when SSPOV is clear

bit 3

bit 2

SDAHT: SDA Hold Time Selection bit (I²C mode only)

1= Minimum of 300 ns hold time on SDA after the falling edge of SCL

0= Minimum of 100 ns hold time on SDA after the falling edge of SCL

SBCDE: Slave Mode Bus Collision Detect Enable bit (I²C Slave mode only)

If on the rising edge of SCL, SDA is sampled low when the module is outputting a high state, the

BCL1IF bit of the PIR2 register is set, and bus goes idle

1= Enable slave bus collision interrupts

0= Slave bus collision interrupts are disabled

bit 1

bit 0

AHEN: Address Hold Enable bit (I²C Slave mode only)

1= Following the 8th falling edge of SCL for a matching received address byte; CKP bit of the SSP-

CON1 register will be cleared and the SCL will be held low.

0= Address holding is disabled

DHEN: Data Hold Enable bit (I²C Slave mode only)

1= Following the 8th falling edge of SCL for a received data byte; slave hardware clears the CKP bit

of the SSPCON1 register and SCL is held low.

0= Data holding is disabled

Note 1: For daisy-chained SPI operation; allows the user to ignore all but the last received byte. SSPOV is still set

when a new byte is received and BF = 1, but hardware continues to write the most recent byte to SSPBUF.

2: This bit has no effect in Slave modes that Start and Stop condition detection is explicitly listed as enabled.

3: The ACKTIM Status bit is only active when the AHEN bit or DHEN bit is set.

DS40001579E-page 308

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 26-5: SSPMSK: SSP MASK REGISTER

R/W-1/1

MSK<7:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7-1

bit 0

MSK<7:1>: Mask bits

1= The received address bit n is compared to SSPADD<n> to detect I²C address match

0= The received address bit n is not used to detect I²C address match

MSK<0>: Mask bit for I²C Slave mode, 10-bit Address

I²C Slave mode, 10-bit address (SSPM<3:0> = 0111or 1111):

1= The received address bit 0 is compared to SSPADD<0> to detect I²C address match

0= The received address bit 0 is not used to detect I²C address match

I²C Slave mode, 7-bit address, the bit is ignored

REGISTER 26-6: SSPADD: MSSP ADDRESS AND BAUD RATE REGISTER (I²C MODE)

R/W-0/0

ADD<7:0>

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

Master mode:

bit 7-0

ADD<7:0>: Baud Rate Clock Divider bits

SCL pin clock period = ((ADD<7:0> + 1) *4)/FOSC

10-Bit Slave mode — Most Significant Address Byte:

bit 7-3

Not used: Unused for Most Significant Address byte. Bit state of this register is a “don’t care”. Bit

pattern sent by master is fixed by I²C specification and must be equal to ‘11110’. However, those bits

are compared by hardware and are not affected by the value in this register.

bit 2-1

bit 0

ADD<2:1>: Two Most Significant bits of 10-bit address

Not used: Unused in this mode. Bit state is a “don’t care”.

10-Bit Slave mode — Least Significant Address Byte:

bit 7-0

ADD<7:0>: Eight Least Significant bits of 10-bit address

7-Bit Slave mode:

bit 7-1

bit 0

ADD<7:1>: 7-bit address

Not used: Unused in this mode. Bit state is a “don’t care”.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 309

PIC16(L)F1782/3

The EUSART module includes the following capabilities:

27.0 ENHANCED UNIVERSAL

SYNCHRONOUS

• Full-duplex asynchronous transmit and receive

• Two-character input buffer

ASYNCHRONOUS RECEIVER

TRANSMITTER (EUSART)

• One-character output buffer

• Programmable 8-bit or 9-bit character length

• Address detection in 9-bit mode

The Enhanced Universal Synchronous Asynchronous

Receiver Transmitter (EUSART) module is a serial I/O

communications peripheral. It contains all the clock

generators, shift registers and data buffers necessary

to perform an input or output serial data transfer

independent of device program execution. The

EUSART, also known as a Serial Communications

Interface (SCI), can be configured as a full-duplex

asynchronous system or half-duplex synchronous

• Input buffer overrun error detection

• Received character framing error detection

• Half-duplex synchronous master

• Half-duplex synchronous slave

• Programmable clock polarity in synchronous

modes

• Sleep operation

system.

Full-Duplex

mode

is

useful

for

The EUSART module implements the following

additional features, making it ideally suited for use in

Local Interconnect Network (LIN) bus systems:

communications with peripheral systems, such as CRT

terminals and personal computers. Half-Duplex

Synchronous mode is intended for communications

with peripheral devices, such as A/D or D/A integrated

circuits, serial EEPROMs or other microcontrollers.

These devices typically do not have internal clocks for

baud rate generation and require the external clock

signal provided by a master synchronous device.

• Automatic detection and calibration of the baud rate

• Wake-up on Break reception

• 13-bit Break character transmit

Block diagrams of the EUSART transmitter and

receiver are shown in Figure 27-1 and Figure 27-2.

FIGURE 27-1:

EUSART TRANSMIT BLOCK DIAGRAM

Data Bus

TXIE

Interrupt

TXIF

TXREG Register

8

TX/CK pin

MSb

(8)

LSb

0

Pin Buffer

and Control

• • •

Transmit Shift Register (TSR)

TXEN

TRMT

SPEN

Baud Rate Generator

BRG16

FOSC

÷ n

TX9

n

+ 1

Multiplier x4

x16 x64

TX9D

SYNC

BRGH

BRG16

1

X

1

0

1

0

1

0

SPBRGH

SPBRGL

DS40001579E-page 310

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 27-2:

EUSART RECEIVE BLOCK DIAGRAM

SPEN

CREN

OERR

RCIDL

RX/DT pin

RSR Register

MSb

Stop (8)

LSb

0

START

Pin Buffer

and Control

Data

Recovery

7

1

• • •

Baud Rate Generator

FOSC

RX9

÷ n

BRG16

n

+ 1

Multiplier x4

x16 x64

SYNC

BRGH

BRG16

1

X

1

0

1

0

1

0

FIFO

SPBRGH

SPBRGL

RX9D

FERR

RCREG Register

8

Data Bus

RCIF

RCIE

Interrupt

The operation of the EUSART module is controlled

through three registers:

• Transmit Status and Control (TXSTA)

• Receive Status and Control (RCSTA)

• Baud Rate Control (BAUDCON)

These registers are detailed in Register 27-1,

Register 27-2 and Register 27-3, respectively.

When the receiver or transmitter section is not enabled

then the corresponding RX or TX pin may be used for

general purpose input and output.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 311

PIC16(L)F1782/3

27.1.1.2

Transmitting Data

27.1 EUSART Asynchronous Mode

A transmission is initiated by writing a character to the

TXREG register. If this is the first character, or the

previous character has been completely flushed from

the TSR, the data in the TXREG is immediately

transferred to the TSR register. If the TSR still contains

all or part of a previous character, the new character

data is held in the TXREG until the Stop bit of the

previous character has been transmitted. The pending

character in the TXREG is then transferred to the TSR

in one TCY immediately following the Stop bit

transmission. The transmission of the Start bit, data bits

and Stop bit sequence commences immediately

following the transfer of the data to the TSR from the

TXREG.

The EUSART transmits and receives data using the

standard non-return-to-zero (NRZ) format. NRZ is

implemented with two levels: a VOH mark state which

represents a ‘1’ data bit, and a VOL space state which

represents a ‘0’ data bit. NRZ refers to the fact that

consecutively transmitted data bits of the same value

stay at the output level of that bit without returning to a

neutral level between each bit transmission. An NRZ

transmission port idles in the Mark state. Each character

transmission consists of one Start bit followed by eight

or nine data bits and is always terminated by one or

more Stop bits. The Start bit is always a space and the

Stop bits are always marks. The most common data

format is 8 bits. Each transmitted bit persists for a period

of 1/(Baud Rate). An on-chip dedicated 8-bit/16-bit Baud

Rate Generator is used to derive standard baud rate

frequencies from the system oscillator. See Table 27-5

for examples of baud rate configurations.

27.1.1.3

Transmit Data Polarity

The polarity of the transmit data can be controlled with

the SCKP bit of the BAUDxCON register. The default

state of this bit is ‘0’ which selects high true transmit idle

and data bits. Setting the SCKP bit to ‘1’ will invert the

transmit data resulting in low true idle and data bits. The

SCKP bit controls transmit data polarity in

Asynchronous mode only. In Synchronous mode, the

SCKP bit has a different function. See Section 27.5.1.2

“Clock Polarity”.

The EUSART transmits and receives the LSb first. The

EUSART’s transmitter and receiver are functionally

independent, but share the same data format and baud

rate. Parity is not supported by the hardware, but can

be implemented in software and stored as the ninth

data bit.

27.1.1

EUSART ASYNCHRONOUS

TRANSMITTER

27.1.1.4

Transmit Interrupt Flag

The TXIF interrupt flag bit of the PIR1 register is set

whenever the EUSART transmitter is enabled and no

character is being held for transmission in the TXREG.

In other words, the TXIF bit is only clear when the TSR

is busy with a character and a new character has been

queued for transmission in the TXREG. The TXIF flag bit

is not cleared immediately upon writing TXREG. TXIF

becomes valid in the second instruction cycle following

the write execution. Polling TXIF immediately following

the TXREG write will return invalid results. The TXIF bit

is read-only, it cannot be set or cleared by software.

The EUSART transmitter block diagram is shown in

Figure 27-1. The heart of the transmitter is the serial

Transmit Shift Register (TSR), which is not directly

accessible by software. The TSR obtains its data from

the transmit buffer, which is the TXREG register.

27.1.1.1

Enabling the Transmitter

The EUSART transmitter is enabled for asynchronous

operations by configuring the following three control

bits:

• TXEN = 1

• SYNC = 0

• SPEN = 1

The TXIF interrupt can be enabled by setting the TXIE

interrupt enable bit of the PIE1 register. However, the

TXIF flag bit will be set whenever the TXREG is empty,

regardless of the state of TXIE enable bit.

All other EUSART control bits are assumed to be in

their default state.

To use interrupts when transmitting data, set the TXIE

bit only when there is more data to send. Clear the

TXIE interrupt enable bit upon writing the last character

of the transmission to the TXREG.

Setting the TXEN bit of the TXSTA register enables the

transmitter circuitry of the EUSART. Clearing the SYNC

bit of the TXSTA register configures the EUSART for

asynchronous operation. Setting the SPEN bit of the

RCSTA register enables the EUSART and automatically

configures the TX/CK I/O pin as an output. If the TX/CK

pin is shared with an analog peripheral, the analog I/O

function must be disabled by clearing the corresponding

ANSEL bit.

Note:

The TXIF Transmitter Interrupt flag is set

when the TXEN enable bit is set.

DS40001579E-page 312

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

27.1.1.5

TSR Status

27.1.1.7

Asynchronous Transmission Set-up:

The TRMT bit of the TXSTA register indicates the

status of the TSR register. This is a read-only bit. The

TRMT bit is set when the TSR register is empty and is

cleared when a character is transferred to the TSR

register from the TXREG. The TRMT bit remains clear

until all bits have been shifted out of the TSR register.

No interrupt logic is tied to this bit, so the user has to

poll this bit to determine the TSR status.

1. Initialize the SPBRGH, SPBRGL register pair and

the BRGH and BRG16 bits to achieve the desired

baud rate (see Section 27.4 “EUSART Baud

Rate Generator (BRG)”).

2. Enable the asynchronous serial port by clearing

the SYNC bit and setting the SPEN bit.

3. If 9-bit transmission is desired, set the TX9

control bit. A set ninth data bit will indicate that

the 8 Least Significant data bits are an address

when the receiver is set for address detection.

Note:

The TSR register is not mapped in data

memory, so it is not available to the user.

4. Set SCKP bit if inverted transmit is desired.

27.1.1.6

Transmitting 9-Bit Characters

5. Enable the transmission by setting the TXEN

control bit. This will cause the TXIF interrupt bit

to be set.

The EUSART supports 9-bit character transmissions.

When the TX9 bit of the TXSTA register is set, the

EUSART will shift 9 bits out for each character transmit-

ted. The TX9D bit of the TXSTA register is the ninth,

and Most Significant, data bit. When transmitting 9-bit

data, the TX9D data bit must be written before writing

the eight Least Significant bits into the TXREG. All 9

bits of data will be transferred to the TSR shift register

immediately after the TXREG is written.

6. If interrupts are desired, set the TXIE interrupt

enable bit of the PIE1 register. An interrupt will

occur immediately provided that the GIE and

PEIE bits of the INTCON register are also set.

7. If 9-bit transmission is selected, the ninth bit

should be loaded into the TX9D data bit.

8. Load 8-bit data into the TXREG register. This

will start the transmission.

A special 9-bit Address mode is available for use with

multiple receivers. See Section 27.1.2.7 “Address

Detection” for more information on the address mode.

FIGURE 27-3:

ASYNCHRONOUS TRANSMISSION

Write to TXREG

Word 1

BRG Output

(Shift Clock)

TX/CK

Start bit

bit 0

bit 1

Word 1

bit 7/8

Stop bit

TXIF bit

(Transmit Buffer

Reg. Empty Flag)

1 TCY

Word 1

Transmit Shift Reg.

TRMT bit

(Transmit Shift

Reg. Empty Flag)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 313

PIC16(L)F1782/3

FIGURE 27-4:

ASYNCHRONOUS TRANSMISSION (BACK-TO-BACK)

Write to TXREG

Word 2

Start bit

Word 1

BRG Output

(Shift Clock)

TX/CK

Start bit

Word 2

bit 0

bit 1

bit 7/8

bit 0

Stop bit

Word 2

1 TCY

Word 1

TXIF bit

(Transmit Buffer

Reg. Empty Flag)

1 TCY

Word 1

Transmit Shift Reg.

TRMT bit

(Transmit Shift

Reg. Empty Flag)

Transmit Shift Reg.

Note:

This timing diagram shows two consecutive transmissions.

TABLE 27-1: SUMMARY OF REGISTERS ASSOCIATED WITH ASYNCHRONOUS TRANSMISSION

Register on

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

Page

111

322

79

APFCON

BAUDCON

INTCON

PIE1

C2OUTSEL CC1PSEL SDOSEL

SCKSEL

SCKP

INTE

SDISEL

BRG16

IOCIE

TXSEL

—

RXSEL

WUE

CCP2SEL

ABDEN

IOCIF

ABDOVF

GIE

RCIDL

PEIE

ADIE

ADIF

RX9

—

TMR0IE

RCIE

TMR0IF

CCP1IE

CCP1IF

FERR

INTF

TMR1GIE

TMR1GIF

SPEN

TXIE

SSP1IE

SSP1IF

ADDEN

TMR2IE

TMR2IF

OERR

TMR1IE

TMR1IF

RX9D

80

PIR1

RCIF

TXIF

83

RCSTA

SPBRGL

SPBRGH

TRISC

SREN

CREN

321

323

125

312*

320

BRG<7:0>

BRG<15:8>

TRISC7

TRISC6

TRISC5

TRISC4

TRISC3

TRISC2

BRGH

TRISC1

TRMT

TRISC0

TX9D

TXREG

TXSTA

EUSART Transmit Data Register

CSRC TX9 TXEN

SYNC

SENDB

Legend:

— = unimplemented location, read as ‘0’. Shaded cells are not used for asynchronous transmission.

*

Page provides register information.

DS40001579E-page 314

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

27.1.2

EUSART ASYNCHRONOUS

RECEIVER

27.1.2.2

Receiving Data

The receiver data recovery circuit initiates character

reception on the falling edge of the first bit. The first bit,

also known as the Start bit, is always a zero. The data

recovery circuit counts one-half bit time to the center of

the Start bit and verifies that the bit is still a zero. If it is

not a zero then the data recovery circuit aborts

character reception, without generating an error, and

resumes looking for the falling edge of the Start bit. If

the Start bit zero verification succeeds then the data

recovery circuit counts a full bit time to the center of the

next bit. The bit is then sampled by a majority detect

circuit and the resulting ‘0’ or ‘1’ is shifted into the RSR.

This repeats until all data bits have been sampled and

shifted into the RSR. One final bit time is measured and

the level sampled. This is the Stop bit, which is always

a ‘1’. If the data recovery circuit samples a ‘0’ in the

Stop bit position then a framing error is set for this

character, otherwise the framing error is cleared for this

character. See Section 27.1.2.4 “Receive Framing

Error” for more information on framing errors.

The Asynchronous mode is typically used in RS-232

systems. The receiver block diagram is shown in

Figure 27-2. The data is received on the RX/DT pin and

drives the data recovery block. The data recovery block

is actually a high-speed shifter operating at 16 times

the baud rate, whereas the serial Receive Shift

Register (RSR) operates at the bit rate. When all 8 or 9

bits of the character have been shifted in, they are

immediately transferred to

a

two character

First-In-First-Out (FIFO) memory. The FIFO buffering

allows reception of two complete characters and the

start of a third character before software must start

servicing the EUSART receiver. The FIFO and RSR

registers are not directly accessible by software.

Access to the received data is via the RCREG register.

27.1.2.1

Enabling the Receiver

The EUSART receiver is enabled for asynchronous

operation by configuring the following three control bits:

Immediately after all data bits and the Stop bit have

been received, the character in the RSR is transferred

to the EUSART receive FIFO and the RCIF interrupt

flag bit of the PIR1 register is set. The top character in

the FIFO is transferred out of the FIFO by reading the

RCREG register.

• CREN = 1

• SYNC = 0

• SPEN = 1

All other EUSART control bits are assumed to be in

their default state.

Setting the CREN bit of the RCSTA register enables the

receiver circuitry of the EUSART. Clearing the SYNC bit

of the TXSTA register configures the EUSART for

asynchronous operation. Setting the SPEN bit of the

RCSTA register enables the EUSART. The programmer

must set the corresponding TRIS bit to configure the

RX/DT I/O pin as an input.

Note:

If the receive FIFO is overrun, no additional

characters will be received until the overrun

condition is cleared. See Section 27.1.2.5

“Receive Overrun Error” for more

information on overrun errors.

27.1.2.3

Receive Interrupts

Note:

If the RX/DT function is on an analog pin,

the corresponding ANSEL bit must be

cleared for the receiver to function.

The RCIF interrupt flag bit of the PIR1 register is set

whenever the EUSART receiver is enabled and there is

an unread character in the receive FIFO. The RCIF

interrupt flag bit is read-only, it cannot be set or cleared

by software.

RCIF interrupts are enabled by setting all of the

following bits:

• RCIE, Interrupt Enable bit of the PIE1 register

• PEIE, Peripheral Interrupt Enable bit of the

INTCON register

• GIE, Global Interrupt Enable bit of the INTCON

register

The RCIF interrupt flag bit will be set when there is an

unread character in the FIFO, regardless of the state of

interrupt enable bits.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 315

PIC16(L)F1782/3

27.1.2.4

Receive Framing Error

27.1.2.7

Address Detection

Each character in the receive FIFO buffer has a

corresponding framing error Status bit. A framing error

indicates that a Stop bit was not seen at the expected

time. The framing error status is accessed via the

FERR bit of the RCSTA register. The FERR bit

represents the status of the top unread character in the

receive FIFO. Therefore, the FERR bit must be read

before reading the RCREG.

A special Address Detection mode is available for use

when multiple receivers share the same transmission

line, such as in RS-485 systems. Address detection is

enabled by setting the ADDEN bit of the RCSTA

register.

Address detection requires 9-bit character reception.

When address detection is enabled, only characters

with the ninth data bit set will be transferred to the

receive FIFO buffer, thereby setting the RCIF interrupt

bit. All other characters will be ignored.

The FERR bit is read-only and only applies to the top

unread character in the receive FIFO. A framing error

(FERR = 1) does not preclude reception of additional

characters. It is not necessary to clear the FERR bit.

Reading the next character from the FIFO buffer will

advance the FIFO to the next character and the next

corresponding framing error.

Upon receiving an address character, user software

determines if the address matches its own. Upon

address match, user software must disable address

detection by clearing the ADDEN bit before the next

Stop bit occurs. When user software detects the end of

the message, determined by the message protocol

used, software places the receiver back into the

Address Detection mode by setting the ADDEN bit.

The FERR bit can be forced clear by clearing the SPEN

bit of the RCSTA register which resets the EUSART.

Clearing the CREN bit of the RCSTA register does not

affect the FERR bit. A framing error by itself does not

generate an interrupt.

Note:

If all receive characters in the receive

FIFO have framing errors, repeated reads

of the RCREG will not clear the FERR bit.

27.1.2.5

Receive Overrun Error

The receive FIFO buffer can hold two characters. An

overrun error will be generated if a third character, in its

entirety, is received before the FIFO is accessed. When

this happens the OERR bit of the RCSTA register is set.

The characters already in the FIFO buffer can be read

but no additional characters will be received until the

error is cleared. The error must be cleared by either

clearing the CREN bit of the RCSTA register or by

resetting the EUSART by clearing the SPEN bit of the

RCSTA register.

27.1.2.6

Receiving 9-bit Characters

The EUSART supports 9-bit character reception. When

the RX9 bit of the RCSTA register is set the EUSART

will shift 9 bits into the RSR for each character

received. The RX9D bit of the RCSTA register is the

ninth and Most Significant data bit of the top unread

character in the receive FIFO. When reading 9-bit data

from the receive FIFO buffer, the RX9D data bit must

be read before reading the 8 Least Significant bits from

the RCREG.

DS40001579E-page 316

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

27.1.2.8

Asynchronous Reception Set-up:

27.1.2.9

9-bit Address Detection Mode Set-up

1. Initialize the SPBRGH, SPBRGL register pair

and the BRGH and BRG16 bits to achieve the

desired baud rate (see Section 27.4 “EUSART

Baud Rate Generator (BRG)”).

This mode would typically be used in RS-485 systems.

To set up an Asynchronous Reception with Address

Detect Enable:

1. Initialize the SPBRGH, SPBRGL register pair

and the BRGH and BRG16 bits to achieve the

desired baud rate (see Section 27.4 “EUSART

Baud Rate Generator (BRG)”).

2. Clear the ANSEL bit for the RX pin (if applicable).

3. Enable the serial port by setting the SPEN bit.

The SYNC bit must be clear for asynchronous

operation.

2. Clear the ANSEL bit for the RX pin (if applicable).

4. If interrupts are desired, set the RCIE bit of the

PIE1 register and the GIE and PEIE bits of the

INTCON register.

3. Enable the serial port by setting the SPEN bit.

The SYNC bit must be clear for asynchronous

operation.

5. If 9-bit reception is desired, set the RX9 bit.

6. Enable reception by setting the CREN bit.

4. If interrupts are desired, set the RCIE bit of the

PIE1 register and the GIE and PEIE bits of the

INTCON register.

7. The RCIF interrupt flag bit will be set when a

character is transferred from the RSR to the

receive buffer. An interrupt will be generated if

the RCIE interrupt enable bit was also set.

5. Enable 9-bit reception by setting the RX9 bit.

6. Enable address detection by setting the ADDEN

bit.

8. Read the RCSTA register to get the error flags

and, if 9-bit data reception is enabled, the ninth

data bit.

7. Enable reception by setting the CREN bit.

8. The RCIF interrupt flag bit will be set when a

character with the ninth bit set is transferred

from the RSR to the receive buffer. An interrupt

will be generated if the RCIE interrupt enable bit

was also set.

9. Get the received eight Least Significant data bits

from the receive buffer by reading the RCREG

register.

10. If an overrun occurred, clear the OERR flag by

clearing the CREN receiver enable bit.

9. Read the RCSTA register to get the error flags.

The ninth data bit will always be set.

10. Get the received eight Least Significant data bits

from the receive buffer by reading the RCREG

register. Software determines if this is the

device’s address.

11. If an overrun occurred, clear the OERR flag by

clearing the CREN receiver enable bit.

12. If the device has been addressed, clear the

ADDEN bit to allow all received data into the

receive buffer and generate interrupts.

FIGURE 27-5:

ASYNCHRONOUS RECEPTION

Start

bit

Start

bit

Start

bit

RX/DT pin

bit 7/8

bit 0 bit 1

Stop

bit

Stop

bit

Stop

bit

bit 0

bit 7/8

Rcv Shift

Reg

Rcv Buffer Reg.

Word 2

RCREG

Word 1

RCREG

RCIDL

Read Rcv

Buffer Reg.

RCREG

RCIF

(Interrupt Flag)

OERR bit

CREN

Note:

This timing diagram shows three words appearing on the RX input. The RCREG (receive buffer) is read after the third word,

causing the OERR (overrun) bit to be set.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 317

PIC16(L)F1782/3

TABLE 27-2: SUMMARY OF REGISTERS ASSOCIATED WITH ASYNCHRONOUS RECEPTION

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

APFCON

BAUDCON

INTCON

PIE1

C2OUTSEL CC1PSEL SDOSEL

SCKSEL

SCKP

INTE

SDISEL

BRG16

IOCIE

TXSEL

—

RXSEL

WUE

CCP2SEL

ABDEN

IOCIF

111

322

79

ABDOVF

GIE

RCIDL

PEIE

ADIE

ADIF

—

TMR0IE

RCIE

TMR0IF

CCP1IE

CCP1IF

INTF

TMR1GIE

TMR1GIF

TXIE

SSP1IE

SSP1IF

TMR2IE

TMR2IF

TMR1IE

TMR1IF

80

PIR1

RCIF

TXIF

83

RCREG

RCSTA

SPBRGL

SPBRGH

TRISC

EUSART Receive Data Register

315*

321

323

125

320

SPEN

RX9

SREN

CREN

BRG<7:0>

BRG<15:8>

ADDEN

FERR

OERR

RX9D

TRISC7

CSRC

TRISC6

TX9

TRISC5

TXEN

TRISC4

SYNC

TRISC3

SENDB

TRISC2

BRGH

TRISC1

TRMT

TRISC0

TX9D

TXSTA

Legend:

— = unimplemented location, read as ‘0’. Shaded cells are not used for asynchronous reception.

*

Page provides register information.

DS40001579E-page 318

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

27.2 Clock Accuracy with

Asynchronous Operation

The factory calibrates the internal oscillator block

output (INTOSC). However, the INTOSC frequency

may drift as VDD or temperature changes, and this

directly affects the asynchronous baud rate. Two

methods may be used to adjust the baud rate clock, but

both require a reference clock source of some kind.

The first (preferred) method uses the OSCTUNE

register to adjust the INTOSC output. Adjusting the

value in the OSCTUNE register allows for fine resolution

changes to the system clock source. See Section 6.2.2

“Internal Clock Sources” for more information.

The other method adjusts the value in the Baud Rate

Generator. This can be done automatically with the

Auto-Baud Detect feature (see Section 27.4.1

“Auto-Baud Detect”). There may not be fine enough

resolution when adjusting the Baud Rate Generator to

compensate for a gradual change in the peripheral

clock frequency.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 319

PIC16(L)F1782/3

27.3 Register Definitions: EUSART Control

REGISTER 27-1: TXSTA: TRANSMIT STATUS AND CONTROL REGISTER

R/W-/0

CSRC

R/W-0/0

TX9

R/W-0/0

TXEN⁽¹⁾

R/W-0/0

SYNC

R/W-0/0

SENDB

R/W-0/0

BRGH

R-1/1

R/W-0/0

TX9D

TRMT

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

CSRC: Clock Source Select bit

Asynchronous mode:

Don’t care

Synchronous mode:

1= Master mode (clock generated internally from BRG)

0= Slave mode (clock from external source)

bit 6

bit 5

bit 4

bit 3

TX9: 9-bit Transmit Enable bit

1= Selects 9-bit transmission

0= Selects 8-bit transmission

TXEN: Transmit Enable bit⁽¹⁾

1= Transmit enabled

0= Transmit disabled

SYNC: EUSART Mode Select bit

1= Synchronous mode

0= Asynchronous mode

SENDB: Send Break Character bit

Asynchronous mode:

1= Send Sync Break on next transmission (cleared by hardware upon completion)

0= Sync Break transmission completed

Synchronous mode:

Don’t care

bit 2

BRGH: High Baud Rate Select bit

Asynchronous mode:

1= High speed

0= Low speed

Synchronous mode:

Unused in this mode

bit 1

bit 0

TRMT: Transmit Shift Register Status bit

1= TSR empty

0= TSR full

TX9D: Ninth bit of Transmit Data

Can be address/data bit or a parity bit.

Note 1: SREN/CREN overrides TXEN in Sync mode.

DS40001579E-page 320

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

REGISTER 27-2: RCSTA: RECEIVE STATUS AND CONTROL REGISTER

R/W-0/0

SPEN

R/W-0/0

RX9

R/W-0/0

SREN

R/W-0/0

CREN

R/W-0/0

ADDEN

R-0/0

RX9D

FERR

OERR

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

bit 6

bit 5

SPEN: Serial Port Enable bit

1= Serial port enabled (configures RX/DT and TX/CK pins as serial port pins)

0= Serial port disabled (held in Reset)

RX9: 9-bit Receive Enable bit

1= Selects 9-bit reception

0= Selects 8-bit reception

SREN: Single Receive Enable bit

Asynchronous mode:

Don’t care

Synchronous mode – Master:

1= Enables single receive

0= Disables single receive

This bit is cleared after reception is complete.

Synchronous mode – Slave

Don’t care

bit 4

CREN: Continuous Receive Enable bit

Asynchronous mode:

1= Enables receiver

0= Disables receiver

Synchronous mode:

1= Enables continuous receive until enable bit CREN is cleared (CREN overrides SREN)

0= Disables continuous receive

bit 3

ADDEN: Address Detect Enable bit

Asynchronous mode 9-bit (RX9 = 1):

1= Enables address detection, enable interrupt and load the receive buffer when RSR<8> is set

0= Disables address detection, all bytes are received and ninth bit can be used as parity bit

Asynchronous mode 8-bit (RX9 = 0):

Don’t care

bit 2

bit 1

bit 0

FERR: Framing Error bit

1= Framing error (can be updated by reading RCREG register and receive next valid byte)

0= No framing error

OERR: Overrun Error bit

1= Overrun error (can be cleared by clearing bit CREN)

0= No overrun error

RX9D: Ninth bit of Received Data

This can be address/data bit or a parity bit and must be calculated by user firmware.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 321

PIC16(L)F1782/3

REGISTER 27-3: BAUDCON: BAUD RATE CONTROL REGISTER

R-0/0

R-1/1

U-0

—

R/W-0/0

SCKP

R/W-0/0

BRG16

U-0

—

R/W-0/0

WUE

R/W-0/0

ABDEN

ABDOVF

RCIDL

bit 7

bit 0

Legend:

R = Readable bit

W = Writable bit

U = Unimplemented bit, read as ‘0’

-n/n = Value at POR and BOR/Value at all other Resets

u = Bit is unchanged

‘1’ = Bit is set

x = Bit is unknown

‘0’ = Bit is cleared

bit 7

bit 6

ABDOVF: Auto-Baud Detect Overflow bit

Asynchronous mode:

1= Auto-baud timer overflowed

0= Auto-baud timer did not overflow

Synchronous mode:

Don’t care

RCIDL: Receive Idle Flag bit

Asynchronous mode:

1= Receiver is idle

0= Start bit has been received and the receiver is receiving

Synchronous mode:

Don’t care

bit 5

bit 4

Unimplemented: Read as ‘0’

SCKP: Synchronous Clock Polarity Select bit

Asynchronous mode:

1= Transmit inverted data to the TX/CK pin

0= Transmit non-inverted data to the TX/CK pin

Synchronous mode:

1= Data is clocked on rising edge of the clock

0= Data is clocked on falling edge of the clock

bit 3

BRG16: 16-bit Baud Rate Generator bit

1= 16-bit Baud Rate Generator is used

0= 8-bit Baud Rate Generator is used

bit 2

bit 1

Unimplemented: Read as ‘0’

WUE: Wake-up Enable bit

Asynchronous mode:

1= Receiver is waiting for a falling edge. No character will be received, byte RCIF will be set. WUE

will automatically clear after RCIF is set.

0= Receiver is operating normally

Synchronous mode:

Don’t care

bit 0

ABDEN: Auto-Baud Detect Enable bit

Asynchronous mode:

1= Auto-Baud Detect mode is enabled (clears when auto-baud is complete)

0= Auto-Baud Detect mode is disabled

Synchronous mode:

Don’t care

DS40001579E-page 322

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

EXAMPLE 27-1:

CALCULATING BAUD

RATE ERROR

27.4 EUSART Baud Rate Generator

(BRG)

For a device with FOSC of 16 MHz, desired baud rate

of 9600, Asynchronous mode, 8-bit BRG:

The Baud Rate Generator (BRG) is an 8-bit or 16-bit

timer that is dedicated to the support of both the

asynchronous and synchronous EUSART operation.

By default, the BRG operates in 8-bit mode. Setting the

BRG16 bit of the BAUDCON register selects 16-bit

mode.

FOSC

Desired Baud Rate = -----------------------------------------------------------------------

64[SPBRGH:SPBRGL] + 1

Solving for SPBRGH:SPBRGL:

FOSC

---------------------------------------------

Desired Baud Rate

X = --------------------------------------------- – 1

64

The SPBRGH, SPBRGL register pair determines the

period of the free running baud rate timer. In

Asynchronous mode the multiplier of the baud rate

period is determined by both the BRGH bit of the TXSTA

register and the BRG16 bit of the BAUDCON register. In

Synchronous mode, the BRGH bit is ignored.

16000000

-----------------------

9600

= ----------------------- – 1

64

= 25.042 = 25

Table 27-3 contains the formulas for determining the

baud rate. Example 27-1 provides a sample calculation

for determining the baud rate and baud rate error.

16000000

Calculated Baud Rate = --------------------------

6425 + 1

Typical baud rates and error values for various

asynchronous modes have been computed for your

convenience and are shown in Table 27-3. It may be

advantageous to use the high baud rate (BRGH = 1),

or the 16-bit BRG (BRG16 = 1) to reduce the baud rate

error. The 16-bit BRG mode is used to achieve slow

baud rates for fast oscillator frequencies.

= 9615

Calc. Baud Rate – Desired Baud Rate

Error = --------------------------------------------------------------------------------------------

Desired Baud Rate

9615 – 9600

= ---------------------------------- = 0 . 1 6 %

9600

Writing a new value to the SPBRGH, SPBRGL register

pair causes the BRG timer to be reset (or cleared). This

ensures that the BRG does not wait for a timer overflow

before outputting the new baud rate.

If the system clock is changed during an active receive

operation, a receive error or data loss may result. To

avoid this problem, check the status of the RCIDL bit to

make sure that the receive operation is idle before

changing the system clock.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 323

PIC16(L)F1782/3

TABLE 27-3: BAUD RATE FORMULAS

Configuration Bits

Baud Rate Formula

BRG/EUSART Mode

SYNC

BRG16

BRGH

0

1

0

1

0

1

0

1

0

1

x

8-bit/Asynchronous

16-bit/Asynchronous

8-bit/Synchronous

16-bit/Synchronous

FOSC/[64 (n+1)]

FOSC/[16 (n+1)]

FOSC/[4 (n+1)]

Legend:

x= Don’t care, n = value of SPBRGH, SPBRGL register pair

TABLE 27-4: SUMMARY OF REGISTERS ASSOCIATED WITH THE BAUD RATE GENERATOR

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

BAUDCON

RCSTA

ABDOVF RCIDL

—

SCKP

CREN

BRG16

ADDEN

—

WUE

ABDEN

RX9D

322

321

323

320

SPEN

CSRC

RX9

SREN

FERR

OERR

SPBRGL

SPBRGH

TXSTA

BRG<7:0>

BRG<15:8>

SYNC SENDB

TX9

TXEN

BRGH

TRMT

TX9D

Legend: — = unimplemented location, read as ‘0’. Shaded cells are not used for the Baud Rate Generator.

Page provides register information.

*

DS40001579E-page 324

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 27-5: BAUD RATES FOR ASYNCHRONOUS MODES

SYNC = 0, BRGH = 0, BRG16 = 0

FOSC = 20.000 MHz FOSC = 18.432 MHz

FOSC = 32.000 MHz

FOSC = 11.0592 MHz

BAUD

RATE

SPBRG

value

SPBRG

value

SPBRG

Actual

Rate

%

Actual

Rate

%

Error

Actual

Rate

%

Error

Actual

Rate

%

value

(decimal)

value

(decimal)

Error

(decimal)

300

1200

—

255

129

32

—

239

119

29

—

143

71

17

16

8

—

1221

2404

9470

10417

19.53k

1.73

0.16

-1.36

0.00

1.73

1200

2400

9600

10286

19.20k

0.00

-1.26

0.00

—

1200

2400

9600

10165

19.20k

0.00

-2.42

0.00

—

2400

2404

9615

10417

19.23k

0.16

0.00

0.16

207

51

47

25

9600

10417

19.2k

57.6k

115.2k

29

27

15

14

2

55.55k

—

-3.55

—

3

—

57.60k

—

7

57.60k

—

SYNC = 0, BRGH = 0, BRG16 = 0

FOSC = 4.000 MHz FOSC = 3.6864 MHz

FOSC = 8.000 MHz

FOSC = 1.000 MHz

BAUD

RATE

SPBRG

value

SPBRG

value

SPBRG

Actual

Rate

%

Actual

Rate

%

Error

Actual

Rate

%

Error

Actual

Rate

%

value

(decimal)

value

(decimal)

Error

(decimal)

0.00

—

300

1200

—

1202

2404

9615

10417

—

0.16

0.00

—

103

51

12

11

300

1202

2404

—

0.16

—

207

51

25

—

5

300

1200

2400

9600

—

191

47

23

5

300

1202

—

0.16

—

51

12

—

2400

9600

—

10417

19.2k

57.6k

115.2k

10417

—

0.00

—

2

—

19.20k

0.00

—

0

—

57.60k

—

SYNC = 0, BRGH = 1, BRG16 = 0

FOSC = 20.000 MHz FOSC = 18.432 MHz

FOSC = 32.000 MHz

FOSC = 11.0592 MHz

BAUD

RATE

SPBRG

value

SPBRG

value

SPBRG

Actual

Rate

%

Actual

Rate

%

Error

Actual

Rate

%

Error

Actual

Rate

%

value

(decimal)

value

(decimal)

Error

(decimal)

—

300

1200

2400

9600

10417

19.2k

57.6k

—

71

65

35

11

5

9615

10417

19.23k

57.14k

0.16

0.00

0.16

-0.79

2.12

207

191

103

34

9615

10417

19.23k

56.82k

0.16

0.00

0.16

-1.36

129

119

64

9600

10378

19.20k

57.60k

115.2k

0.00

-0.37

0.00

119

110

59

19

9

9600

0.00

0.53

0.00

10473

19.20k

57.60k

115.2k

21

115.2k 117.64k

16

113.64k -1.36

10

 2011-2014 Microchip Technology Inc.

DS40001579E-page 325

PIC16(L)F1782/3

TABLE 27-5: BAUD RATES FOR ASYNCHRONOUS MODES (CONTINUED)

SYNC = 0, BRGH = 1, BRG16 = 0

FOSC = 8.000 MHz

FOSC = 4.000 MHz

FOSC = 3.6864 MHz

FOSC = 1.000 MHz

BAUD

RATE

SPBRG

Actual

Rate

%

Actual

Rate

%

Actual

Rate

%

Actual

Rate

%

value

(decimal)

value

(decimal)

value

(decimal)

value

(decimal)

Error

—

300

1200

—

1202

2404

9615

10417

19.23k

—

207

103

25

—

191

95

23

21

11

3

300

1202

2404

—

0.16

—

207

51

25

—

5

0.16

0.00

0.16

—

1200

0.00

0.53

0.00

2400

2404

9615

10417

19231

55556

—

0.16

0.00

0.16

-3.55

—

207

51

47

25

8

2400

9600

10417

19.2k

57.6k

115.2k

23

10473

19.2k

57.60k

115.2k

10417

—

0.00

—

12

—

1

—

SYNC = 0, BRGH = 0, BRG16 = 1

FOSC = 20.000 MHz FOSC = 18.432 MHz

FOSC = 32.000 MHz

FOSC = 11.0592 MHz

BAUD

RATE

SPBRG

value

SPBRG

value

SPBRG

Actual

Rate

%

Actual

Rate

%

Error

Actual

Rate

%

Error

Actual

Rate

%

value

(decimal)

value

(decimal)

Error

(decimal)

300

1200

300.0

1200

0.00

-0.02

-0.04

0.16

0.00

0.16

-0.79

2.12

6666

3332

832

207

191

103

34

300.0

1200

-0.01

-0.03

0.16

0.00

0.16

-1.36

4166

1041

520

129

119

64

300.0

1200

0.00

-0.37

0.00

3839

959

479

119

110

59

300.0

1200

0.00

0.53

0.00

2303

575

287

71

2400

2401

2399

2400

9600

9615

9600

10417

19.2k

57.6k

115.2k

10417

19.23k

57.14k

117.6k

10417

19.23k

56.818

10378

19.20k

57.60k

115.2k

10473

19.20k

57.60k

115.2k

65

35

21

19

11

16

113.636 -1.36

10

9

5

SYNC = 0, BRGH = 0, BRG16 = 1

FOSC = 4.000 MHz FOSC = 3.6864 MHz

FOSC = 8.000 MHz

FOSC = 1.000 MHz

BAUD

RATE

SPBRG

value

SPBRG

value

SPBRG

Actual

Rate

%

Actual

Rate

%

Error

Actual

Rate

%

Error

Actual

Rate

%

value

(decimal)

value

(decimal)

Error

(decimal)

300

1200

299.9

1199

-0.02

-0.08

0.16

0.00

0.16

-3.55

—

1666

416

207

51

300.1

1202

2404

9615

10417

19.23k

—

0.04

0.16

0.00

0.16

—

832

207

103

25

300.0

1200

0.00

0.53

0.00

767

191

95

23

21

11

3

300.5

1202

2404

—

0.16

—

207

51

25

—

5

2400

2404

9615

10417

19.23k

55556

—

2400

9600

10417

19.2k

57.6k

115.2k

47

23

10473

19.20k

57.60k

115.2k

10417

—

0.00

—

25

12

—

8

—

1

—

DS40001579E-page 326

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 27-5: BAUD RATES FOR ASYNCHRONOUS MODES (CONTINUED)

SYNC = 0, BRGH = 1, BRG16 = 1or SYNC = 1, BRG16 = 1

FOSC = 20.000 MHz FOSC = 18.432 MHz

FOSC = 32.000 MHz

FOSC = 11.0592 MHz

BAUD

RATE

SPBRG

Actual

Rate

%

Actual

Rate

%

Actual

Rate

%

Actual

Rate

%

value

(decimal)

value

(decimal)

value

(decimal)

value

(decimal)

Error

300

1200

300.0

1200

0.00

0.01

0.04

0.00

-0.08

0.64

26666

6666

3332

832

300.0

1200

0.00

-0.01

0.02

-0.03

0.00

0.16

-0.22

0.94

16665

4166

2082

520

479

259

86

300.0

1200

0.00

0.08

0.00

15359

3839

1919

479

441

239

79

300.0

1200

0.00

0.16

0.00

9215

2303

1151

287

264

143

47

2400

9600

9604

9597

9600

10417

19.2k

57.6k

115.2k

10417

19.18k

57.55k

115.9k

767

10417

19.23k

57.47k

116.3k

10425

19.20k

57.60k

115.2k

10433

19.20k

57.60k

115.2k

416

138

68

42

39

23

SYNC = 0, BRGH = 1, BRG16 = 1or SYNC = 1, BRG16 = 1

FOSC = 4.000 MHz FOSC = 3.6864 MHz

FOSC = 8.000 MHz

FOSC = 1.000 MHz

BAUD

RATE

SPBRG

Actual

Rate

%

Actual

Rate

%

Actual

Rate

%

Actual

Rate

%

value

(decimal)

value

(decimal)

value

(decimal)

value

(decimal)

Error

300

1200

300.0

1200

0.00

-0.02

0.04

0.16

0

6666

1666

832

207

191

103

34

300.0

1200

0.01

0.04

0.08

0.16

0.00

0.16

2.12

-3.55

3332

832

416

103

95

300.0

1200

0.00

0.53

0.00

3071

767

383

95

300.1

1202

2404

9615

10417

19.23k

—

0.04

0.16

0.00

0.16

—

832

207

103

25

2400

2401

2398

2400

9600

9615

9600

10417

19.2k

57.6k

115.2k

10417

19.23k

57.14k

117.6k

10417

19.23k

58.82k

111.1k

10473

19.20k

57.60k

115.2k

87

23

0.16

-0.79

2.12

51

47

12

16

15

—

16

8

7

—

 2011-2014 Microchip Technology Inc.

DS40001579E-page 327

PIC16(L)F1782/3

and SPBRGL registers are clocked at 1/8th the BRG

base clock rate. The resulting byte measurement is the

average bit time when clocked at full speed.

27.4.1

AUTO-BAUD DETECT

The EUSART module supports automatic detection

and calibration of the baud rate.

Note 1: If the WUE bit is set with the ABDEN bit,

auto-baud detection will occur on the byte

following the Break character (see

In the Auto-Baud Detect (ABD) mode, the clock to the

BRG is reversed. Rather than the BRG clocking the

incoming RX signal, the RX signal is timing the BRG.

The Baud Rate Generator is used to time the period of

a received 55h (ASCII “U”) which is the Sync character

for the LIN bus. The unique feature of this character is

that it has five rising edges including the Stop bit edge.

Section 27.4.3

“Auto-Wake-up

on

Break”).

2: It is up to the user to determine that the

incoming character baud rate is within the

range of the selected BRG clock source.

Some combinations of oscillator frequency

and EUSART baud rates are not possible.

Setting the ABDEN bit of the BAUDCON register starts

the auto-baud calibration sequence (Figure 27-6).

While the ABD sequence takes place, the EUSART

state machine is held in idle. On the first rising edge of

the receive line, after the Start bit, the SPBRG begins

counting up using the BRG counter clock as shown in

Table 27-6. The fifth rising edge will occur on the RX pin

at the end of the eighth bit period. At that time, an

accumulated value totaling the proper BRG period is

left in the SPBRGH, SPBRGL register pair, the ABDEN

bit is automatically cleared and the RCIF interrupt flag

is set. The value in the RCREG needs to be read to

clear the RCIF interrupt. RCREG content should be

discarded. When calibrating for modes that do not use

the SPBRGH register the user can verify that the

SPBRGL register did not overflow by checking for 00h

in the SPBRGH register.

3: During the auto-baud process, the

auto-baud counter starts counting at 1.

Upon completion of the auto-baud

sequence, to achieve maximum accuracy,

subtract 1 from the SPBRGH:SPBRGL

register pair.

TABLE 27-6:

BRG16 BRGH

BRG COUNTER CLOCK RATES

BRG Base

Clock

BRG ABD

Clock

0

1

FOSC/64

FOSC/16

FOSC/512

FOSC/128

1

0

1

FOSC/16

FOSC/4

FOSC/128

FOSC/32

The BRG auto-baud clock is determined by the BRG16

and BRGH bits as shown in Table 27-6. During ABD,

both the SPBRGH and SPBRGL registers are used as

a 16-bit counter, independent of the BRG16 bit setting.

While calibrating the baud rate period, the SPBRGH

Note:

During the ABD sequence, SPBRGL and

SPBRGH registers are both used as a 16-bit

counter, independent of BRG16 setting.

FIGURE 27-6:

AUTOMATIC BAUD RATE CALIBRATION

XXXXh

0000h

001Ch

BRG Value

Edge #5

Stop bit

Edge #1

bit 1

Edge #2

bit 3

Edge #3

bit 5

Edge #4

bit 7

bit 6

RX pin

Start

bit 0

bit 2

bit 4

BRG Clock

Auto Cleared

Set by User

ABDEN bit

RCIDL

RCIF bit

(Interrupt)

Read

RCREG

XXh

1Ch

00h

SPBRGL

SPBRGH

Note 1: The ABD sequence requires the EUSART module to be configured in Asynchronous mode.

DS40001579E-page 328

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

27.4.2

AUTO-BAUD OVERFLOW

27.4.3.1

Special Considerations

During the course of automatic baud detection, the

ABDOVF bit of the BAUDCON register will be set if the

baud rate counter overflows before the fifth rising edge

is detected on the RX pin. The ABDOVF bit indicates

that the counter has exceeded the maximum count that

can fit in the 16 bits of the SPBRGH:SPBRGL register

pair. After the ABDOVF bit has been set, the counter

continues to count until the fifth rising edge is detected

on the RX pin. Upon detecting the fifth RX edge, the

hardware will set the RCIF interrupt flag and clear the

ABDEN bit of the BAUDCON register. The RCIF flag

can be subsequently cleared by reading the RCREG

register. The ABDOVF flag of the BAUDCON register

can be cleared by software directly.

Break Character

To avoid character errors or character fragments during

a wake-up event, the wake-up character must be all

zeros.

When the wake-up is enabled the function works

independent of the low time on the data stream. If the

WUE bit is set and a valid non-zero character is

received, the low time from the Start bit to the first rising

edge will be interpreted as the wake-up event. The

remaining bits in the character will be received as a

fragmented character and subsequent characters can

result in framing or overrun errors.

Therefore, the initial character in the transmission must

be all ‘0’s. This must be ten or more bit times, 13-bit

times recommended for LIN bus, or any number of bit

times for standard RS-232 devices.

To terminate the auto-baud process before the RCIF

flag is set, clear the ABDEN bit then clear the ABDOVF

bit of the BAUDCON register. The ABDOVF bit will

remain set if the ABDEN bit is not cleared first.

Oscillator Start-up Time

Oscillator start-up time must be considered, especially

in applications using oscillators with longer start-up

intervals (i.e., LP, XT or HS/PLL mode). The Sync

Break (or wake-up signal) character must be of

sufficient length, and be followed by a sufficient

interval, to allow enough time for the selected oscillator

to start and provide proper initialization of the EUSART.

27.4.3

AUTO-WAKE-UP ON BREAK

During Sleep mode, all clocks to the EUSART are

suspended. Because of this, the Baud Rate Generator

is inactive and a proper character reception cannot be

performed. The Auto-Wake-up feature allows the

controller to wake-up due to activity on the RX/DT line.

This feature is available only in Asynchronous mode.

WUE Bit

The Auto-Wake-up feature is enabled by setting the

WUE bit of the BAUDCON register. Once set, the normal

receive sequence on RX/DT is disabled, and the

EUSART remains in an Idle state, monitoring for a

wake-up event independent of the CPU mode. A

wake-up event consists of a high-to-low transition on the

RX/DT line. (This coincides with the start of a Sync Break

or a wake-up signal character for the LIN protocol.)

The wake-up event causes a receive interrupt by

setting the RCIF bit. The WUE bit is cleared in

hardware by a rising edge on RX/DT. The interrupt

condition is then cleared in software by reading the

RCREG register and discarding its contents.

To ensure that no actual data is lost, check the RCIDL

bit to verify that a receive operation is not in process

before setting the WUE bit. If a receive operation is not

occurring, the WUE bit may then be set just prior to

entering the Sleep mode.

The EUSART module generates an RCIF interrupt

coincident with the wake-up event. The interrupt is

generated synchronously to the Q clocks in normal CPU

operating modes (Figure 27-7), and asynchronously if

the device is in Sleep mode (Figure 27-8). The interrupt

condition is cleared by reading the RCREG register.

The WUE bit is automatically cleared by the low-to-high

transition on the RX line at the end of the Break. This

signals to the user that the Break event is over. At this

point, the EUSART module is in Idle mode waiting to

receive the next character.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 329

PIC16(L)F1782/3

FIGURE 27-7:

AUTO-WAKE-UP BIT (WUE) TIMING DURING NORMAL OPERATION

Q1 Q2 Q3 Q4 Q1 Q2 Q3Q4 Q1Q2 Q3 Q4 Q1Q2 Q3 Q4 Q1Q2 Q3 Q4 Q1Q2 Q3 Q4 Q1Q2 Q3 Q4 Q1Q2 Q3Q4 Q1 Q2 Q3 Q4 Q1Q2 Q3Q4

OSC1

Auto Cleared

Bit set by user

WUE bit

RX/DT Line

RCIF

Cleared due to User Read of RCREG

Note 1: The EUSART remains in idle while the WUE bit is set.

FIGURE 27-8:

AUTO-WAKE-UP BIT (WUE) TIMINGS DURING SLEEP

Q4

Q1Q2Q3 Q4 Q1Q2 Q3Q4 Q1Q2Q3

Q1

Q2 Q3Q4 Q1Q2Q3 Q4 Q1Q2Q3Q4 Q1Q2Q3 Q4 Q1Q2 Q3Q4

Auto Cleared

OSC1

Bit Set by User

WUE bit

RX/DT Line

Note 1

RCIF

Cleared due to User Read of RCREG

Sleep Command Executed

Sleep Ends

Note 1: If the wake-up event requires long oscillator warm-up time, the automatic clearing of the WUE bit can occur while the stposcsignal is

still active. This sequence should not depend on the presence of Q clocks.

2: The EUSART remains in idle while the WUE bit is set.

DS40001579E-page 330

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

27.4.4

BREAK CHARACTER SEQUENCE

27.4.5

RECEIVING A BREAK CHARACTER

The EUSART module has the capability of sending the

special Break character sequences that are required by

the LIN bus standard. A Break character consists of a

Start bit, followed by 12 ‘0’ bits and a Stop bit.

The Enhanced EUSART module can receive a Break

character in two ways.

The first method to detect a Break character uses the

FERR bit of the RCSTA register and the received data

as indicated by RCREG. The Baud Rate Generator is

assumed to have been initialized to the expected baud

rate.

To send a Break character, set the SENDB and TXEN

bits of the TXSTA register. The Break character

transmission is then initiated by a write to the TXREG.

The value of data written to TXREG will be ignored and

all ‘0’s will be transmitted.

A Break character has been received when;

• RCIF bit is set

• FERR bit is set

• RCREG = 00h

The SENDB bit is automatically reset by hardware after

the corresponding Stop bit is sent. This allows the user

to preload the transmit FIFO with the next transmit byte

following the Break character (typically, the Sync

character in the LIN specification).

The second method uses the Auto-Wake-up feature

described in Section 27.4.3 “Auto-Wake-up on

Break”. By enabling this feature, the EUSART will

sample the next two transitions on RX/DT, cause an

RCIF interrupt, and receive the next data byte followed

by another interrupt.

The TRMT bit of the TXSTA register indicates when the

transmit operation is active or idle, just as it does during

normal transmission. See Figure 27-9 for the timing of

the Break character sequence.

Note that following a Break character, the user will

typically want to enable the Auto-Baud Detect feature.

For both methods, the user can set the ABDEN bit of

the BAUDCON register before placing the EUSART in

Sleep mode.

27.4.4.1

Break and Sync Transmit Sequence

The following sequence will start a message frame

header made up of a Break, followed by an auto-baud

Sync byte. This sequence is typical of a LIN bus

master.

1. Configure the EUSART for the desired mode.

2. Set the TXEN and SENDB bits to enable the

Break sequence.

3. Load the TXREG with a dummy character to

initiate transmission (the value is ignored).

4. Write ‘55h’ to TXREG to load the Sync character

into the transmit FIFO buffer.

5. After the Break has been sent, the SENDB bit is

reset by hardware and the Sync character is

then transmitted.

When the TXREG becomes empty, as indicated by the

TXIF, the next data byte can be written to TXREG.

FIGURE 27-9:

SEND BREAK CHARACTER SEQUENCE

Write to TXREG

Dummy Write

BRG Output

(Shift Clock)

TX (pin)

Start bit

bit 0

bit 1

Break

bit 11

Stop bit

TXIF bit

(Transmit

Interrupt Flag)

TRMT bit

(Transmit Shift

Empty Flag)

SENDB Sampled Here

Auto Cleared

SENDB

(send Break

control bit)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 331

PIC16(L)F1782/3

Clearing the SCKP bit sets the Idle state as low. When

the SCKP bit is cleared, the data changes on the rising

edge of each clock.

27.5 EUSART Synchronous Mode

Synchronous serial communications are typically used

in systems with a single master and one or more

slaves. The master device contains the necessary

circuitry for baud rate generation and supplies the clock

for all devices in the system. Slave devices can take

advantage of the master clock by eliminating the

internal clock generation circuitry.

27.5.1.3

Synchronous Master Transmission

Data is transferred out of the device on the RX/DT pin.

The RX/DT and TX/CK pin output drivers are automat-

ically enabled when the EUSART is configured for

synchronous master transmit operation.

There are two signal lines in Synchronous mode: a

bidirectional data line and a clock line. Slaves use the

external clock supplied by the master to shift the serial

data into and out of their respective receive and trans-

mit shift registers. Since the data line is bidirectional,

synchronous operation is half-duplex only. Half-duplex

refers to the fact that master and slave devices can

receive and transmit data but not both simultaneously.

The EUSART can operate as either a master or slave

device.

A transmission is initiated by writing a character to the

TXREG register. If the TSR still contains all or part of a

previous character the new character data is held in the

TXREG until the last bit of the previous character has

been transmitted. If this is the first character, or the

previous character has been completely flushed from

the TSR, the data in the TXREG is immediately trans-

ferred to the TSR. The transmission of the character

commences immediately following the transfer of the

data to the TSR from the TXREG.

Start and Stop bits are not used in synchronous

transmissions.

Each data bit changes on the leading edge of the

master clock and remains valid until the subsequent

leading clock edge.

27.5.1

SYNCHRONOUS MASTER MODE

Note:

The TSR register is not mapped in data

memory, so it is not available to the user.

The following bits are used to configure the EUSART

for synchronous master operation:

• SYNC = 1

27.5.1.4

Synchronous Master Transmission

Set-up:

• CSRC = 1

• SREN = 0(for transmit); SREN = 1(for receive)

• CREN = 0(for transmit); CREN = 1(for receive)

• SPEN = 1

1. Initialize the SPBRGH, SPBRGL register pair

and the BRGH and BRG16 bits to achieve the

desired baud rate (see Section 27.4 “EUSART

Baud Rate Generator (BRG)”).

Setting the SYNC bit of the TXSTA register configures

the device for synchronous operation. Setting the CSRC

bit of the TXSTA register configures the device as a

master. Clearing the SREN and CREN bits of the RCSTA

register ensures that the device is in the Transmit mode,

otherwise the device will be configured to receive. Setting

the SPEN bit of the RCSTA register enables the

EUSART.

2. Enable the synchronous master serial port by

setting bits SYNC, SPEN and CSRC.

3. Disable Receive mode by clearing bits SREN

and CREN.

4. Enable Transmit mode by setting the TXEN bit.

5. If 9-bit transmission is desired, set the TX9 bit.

6. If interrupts are desired, set the TXIE bit of the

PIE1 register and the GIE and PEIE bits of the

INTCON register.

27.5.1.1

Master Clock

Synchronous data transfers use a separate clock line,

which is synchronous with the data. A device config-

ured as a master transmits the clock on the TX/CK line.

The TX/CK pin output driver is automatically enabled

when the EUSART is configured for synchronous

transmit or receive operation. Serial data bits change

on the leading edge to ensure they are valid at the

trailing edge of each clock. One clock cycle is

generated for each data bit. Only as many clock cycles

are generated as there are data bits.

7. If 9-bit transmission is selected, the ninth bit

should be loaded in the TX9D bit.

8. Start transmission by loading data to the TXREG

register.

27.5.1.2

Clock Polarity

A clock polarity option is provided for Microwire

compatibility. Clock polarity is selected with the SCKP

bit of the BAUDCON register. Setting the SCKP bit sets

the clock Idle state as high. When the SCKP bit is set,

the data changes on the falling edge of each clock.

DS40001579E-page 332

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 27-10:

SYNCHRONOUS TRANSMISSION

RX/DT

bit 0

bit 1

bit 2

bit 7

bit 0

bit 1

Word 2

bit 7

Word 1

TX/CK pin

(SCKP = 0)

TX/CK pin

(SCKP = 1)

Write to

TXREG Reg

Write Word 1

Write Word 2

TXIF bit

(Interrupt Flag)

TRMT bit

‘1’

TXEN bit

Note:

Sync Master mode, SPBRGL = 0, continuous transmission of two 8-bit words.

FIGURE 27-11:

SYNCHRONOUS TRANSMISSION (THROUGH TXEN)

RX/DT pin

bit 0

bit 2

bit 1

bit 6

bit 7

TX/CK pin

Write to

TXREG reg

TXIF bit

TRMT bit

TXEN bit

TABLE 27-7: SUMMARY OF REGISTERS ASSOCIATED WITH SYNCHRONOUS MASTER

TRANSMISSION

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

APFCON

BAUDCON

INTCON

PIE1

C2OUTSEL CC1PSEL SDOSEL

SCKSEL

SCKP

INTE

SDISEL

BRG16

IOCIE

TXSEL

—

RXSEL

WUE

CCP2SEL

ABDEN

IOCIF

111

322

79

ABDOVF

GIE

RCIDL

PEIE

ADIE

ADIF

RX9

—

TMR0IE

RCIE

TMR0IF

CCP1IE

CCP1IF

FERR

INTF

TMR1GIE

TMR1GIF

SPEN

TXIE

SSP1IE

SSP1IF

ADDEN

TMR2IE

TMR2IF

OERR

TMR1IE

TMR1IF

RX9D

80

PIR1

RCIF

TXIF

83

RCSTA

SPBRGL

SPBRGH

TRISC

SREN

CREN

321

323

125

312*

320

BRG<7:0>

BRG<15:8>

TRISC4 TRISC3

TRISC7

CSRC

TRISC6

TX9

TRISC5

TRISC2

TRISC1

TRMT

TRISC0

TX9D

TXREG

EUSART Transmit Data Register

TXEN SYNC SENDB

TXSTA

BRGH

Legend:

— = unimplemented location, read as ‘0’. Shaded cells are not used for synchronous master transmission.

*

Page provides register information.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 333

PIC16(L)F1782/3

will be received until the error is cleared. The OERR bit

can only be cleared by clearing the overrun condition.

If the overrun error occurred when the SREN bit is set

and CREN is clear then the error is cleared by reading

RCREG. If the overrun occurred when the CREN bit is

set then the error condition is cleared by either clearing

the CREN bit of the RCSTA register or by clearing the

SPEN bit which resets the EUSART.

27.5.1.5

Synchronous Master Reception

Data is received at the RX/DT pin. The RX/DT pin

output driver is automatically disabled when the

EUSART is configured for synchronous master receive

operation.

In Synchronous mode, reception is enabled by setting

either the Single Receive Enable bit (SREN of the

RCSTA register) or the Continuous Receive Enable bit

(CREN of the RCSTA register).

27.5.1.8

Receiving 9-bit Characters

When SREN is set and CREN is clear, only as many

clock cycles are generated as there are data bits in a

single character. The SREN bit is automatically cleared

at the completion of one character. When CREN is set,

clocks are continuously generated until CREN is

cleared. If CREN is cleared in the middle of a character

the CK clock stops immediately and the partial charac-

ter is discarded. If SREN and CREN are both set, then

SREN is cleared at the completion of the first character

and CREN takes precedence.

The EUSART supports 9-bit character reception. When

the RX9 bit of the RCSTA register is set the EUSART

will shift 9-bits into the RSR for each character

received. The RX9D bit of the RCSTA register is the

ninth, and Most Significant, data bit of the top unread

character in the receive FIFO. When reading 9-bit data

from the receive FIFO buffer, the RX9D data bit must

be read before reading the eight Least Significant bits

from the RCREG.

27.5.1.9

Synchronous Master Reception

Set-up:

To initiate reception, set either SREN or CREN. Data is

sampled at the RX/DT pin on the trailing edge of the

TX/CK clock pin and is shifted into the Receive Shift

Register (RSR). When a complete character is

received into the RSR, the RCIF bit is set and the char-

acter is automatically transferred to the two character

receive FIFO. The Least Significant eight bits of the top

character in the receive FIFO are available in RCREG.

The RCIF bit remains set as long as there are unread

characters in the receive FIFO.

1. Initialize the SPBRGH, SPBRGL register pair for

the appropriate baud rate. Set or clear the

BRGH and BRG16 bits, as required, to achieve

the desired baud rate.

2. Clear the ANSEL bit for the RX pin (if applicable).

3. Enable the synchronous master serial port by

setting bits SYNC, SPEN and CSRC.

4. Ensure bits CREN and SREN are clear.

Note:

If the RX/DT function is on an analog pin,

the corresponding ANSEL bit must be

cleared for the receiver to function.

5. If interrupts are desired, set the RCIE bit of the

PIE1 register and the GIE and PEIE bits of the

INTCON register.

6. If 9-bit reception is desired, set bit RX9.

27.5.1.6

Slave Clock

7. Start reception by setting the SREN bit or for

continuous reception, set the CREN bit.

Synchronous data transfers use a separate clock line,

which is synchronous with the data. A device configured

as a slave receives the clock on the TX/CK line. The

TX/CK pin output driver is automatically disabled when

the device is configured for synchronous slave transmit

or receive operation. Serial data bits change on the

leading edge to ensure they are valid at the trailing edge

of each clock. One data bit is transferred for each clock

cycle. Only as many clock cycles should be received as

there are data bits.

8. Interrupt flag bit RCIF will be set when reception

of a character is complete. An interrupt will be

generated if the enable bit RCIE was set.

9. Read the RCSTA register to get the ninth bit (if

enabled) and determine if any error occurred

during reception.

10. Read the 8-bit received data by reading the

RCREG register.

11. If an overrun error occurs, clear the error by

either clearing the CREN bit of the RCSTA

register or by clearing the SPEN bit which resets

the EUSART.

Note:

If the device is configured as a slave and

the TX/CK function is on an analog pin, the

corresponding ANSEL bit must be cleared.

27.5.1.7

Receive Overrun Error

The receive FIFO buffer can hold two characters. An

overrun error will be generated if a third character, in its

entirety, is received before RCREG is read to access

the FIFO. When this happens the OERR bit of the

RCSTA register is set. Previous data in the FIFO will

not be overwritten. The two characters in the FIFO

buffer can be read, however, no additional characters

DS40001579E-page 334

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 27-12:

SYNCHRONOUS RECEPTION (MASTER MODE, SREN)

RX/DT

bit 0

bit 1

bit 2

bit 3

bit 4

bit 5

bit 6

bit 7

TX/CK pin

(SCKP = 0)

TX/CK pin

(SCKP = 1)

Write to

bit SREN

SREN bit

‘0’

CREN bit

RCIF bit

(Interrupt)

Read

RCREG

Note:

Timing diagram demonstrates Sync Master mode with bit SREN = 1and bit BRGH = 0.

TABLE 27-8: SUMMARY OF REGISTERS ASSOCIATED WITH SYNCHRONOUS MASTER

RECEPTION

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

APFCON

BAUDCON

INTCON

PIE1

C2OUTSEL CC1PSEL SDOSEL

SCKSEL

SCKP

INTE

SDISEL

BRG16

IOCIE

TXSEL

—

RXSEL

WUE

CCP2SEL

ABDEN

IOCIF

111

322

79

ABDOVF

GIE

RCIDL

PEIE

ADIE

ADIF

—

TMR0IE

RCIE

TMR0IF

CCP1IE

CCP1IF

INTF

TMR1GIE

TMR1GIF

TXIE

SSP1IE

SSP1IF

TMR2IE

TMR2IF

TMR1IE

TMR1IF

80

PIR1

RCIF

TXIF

83

RCREG

RCSTA

SPBRGL

SPBRGH

TRISC

EUSART Receive Data Register

315*

321

323

125

320

SPEN

RX9

SREN

CREN

BRG<7:0>

BRG<15:8>

ADDEN

FERR

OERR

RX9D

TRISC7

CSRC

TRISC6

TX9

TRISC5

TXEN

TRISC4

SYNC

TRISC3

SENDB

TRISC2

BRGH

TRISC1

TRMT

TRISC0

TX9D

TXSTA

Legend:

— = unimplemented location, read as ‘0’. Shaded cells are not used for synchronous master reception.

*

Page provides register information.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 335

PIC16(L)F1782/3

If two words are written to the TXREG and then the

SLEEPinstruction is executed, the following will occur:

27.5.2

SYNCHRONOUS SLAVE MODE

The following bits are used to configure the EUSART

for synchronous slave operation:

1. The first character will immediately transfer to

the TSR register and transmit.

• SYNC = 1

2. The second word will remain in TXREG register.

3. The TXIF bit will not be set.

• CSRC = 0

• SREN = 0(for transmit); SREN = 1(for receive)

• CREN = 0(for transmit); CREN = 1(for receive)

• SPEN = 1

4. After the first character has been shifted out of

TSR, the TXREG register will transfer the second

character to the TSR and the TXIF bit will now be

set.

Setting the SYNC bit of the TXSTA register configures the

device for synchronous operation. Clearing the CSRC bit

of the TXSTA register configures the device as a slave.

Clearing the SREN and CREN bits of the RCSTA register

ensures that the device is in the Transmit mode,

otherwise the device will be configured to receive. Setting

the SPEN bit of the RCSTA register enables the

EUSART.

5. If the PEIE and TXIE bits are set, the interrupt

will wake the device from Sleep and execute the

next instruction. If the GIE bit is also set, the

program will call the Interrupt Service Routine.

27.5.2.2

Synchronous Slave Transmission

Set-up:

1. Set the SYNC and SPEN bits and clear the

CSRC bit.

27.5.2.1

EUSART Synchronous Slave

Transmit

2. Clear the ANSEL bit for the CK pin (if applicable).

3. Clear the CREN and SREN bits.

The operation of the Synchronous Master and Slave

modes are identical (see Section 27.5.1.3

“Synchronous Master Transmission”), except in the

4. If interrupts are desired, set the TXIE bit of the

PIE1 register and the GIE and PEIE bits of the

INTCON register.

case of the Sleep mode.

5. If 9-bit transmission is desired, set the TX9 bit.

6. Enable transmission by setting the TXEN bit.

7. If 9-bit transmission is selected, insert the Most

Significant bit into the TX9D bit.

8. Start transmission by writing the Least

Significant 8 bits to the TXREG register.

TABLE 27-9: SUMMARY OF REGISTERS ASSOCIATED WITH SYNCHRONOUS SLAVE

TRANSMISSION

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

APFCON

BAUDCON

INTCON

PIE1

C2OUTSEL CC1PSEL SDOSEL

SCKSEL

SCKP

INTE

SDISEL

BRG16

IOCIE

TXSEL

—

RXSEL

WUE

CCP2SEL

ABDEN

IOCIF

111

322

79

ABDOVF

GIE

RCIDL

PEIE

—

TMR0IE

RCIE

TMR0IF

CCP1IE

CCP1IF

FERR

INTF

TMR1GIE

TMR1GIF

SPEN

ADIE

TXIE

SSP1IE

SSP1IF

ADDEN

TRISC3

TMR2IE

TMR2IF

OERR

TRISC1

TMR1IE

TMR1IF

RX9D

80

PIR1

ADIF

RCIF

TXIF

83

RCSTA

TRISC

TXREG

RX9

SREN

TRISC5

CREN

TRISC4

321

125

312*

320

TRISC7

TRISC6

TRISC2

TRISC0

EUSART Transmit Data Register

TXEN SYNC SENDB

TXSTA

CSRC

TX9

BRGH

TRMT

TX9D

Legend:

— = unimplemented location, read as ‘0’. Shaded cells are not used for synchronous slave transmission.

*

Page provides register information.

DS40001579E-page 336

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

27.5.2.3

EUSART Synchronous Slave

Reception

27.5.2.4

Synchronous Slave Reception

Set-up:

The operation of the Synchronous Master and Slave

modes is identical (Section 27.5.1.5 “Synchronous

Master Reception”), with the following exceptions:

1. Set the SYNC and SPEN bits and clear the

CSRC bit.

2. Clear the ANSEL bit for both the CK and DT pins

(if applicable).

• Sleep

3. If interrupts are desired, set the RCIE bit of the

PIE1 register and the GIE and PEIE bits of the

INTCON register.

• CREN bit is always set, therefore the receiver is

never idle

• SREN bit, which is a “don’t care” in Slave mode

4. If 9-bit reception is desired, set the RX9 bit.

5. Set the CREN bit to enable reception.

A character may be received while in Sleep mode by

setting the CREN bit prior to entering Sleep. Once the

word is received, the RSR register will transfer the data

to the RCREG register. If the RCIE enable bit is set, the

interrupt generated will wake the device from Sleep

and execute the next instruction. If the GIE bit is also

set, the program will branch to the interrupt vector.

6. The RCIF bit will be set when reception is

complete. An interrupt will be generated if the

RCIE bit was set.

7. If 9-bit mode is enabled, retrieve the Most

Significant bit from the RX9D bit of the RCSTA

register.

8. Retrieve the eight Least Significant bits from the

receive FIFO by reading the RCREG register.

9. If an overrun error occurs, clear the error by

either clearing the CREN bit of the RCSTA

register or by clearing the SPEN bit which resets

the EUSART.

TABLE 27-10: SUMMARY OF REGISTERS ASSOCIATED WITH SYNCHRONOUS SLAVE

RECEPTION

Register

on Page

Name

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

APFCON

BAUDCON

INTCON

PIE1

C2OUTSEL CC1PSEL SDOSEL

SCKSEL

SCKP

INTE

SDISEL

BRG16

IOCIE

TXSEL

—

RXSEL

WUE

CCP2SEL

ABDEN

IOCIF

111

322

79

ABDOVF

GIE

RCIDL

PEIE

ADIE

ADIF

—

TMR0IE

RCIE

TMR0IF

CCP1IE

CCP1IF

INTF

TMR1GIE

TMR1GIF

TXIE

SSP1IE

SSP1IF

TMR2IE

TMR2IF

TMR1IE

TMR1IF

80

PIR1

RCIF

TXIF

83

RCREG

RCSTA

TRISC

EUSART Receive Data Register

315*

321

125

320

SPEN

TRISC7

CSRC

RX9

TRISC6

TX9

SREN

TRISC5

TXEN

CREN

TRISC4

SYNC

ADDEN

TRISC3

SENDB

FERR

TRISC2

BRGH

OERR

TRISC1

TRMT

RX9D

TRISC0

TX9D

TXSTA

Legend:

— = unimplemented location, read as ‘0’. Shaded cells are not used for synchronous slave reception.

*

Page provides register information.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 337

PIC16(L)F1782/3

27.6.2

SYNCHRONOUS TRANSMIT

DURING SLEEP

27.6 EUSART Operation During Sleep

The EUSART will remain active during Sleep only in the

Synchronous Slave mode. All other modes require the

system clock and therefore cannot generate the

necessary signals to run the Transmit or Receive Shift

registers during Sleep.

To transmit during Sleep, all the following conditions

must be met before entering Sleep mode:

• RCSTA and TXSTA Control registers must be

configured for synchronous slave transmission

(see Section 27.5.2.2 “Synchronous Slave

Transmission Set-up:”).

Synchronous Slave mode uses an externally generated

clock to run the Transmit and Receive Shift registers.

• The TXIF interrupt flag must be cleared by writing

the output data to the TXREG, thereby filling the

TSR and transmit buffer.

27.6.1

SYNCHRONOUS RECEIVE DURING

SLEEP

• If interrupts are desired, set the TXIE bit of the

PIE1 register and the PEIE bit of the INTCON reg-

ister.

To receive during Sleep, all the following conditions

must be met before entering Sleep mode:

• RCSTA and TXSTA Control registers must be

configured for Synchronous Slave Reception (see

Section 27.5.2.4 “Synchronous Slave

Reception Set-up:”).

• Interrupt enable bits TXIE of the PIE1 register and

PEIE of the INTCON register must set.

Upon entering Sleep mode, the device will be ready to

accept clocks on TX/CK pin and transmit data on the

RX/DT pin. When the data word in the TSR has been

completely clocked out by the external device, the

pending byte in the TXREG will transfer to the TSR and

the TXIF flag will be set. Thereby, waking the processor

from Sleep. At this point, the TXREG is available to

accept another character for transmission, which will

clear the TXIF flag.

• If interrupts are desired, set the RCIE bit of the

PIE1 register and the GIE and PEIE bits of the

INTCON register.

• The RCIF interrupt flag must be cleared by read-

ing RCREG to unload any pending characters in

the receive buffer.

Upon entering Sleep mode, the device will be ready to

accept data and clocks on the RX/DT and TX/CK pins,

respectively. When the data word has been completely

clocked in by the external device, the RCIF interrupt

flag bit of the PIR1 register will be set. Thereby, waking

the processor from Sleep.

Upon waking from Sleep, the instruction following the

SLEEP instruction will be executed. If the Global

Interrupt Enable (GIE) bit is also set then the Interrupt

Service Routine at address 0004h will be called.

Upon waking from Sleep, the instruction following the

SLEEPinstruction will be executed. If the Global Inter-

rupt Enable (GIE) bit of the INTCON register is also set,

then the Interrupt Service Routine at address 004h will

be called.

27.6.3

ALTERNATE PIN LOCATIONS

This module incorporates I/O pins that can be moved to

other locations with the use of the alternate pin function

register, APFCON. To determine which pins can be

moved and what their default locations are upon a

Reset, see Section 13.1 “Alternate Pin Function” for

more information.

DS40001579E-page 338

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

28.3 Common Programming Interfaces

28.0 IN-CIRCUIT SERIAL

PROGRAMMING™ (ICSP™)

Connection to a target device is typically done through

an ICSP™ header. A commonly found connector on

development tools is the RJ-11 in the 6P6C (6-pin, 6

connector) configuration. See Figure 28-1.

ICSP™ programming allows customers to manufacture

circuit boards with unprogrammed devices. Programming

can be done after the assembly process, allowing the

device to be programmed with the most recent firmware

or a custom firmware. Five pins are needed for ICSP™

programming:

FIGURE 28-1:

ICD RJ-11 STYLE

CONNECTOR INTERFACE

• ICSPCLK

• ICSPDAT

• MCLR/VPP

• VDD

ICSPDAT

• VSS

NC

2 4 6

VDD

In Program/Verify mode the program memory, user IDs

and the Configuration Words are programmed through

serial communications. The ICSPDAT pin is

bidirectional I/O used for transferring the serial data

and the ICSPCLK pin is the clock input. For more

information on ICSP™ refer to the “PIC16(L)F178X

Memory Programming Specification” (DS41457).

ICSPCLK

1 3

5

Target

PC Board

Bottom Side

a

VPP/MCLR

VSS

Pin Description*

1 = VPP/MCLR

2 = VDD Target

3 = VSS (ground)

4 = ICSPDAT

28.1 High-Voltage Programming Entry

Mode

The device is placed into High-Voltage Programming

Entry mode by holding the ICSPCLK and ICSPDAT

pins low then raising the voltage on MCLR/VPP to VIHH.

5 = ICSPCLK

6 = No Connect

28.2 Low-Voltage Programming Entry

Mode

Another connector often found in use with the PICkit™

programmers is a standard 6-pin header with 0.1 inch

spacing. Refer to Figure 28-2.

The Low-Voltage Programming Entry mode allows the

PIC^®Flash MCUs to be programmed using VDD only,

without high voltage. When the LVP bit of Configuration

Words is set to ‘1’, the low-voltage ICSP programming

entry is enabled. To disable the Low-Voltage ICSP

mode, the LVP bit must be programmed to ‘0’.

For additional interface recommendations, refer to your

specific device programmer manual prior to PCB

design.

It is recommended that isolation devices be used to

separate the programming pins from other circuitry.

The type of isolation is highly dependent on the specific

application and may include devices such as resistors,

diodes, or even jumpers. See Figure 28-3 for more

information.

Entry into the Low-Voltage Programming Entry mode

requires the following steps:

1. MCLR is brought to VIL.

2.

A

32-bit key sequence is presented on

ICSPDAT, while clocking ICSPCLK.

Once the key sequence is complete, MCLR must be

held at VIL for as long as Program/Verify mode is to be

maintained.

If low-voltage programming is enabled (LVP = 1), the

MCLR Reset function is automatically enabled and

cannot be disabled. See Section 5.5 “MCLR” for more

information.

The LVP bit can only be reprogrammed to ‘0’ by using

the High-Voltage Programming mode.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 339

PIC16(L)F1782/3

FIGURE 28-2:

PICkit™ PROGRAMMER STYLE CONNECTOR INTERFACE

Pin 1 Indicator

Pin Description*

1 = VPP/MCLR

2 = VDD Target

3 = VSS (ground)

4 = ICSPDAT

1

2

3

4

5

6

5 = ICSPCLK

6 = No Connect

*

The 6-pin header (0.100" spacing) accepts 0.025" square pins.

FIGURE 28-3:

TYPICAL CONNECTION FOR ICSP™ PROGRAMMING

External

Programming

Signals

Device to be

Programmed

VDD

VPP

VSS

MCLR/VPP

VSS

Data

ICSPDAT

ICSPCLK

Clock

*

To Normal Connections

Isolation devices (as required).

*

DS40001579E-page 340

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

29.1 Read-Modify-Write Operations

29.0 INSTRUCTION SET SUMMARY

Any instruction that specifies a file register as part of

the instruction performs a Read-Modify-Write (R-M-W)

operation. The register is read, the data is modified,

and the result is stored according to either the instruc-

tion, or the destination designator ‘d’. A read operation

is performed on a register even if the instruction writes

to that register.

Each instruction is a 14-bit word containing the

operation code (opcode) and all required operands.

The opcodes are broken into three broad categories.

• Byte Oriented

• Bit Oriented

• Literal and Control

The literal and control category contains the most

varied instruction word format.

TABLE 29-1: OPCODE FIELD

DESCRIPTIONS

Table 29-3 lists the instructions recognized by the

MPASM^TMassembler.

Field

Description

All instructions are executed within a single instruction

cycle, with the following exceptions, which may take

two or three cycles:

f

W

b

Register file address (0x00 to 0x7F)

Working register (accumulator)

Bit address within an 8-bit file register

Literal field, constant data or label

• Subroutine takes two cycles (CALL, CALLW)

• Returns from interrupts or subroutines take two

cycles (RETURN, RETLW, RETFIE)

k

x

Don’t care location (= 0or 1).

• Program branching takes two cycles (GOTO, BRA,

BRW, BTFSS, BTFSC, DECFSZ, INCSFZ)

• One additional instruction cycle will be used when

any instruction references an indirect file register

and the file select register is pointing to program

memory.

The assembler will generate code with x = 0.

It is the recommended form of use for

compatibility with all Microchip software tools.

d

Destination select; d = 0: store result in W,

d = 1: store result in file register f.

Default is d = 1.

One instruction cycle consists of 4 oscillator cycles; for

an oscillator frequency of 4 MHz, this gives a nominal

instruction execution rate of 1 MHz.

n

FSR or INDF number. (0-1)

mm

Pre-post increment-decrement mode

selection

All instruction examples use the format ‘0xhh’ to

represent a hexadecimal number, where ‘h’ signifies a

hexadecimal digit.

TABLE 29-2: ABBREVIATION

DESCRIPTIONS

Field

Description

PC

TO

C

Program Counter

Time-out bit

Carry bit

DC

Z

Digit carry bit

Zero bit

PD

Power-down bit

 2011-2014 Microchip Technology Inc.

DS40001579E-page 341

PIC16(L)F1782/3

FIGURE 29-1:

GENERAL FORMAT FOR

INSTRUCTIONS

Byte-oriented file register operations

13

8

7

6

0

OPCODE

d

f (FILE #)

d = 0for destination W

d = 1for destination f

f = 7-bit file register address

Bit-oriented file register operations

13 10 9

7 6

0

OPCODE

b (BIT #)

f (FILE #)

b = 3-bit bit address

f = 7-bit file register address

Literal and control operations

General

13

8

7

0

OPCODE

k (literal)

k = 8-bit immediate value

CALLand GOTOinstructions only

13 11 10

OPCODE

0

k (literal)

k = 11-bit immediate value

MOVLPinstruction only

13

7

6

0

OPCODE

k (literal)

k = 7-bit immediate value

MOVLBinstruction only

13

5 4

OPCODE

k (literal)

k = 5-bit immediate value

BRAinstruction only

13

9

8

0

OPCODE

k (literal)

k = 9-bit immediate value

FSR Offset instructions

13

7

6

5

0

OPCODE

n

k (literal)

n = appropriate FSR

k = 6-bit immediate value

FSRIncrement instructions

13

3

2

n

1

OPCODE

m (mode)

n = appropriate FSR

m = 2-bit mode value

OPCODE only

13

0

OPCODE

DS40001579E-page 342

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 29-3: INSTRUCTION SET

14-Bit Opcode

Status

Mnemonic,

Operands

Description

Cycles

Notes

Affected

MSb

LSb

BYTE-ORIENTED FILE REGISTER OPERATIONS

ADDWF

ADDWFC f, d

ANDWF

ASRF

LSLF

f, d

Add W and f

Add with Carry W and f

AND W with f

Arithmetic Right Shift

Logical Left Shift

Logical Right Shift

Clear f

Clear W

Complement f

Decrement f

Increment f

Inclusive OR W with f

Move f

Move W to f

Rotate Left f through Carry

Rotate Right f through Carry

Subtract W from f

Subtract with Borrow W from f

Swap nibbles in f

Exclusive OR W with f

1

00 0111 dfff ffff C, DC, Z

11 1101 dfff ffff C, DC, Z

00 0101 dfff ffff Z

11 0111 dfff ffff C, Z

11 0101 dfff ffff C, Z

11 0110 dfff ffff C, Z

2

f, d

f

LSRF

CLRF

CLRW

COMF

DECF

INCF

IORWF

MOVF

MOVWF

RLF

RRF

SUBWF

SUBWFB f, d

SWAPF

XORWF

00 0001 lfff ffff

00 0001 0000 00xx

00 1001 dfff ffff

00 0011 dfff ffff

00 1010 dfff ffff

00 0100 dfff ffff

00 1000 dfff ffff

00 0000 1fff ffff

00 1101 dfff ffff

00 1100 dfff ffff

Z

–

f, d

f

f, d

2

C

00 0010 dfff ffff C, DC, Z

11 1011 dfff ffff C, DC, Z

00 1110 dfff ffff

f, d

00 0110 dfff ffff

Z

BYTE ORIENTED SKIP OPERATIONS

f, d

Decrement f, Skip if 0

Increment f, Skip if 0

1(2)

00

1011 dfff ffff

1111 dfff ffff

1, 2

DECFSZ

INCFSZ

BIT-ORIENTED FILE REGISTER OPERATIONS

f, b

Bit Clear f

Bit Set f

1

01

00bb bfff ffff

01bb bfff ffff

2

BCF

BSF

BIT-ORIENTED SKIP OPERATIONS

BTFSC

BTFSS

f, b

Bit Test f, Skip if Clear

Bit Test f, Skip if Set

1 (2)

01

10bb bfff ffff

11bb bfff ffff

1, 2

LITERAL OPERATIONS

ADDLW

ANDLW

IORLW

MOVLB

MOVLP

MOVLW

SUBLW

XORLW

k

Add literal and W

AND literal with W

Inclusive OR literal with W

Move literal to BSR

Move literal to PCLATH

Move literal to W

1

11

00

11

1110 kkkk kkkk C, DC, Z

1001 kkkk kkkk

1000 kkkk kkkk

0000 001k kkkk

0001 1kkk kkkk

0000 kkkk kkkk

Z

Subtract W from literal

Exclusive OR literal with W

1100 kkkk kkkk C, DC, Z

1010 kkkk kkkk

Z

Note 1: If the Program Counter (PC) is modified, or a conditional test is true, the instruction requires two cycles. The second

cycle is executed as a NOP.

2: If this instruction addresses an INDF register and the MSb of the corresponding FSR is set, this instruction will require

one additional instruction cycle.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 343

PIC16(L)F1782/3

TABLE 29-3: INSTRUCTION SET (CONTINUED)

14-Bit Opcode

Mnemonic,

Description

Operands

Status

Affected

Cycles

Notes

MSb

LSb

CONTROL OPERATIONS

BRA

BRW

CALL

CALLW

GOTO

RETFIE

RETLW

RETURN

k

–

k

–

k

–

Relative Branch

Relative Branch with W

Call Subroutine

Call Subroutine with W

Go to address

Return from interrupt

Return with literal in W

Return from Subroutine

2

11

00

10

00

10

00

11

00

001k kkkk kkkk

0000 0000 1011

0kkk kkkk kkkk

0000 0000 1010

1kkk kkkk kkkk

0000 0000 1001

0100 kkkk kkkk

0000 0000 1000

INHERENT OPERATIONS

CLRWDT

NOP

OPTION

RESET

SLEEP

TRIS

–

f

Clear Watchdog Timer

No Operation

Load OPTION_REG register with W

Software device Reset

Go into Standby mode

Load TRIS register with W

1

00

0000 0110 0100 TO, PD

0000 0000 0000

0000 0110 0010

0000 0000 0001

0000 0110 0011 TO, PD

0000 0110 0fff

C-COMPILER OPTIMIZED

ADDFSR n, k

Add Literal k to FSRn

Move Indirect FSRn to W with pre/post inc/dec

modifier, mm

1

11 0001 0nkk kkkk

00 0000 0001 0nmm

MOVIW

n mm

Z

2, 3

k[n]

n mm

Move INDFn to W, Indexed Indirect.

Move W to Indirect FSRn with pre/post inc/dec

modifier, mm

1

11 1111 0nkk kkkk

00 0000 0001 1nmm

2

2, 3

MOVWI

k[n]

Move W to INDFn, Indexed Indirect.

1

11 1111 1nkk kkkk

2

Note 1: If the Program Counter (PC) is modified, or a conditional test is true, the instruction requires two cycles. The second

cycle is executed as a NOP.

2: If this instruction addresses an INDF register and the MSb of the corresponding FSR is set, this instruction will require

one additional instruction cycle.

3: See Table in the MOVIW and MOVWI instruction descriptions.

DS40001579E-page 344

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

29.2 Instruction Descriptions

ADDFSR

Add Literal to FSRn

ANDLW

AND literal with W

Syntax:

[ label ] ADDFSR FSRn, k

Syntax:

[ label ] ANDLW

0  k  255

k

Operands:

-32  k  31

n  [ 0, 1]

Operands:

Operation:

Status Affected:

Description:

(W) .AND. (k)  (W)

Operation:

FSR(n) + k  FSR(n)

Z

Status Affected:

Description:

None

The contents of W register are

AND’ed with the 8-bit literal ‘k’. The

result is placed in the W register.

The signed 6-bit literal ‘k’ is added to

the contents of the FSRnH:FSRnL

register pair.

FSRn is limited to the range 0000h -

FFFFh. Moving beyond these bounds

will cause the FSR to wrap-around.

ANDWF

AND W with f

ADDLW

Add literal and W

Syntax:

[ label ] ANDWF f,d

Syntax:

[ label ] ADDLW

0  k  255

k

Operands:

0  f  127

d 0,1

Operands:

Operation:

Status Affected:

Description:

(W) + k  (W)

C, DC, Z

Operation:

(W) .AND. (f)  (destination)

Status Affected:

Description:

Z

The contents of the W register are

added to the 8-bit literal ‘k’ and the

result is placed in the W register.

AND the W register with register ‘f’. If

‘d’ is ‘0’, the result is stored in the W

register. If ‘d’ is ‘1’, the result is stored

back in register ‘f’.

ASRF

Arithmetic Right Shift

ADDWF

Add W and f

Syntax:

[ label ] ASRF f {,d}

Syntax:

[ label ] ADDWF f,d

Operands:

0  f  127

d [0,1]

Operands:

0  f  127

d 0,1

Operation:

(f<7>) dest<7>

(f<7:1>)  dest<6:0>,

(f<0>)  C,

Operation:

(W) + (f)  (destination)

Status Affected:

Description:

C, DC, Z

Add the contents of the W register

with register ‘f’. If ‘d’ is ‘0’, the result is

stored in the W register. If ‘d’ is ‘1’, the

result is stored back in register ‘f’.

Status Affected:

Description:

C, Z

The contents of register ‘f’ are shifted

one bit to the right through the Carry

flag. The MSb remains unchanged. If

‘d’ is ‘0’, the result is placed in W. If ‘d’

is ‘1’, the result is stored back in reg-

ister ‘f’.

ADDWFC

ADD W and CARRY bit to f

C

register f

Syntax:

[ label ] ADDWFC

f {,d}

Operands:

0  f  127

d [0,1]

Operation:

(W) + (f) + (C)  dest

Status Affected:

Description:

C, DC, Z

Add W, the Carry flag and data mem-

ory location ‘f’. If ‘d’ is ‘0’, the result is

placed in W. If ‘d’ is ‘1’, the result is

placed in data memory location ‘f’.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 345

PIC16(L)F1782/3

BTFSC

Bit Test f, Skip if Clear

BCF

Bit Clear f

Syntax:

[ label ] BTFSC f,b

Syntax:

[ label ] BCF f,b

Operands:

0  f  127

0  b  7

Operands:

0  f  127

0  b  7

Operation:

skip if (f<b>) = 0

Operation:

0 (f<b>)

Status Affected:

Description:

None

Status Affected:

Description:

None

If bit ‘b’ in register ‘f’ is ‘1’, the next

instruction is executed.

Bit ‘b’ in register ‘f’ is cleared.

If bit ‘b’, in register ‘f’, is ‘0’, the next

instruction is discarded, and a NOPis

executed instead, making this a

2-cycle instruction.

BTFSS

Bit Test f, Skip if Set

BRA

Relative Branch

Syntax:

[ label ] BTFSS f,b

Syntax:

[ label ] BRA label

[ label ] BRA $+k

Operands:

0  f  127

0  b < 7

Operands:

-256  label - PC + 1  255

-256  k  255

Operation:

skip if (f<b>) = 1

Operation:

(PC) + 1 + k  PC

Status Affected:

Description:

None

Status Affected:

Description:

None

If bit ‘b’ in register ‘f’ is ‘0’, the next

instruction is executed.

If bit ‘b’ is ‘1’, then the next

instruction is discarded and a NOPis

executed instead, making this a

2-cycle instruction.

Add the signed 9-bit literal ‘k’ to the

PC. Since the PC will have incre-

mented to fetch the next instruction,

the new address will be PC + 1 + k.

This instruction is a 2-cycle instruc-

tion. This branch has a limited range.

BRW

Relative Branch with W

Syntax:

[ label ] BRW

None

Operands:

Operation:

Status Affected:

Description:

(PC) + (W)  PC

None

Add the contents of W (unsigned) to

the PC. Since the PC will have incre-

mented to fetch the next instruction,

the new address will be PC + 1 + (W).

This instruction is a 2-cycle instruc-

tion.

BSF

Bit Set f

Syntax:

[ label ] BSF f,b

Operands:

0  f  127

0  b  7

Operation:

1 (f<b>)

Status Affected:

Description:

None

Bit ‘b’ in register ‘f’ is set.

DS40001579E-page 346

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

CALL

Call Subroutine

CLRWDT

Clear Watchdog Timer

Syntax:

[ label ] CALL

0  k  2047

k

Syntax:

[ label ] CLRWDT

Operands:

Operation:

Operands:

Operation:

None

(PC)+ 1 TOS,

k  PC<10:0>,

(PCLATH<6:3>)  PC<14:11>

00h  WDT

0 WDT prescaler,

1 TO

1 PD

Status Affected:

Description:

None

Status Affected:

Description:

TO, PD

Call Subroutine. First, return address

(PC + 1) is pushed onto the stack.

The eleven-bit immediate address is

loaded into PC bits <10:0>. The upper

bits of the PC are loaded from

PCLATH. CALLis a 2-cycle instruc-

tion.

CLRWDTinstruction resets the Watch-

dog Timer. It also resets the prescaler

of the WDT.

Status bits TO and PD are set.

COMF

Complement f

CALLW

Subroutine Call With W

Syntax:

[ label ] COMF f,d

Syntax:

[ label ] CALLW

Operands:

0  f  127

d  [0,1]

Operands:

Operation:

None

(PC) +1  TOS,

(W)  PC<7:0>,

Operation:

(f)  (destination)

(PCLATH<6:0>) PC<14:8>

Status Affected:

Description:

Z

The contents of register ‘f’ are com-

plemented. If ‘d’ is ‘0’, the result is

stored in W. If ‘d’ is ‘1’, the result is

stored back in register ‘f’.

Status Affected:

Description:

None

Subroutine call with W. First, the

return address (PC + 1) is pushed

onto the return stack. Then, the con-

tents of W is loaded into PC<7:0>,

and the contents of PCLATH into

PC<14:8>. CALLWis a 2-cycle

instruction.

DECF

Decrement f

CLRF

Clear f

Syntax:

[ label ] DECF f,d

Syntax:

[ label ] CLRF

0  f  127

f

Operands:

0  f  127

d  [0,1]

Operands:

Operation:

00h  (f)

1 Z

Operation:

(f) - 1  (destination)

Status Affected:

Description:

Z

Status Affected:

Description:

Z

Decrement register ‘f’. If ‘d’ is ‘0’, the

result is stored in the W register. If ‘d’

is ‘1’, the result is stored back in regis-

ter ‘f’.

The contents of register ‘f’ are cleared

and the Z bit is set.

CLRW

Clear W

Syntax:

[ label ] CLRW

Operands:

Operation:

None

00h  (W)

1 Z

Status Affected:

Description:

Z

W register is cleared. Zero bit (Z) is

set.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 347

PIC16(L)F1782/3

DECFSZ

Decrement f, Skip if 0

INCFSZ

Increment f, Skip if 0

Syntax:

[ label ] DECFSZ f,d

Syntax:

[ label ] INCFSZ f,d

Operands:

0  f  127

d  [0,1]

Operands:

0  f  127

d  [0,1]

Operation:

(f) - 1  (destination);

skip if result = 0

Operation:

(f) + 1  (destination),

skip if result = 0

Status Affected:

Description:

None

Status Affected:

Description:

None

The contents of register ‘f’ are decre-

mented. If ‘d’ is ‘0’, the result is placed

in the W register. If ‘d’ is ‘1’, the result

is placed back in register ‘f’.

The contents of register ‘f’ are incre-

mented. If ‘d’ is ‘0’, the result is placed

in the W register. If ‘d’ is ‘1’, the result

is placed back in register ‘f’.

If the result is ‘1’, the next instruction is

executed. If the result is ‘0’, then a

NOPis executed instead, making it a

2-cycle instruction.

If the result is ‘1’, the next instruction is

executed. If the result is ‘0’, a NOPis

executed instead, making it a 2-cycle

instruction.

GOTO

Unconditional Branch

IORLW

Inclusive OR literal with W

Syntax:

[ label ] GOTO

0  k  2047

k

Syntax:

[ label ] IORLW

0  k  255

(W) .OR. k  (W)

Z

k

Operands:

Operation:

Operands:

Operation:

Status Affected:

Description:

k  PC<10:0>

PCLATH<6:3>  PC<14:11>

Status Affected:

Description:

None

The contents of the W register are

OR’ed with the 8-bit literal ‘k’. The

result is placed in the W register.

GOTOis an unconditional branch. The

11-bit immediate value is loaded into

PC bits <10:0>. The upper bits of PC

are loaded from PCLATH<4:3>. GOTO

is a 2-cycle instruction.

INCF

Increment f

IORWF

Inclusive OR W with f

Syntax:

[ label ] INCF f,d

Syntax:

[ label ] IORWF f,d

Operands:

0  f  127

d  [0,1]

Operands:

0  f  127

d  [0,1]

Operation:

(f) + 1  (destination)

Operation:

(W) .OR. (f)  (destination)

Status Affected:

Description:

Z

Status Affected:

Description:

Z

The contents of register ‘f’ are incre-

mented. If ‘d’ is ‘0’, the result is placed

in the W register. If ‘d’ is ‘1’, the result

is placed back in register ‘f’.

Inclusive OR the W register with regis-

ter ‘f’. If ‘d’ is ‘0’, the result is placed in

the W register. If ‘d’ is ‘1’, the result is

placed back in register ‘f’.

DS40001579E-page 348

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

LSLF

Logical Left Shift

MOVF

Move f

Syntax:

[ label ] LSLF f {,d}

Syntax:

[ label ] MOVF f,d

Operands:

0  f  127

d [0,1]

Operands:

0  f  127

d  [0,1]

Operation:

(f<7>)  C

Operation:

(f)  (dest)

(f<6:0>)  dest<7:1>

0  dest<0>

Status Affected:

Description:

Z

The contents of register f is moved to

a destination dependent upon the

status of d. If d = 0, destination is W

register. If d = 1, the destination is file

register f itself. d = 1is useful to test a

file register since status flag Z is

affected.

Status Affected:

Description:

C, Z

The contents of register ‘f’ are shifted

one bit to the left through the Carry flag.

A ‘0’ is shifted into the LSb. If ‘d’ is ‘0’,

the result is placed in W. If ‘d’ is ‘1’, the

result is stored back in register ‘f’.

Words:

1

C

register f

0

Cycles:

Example:

MOVF

FSR, 0

After Instruction

LSRF

Logical Right Shift

W

Z

=

value in FSR register

1

Syntax:

[ label ] LSRF f {,d}

Operands:

0  f  127

d [0,1]

Operation:

0  dest<7>

(f<7:1>)  dest<6:0>,

(f<0>)  C,

Status Affected:

Description:

C, Z

The contents of register ‘f’ are shifted

one bit to the right through the Carry

flag. A ‘0’ is shifted into the MSb. If ‘d’ is

‘0’, the result is placed in W. If ‘d’ is ‘1’,

the result is stored back in register ‘f’.

0

C

register f

 2011-2014 Microchip Technology Inc.

DS40001579E-page 349

PIC16(L)F1782/3

MOVIW

Move INDFn to W

MOVLP

Move literal to PCLATH

Syntax:

[ label ] MOVIW ++FSRn

[ label ] MOVIW --FSRn

[ label ] MOVIW FSRn++

[ label ] MOVIW FSRn--

[ label ] MOVIW k[FSRn]

Syntax:

[ label ] MOVLP

0  k  127

k  PCLATH

None

k

Operands:

Operation:

Status Affected:

Description:

Operands:

Operation:

n  [0,1]

mm  [00,01, 10, 11]

-32  k  31

The 7-bit literal ‘k’ is loaded into the

PCLATH register.

INDFn  W

Effective address is determined by

• FSR + 1 (preincrement)

• FSR - 1 (predecrement)

• FSR + k (relative offset)

After the Move, the FSR value will be

either:

• FSR + 1 (all increments)

• FSR - 1 (all decrements)

• Unchanged

MOVLW

Move literal to W

Syntax:

[ label ] MOVLW

0  k  255

k  (W)

k

Operands:

Operation:

Status Affected:

Description:

None

The 8-bit literal ‘k’ is loaded into W reg-

ister. The “don’t cares” will assemble as

‘0’s.

Status Affected:

Z

Words:

1

Cycles:

Example:

Mode

Syntax

mm

00

01

10

11

MOVLW

0x5A

Preincrement

Predecrement

Postincrement

Postdecrement

++FSRn

--FSRn

FSRn++

FSRn--

After Instruction

W

=

0x5A

MOVWF

Move W to f

[ label ] MOVWF

0  f  127

(W)  (f)

Syntax:

f

Description:

This instruction is used to move data

between W and one of the indirect

registers (INDFn). Before/after this

move, the pointer (FSRn) is updated by

pre/post incrementing/decrementing it.

Operands:

Operation:

Status Affected:

Description:

None

Move data from W register to register

‘f’.

Note: The INDFn registers are not

physical registers. Any instruction that

accesses an INDFn register actually

accesses the register at the address

specified by the FSRn.

Words:

1

Cycles:

Example:

MOVWF

Before Instruction

OPTION_REG = 0xFF

W = 0x4F

OPTION_REG

FSRn is limited to the range 0000h -

FFFFh. Incrementing/decrementing it

beyond these bounds will cause it to

wrap-around.

After Instruction

OPTION_REG = 0x4F

W = 0x4F

MOVLB

Move literal to BSR

Syntax:

[ label ] MOVLB

0  k  31

k  BSR

None

k

Operands:

Operation:

Status Affected:

Description:

The 5-bit literal ‘k’ is loaded into the

Bank Select Register (BSR).

DS40001579E-page 350

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

NOP

No Operation

[ label ] NOP

None

MOVWI

Move W to INDFn

Syntax:

[ label ] MOVWI ++FSRn

[ label ] MOVWI --FSRn

[ label ] MOVWI FSRn++

[ label ] MOVWI FSRn--

[ label ] MOVWI k[FSRn]

Operands:

Operation:

No operation

Status Affected:

Description:

Words:

None

No operation.

Operands:

Operation:

n  [0,1]

mm  [00,01, 10, 11]

-32  k  31

1

Cycles:

1

W  INDFn

Example:

NOP

Effective address is determined by

• FSR + 1 (preincrement)

• FSR - 1 (predecrement)

• FSR + k (relative offset)

After the Move, the FSR value will be

either:

• FSR + 1 (all increments)

• FSR - 1 (all decrements)

Unchanged

Load OPTION_REG Register

with W

OPTION

Syntax:

[ label ] OPTION

None

Operands:

Operation:

Status Affected:

Description:

Status Affected:

None

(W)  OPTION_REG

None

Mode

Syntax

mm

00

01

10

11

Move data from W register to

OPTION_REG register.

Preincrement

Predecrement

Postincrement

Postdecrement

++FSRn

--FSRn

FSRn++

FSRn--

Words:

1

Cycles:

Example:

1

OPTION

Before Instruction

OPTION_REG = 0xFF

W = 0x4F

After Instruction

OPTION_REG = 0x4F

W = 0x4F

Description:

This instruction is used to move data

between W and one of the indirect

registers (INDFn). Before/after this

move, the pointer (FSRn) is updated by

pre/post incrementing/decrementing it.

Note: The INDFn registers are not

physical registers. Any instruction that

accesses an INDFn register actually

accesses the register at the address

specified by the FSRn.

RESET

Software Reset

Syntax:

[ label ] RESET

Operands:

Operation:

None

FSRn is limited to the range 0000h -

FFFFh. Incrementing/decrementing it

beyond these bounds will cause it to

wrap-around.

Execute a device Reset. Resets the

RI flag of the PCON register.

Status Affected:

Description:

None

This instruction provides a way to

execute a hardware Reset by soft-

ware.

The increment/decrement operation on

FSRn WILL NOT affect any Status bits.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 351

PIC16(L)F1782/3

RETURN

Return from Subroutine

RETFIE

Syntax:

Return from Interrupt

[ label ] RETFIE

None

Syntax:

[ label ] RETURN

None

Operands:

Operation:

Status Affected:

Description:

Operands:

Operation:

TOS  PC

None

TOS  PC,

1 GIE

Status Affected:

Description:

None

Return from subroutine. The stack is

POPed and the top of the stack (TOS)

is loaded into the program counter.

This is a 2-cycle instruction.

Return from Interrupt. Stack is POPed

and Top-of-Stack (TOS) is loaded in

the PC. Interrupts are enabled by

setting Global Interrupt Enable bit,

GIE (INTCON<7>). This is a 2-cycle

instruction.

Words:

1

Cycles:

Example:

2

RETFIE

After Interrupt

PC

=

TOS

GIE =

1

RETLW

Syntax:

Return with literal in W

RLF

Rotate Left f through Carry

[ label ] RETLW

0  k  255

k

Syntax:

Operands:

[ label ]

RLF f,d

Operands:

Operation:

0  f  127

d  [0,1]

k  (W);

TOS  PC

Operation:

See description below

C

Status Affected:

Description:

None

Status Affected:

Description:

The W register is loaded with the 8-bit

literal ‘k’. The program counter is

loaded from the top of the stack (the

return address). This is a 2-cycle

instruction.

The contents of register ‘f’ are rotated

one bit to the left through the Carry

flag. If ‘d’ is ‘0’, the result is placed in

the W register. If ‘d’ is ‘1’, the result is

stored back in register ‘f’.

Words:

1

2

C

Register f

Cycles:

Example:

CALL TABLE;W contains table

;offset value

Words:

1

Cycles:

Example:

•

;W now has table value

TABLE

RLF

REG1,0

Before Instruction

ADDWF PC ;W = offset

RETLW k1 ;Begin table

REG1

C

=

1110 0110

0

RETLW k2

;

After Instruction

•

REG1

W

C

=

1110 0110

1100 1100

1

RETLW kn ; End of table

Before Instruction

W

=

0x07

After Instruction

W

=

value of k8

DS40001579E-page 352

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

SUBLW

Subtract W from literal

RRF

Rotate Right f through Carry

Syntax:

[ label ] SUBLW

0 k 255

k

Syntax:

[ label ] RRF f,d

Operands:

Operation:

Status Affected:

Description:

Operands:

0  f  127

d  [0,1]

k - (W) W)

C, DC, Z

Operation:

See description below

C

The W register is subtracted (2’s com-

plement method) from the 8-bit literal

‘k’. The result is placed in the W regis-

ter.

Status Affected:

Description:

The contents of register ‘f’ are rotated

one bit to the right through the Carry

flag. If ‘d’ is ‘0’, the result is placed in

the W register. If ‘d’ is ‘1’, the result is

placed back in register ‘f’.

C = 0

W  k

C = 1

W  k

C

Register f

DC = 0

DC = 1

W<3:0>  k<3:0>

W<3:0>  k<3:0>

SUBWF

Subtract W from f

SLEEP

Enter Sleep mode

[ label ] SLEEP

None

Syntax:

[ label ] SUBWF f,d

Syntax:

Operands:

0 f 127

d  [0,1]

Operands:

Operation:

00h  WDT,

0 WDT prescaler,

1 TO,

Operation:

(f) - (W) destination)

Status Affected:

Description:

C, DC, Z

0 PD

Subtract (2’s complement method) W

register from register ‘f’. If ‘d’ is ‘0’, the

result is stored in the W

register. If ‘d’ is ‘1’, the result is stored

back in register ‘f.

Status Affected:

Description:

TO, PD

The power-down Status bit, PD is

cleared. Time-out Status bit, TO is

set. Watchdog Timer and its pres-

caler are cleared.

C = 0

W  f

The processor is put into Sleep mode

with the oscillator stopped.

C = 1

W  f

DC = 0

DC = 1

W<3:0>  f<3:0>

W<3:0>  f<3:0>

SUBWFB

Subtract W from f with Borrow

Syntax:

SUBWFB f {,d}

Operands:

0  f  127

d  [0,1]

Operation:

(f) – (W) – (B) dest

Status Affected:

Description:

C, DC, Z

Subtract W and the BORROW flag

(CARRY) from register ‘f’ (2’s comple-

ment method). If ‘d’ is ‘0’, the result is

stored in W. If ‘d’ is ‘1’, the result is

stored back in register ‘f’.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 353

PIC16(L)F1782/3

SWAPF

Swap Nibbles in f

XORLW

Exclusive OR literal with W

Syntax:

[ label ] SWAPF f,d

Syntax:

[ label ] XORLW

0 k 255

k

Operands:

0  f  127

d  [0,1]

Operands:

Operation:

Status Affected:

Description:

(W) .XOR. k W)

Z

Operation:

(f<3:0>)  (destination<7:4>),

(f<7:4>)  (destination<3:0>)

The contents of the W register are

XOR’ed with the 8-bit

literal ‘k’. The result is placed in the

W register.

Status Affected:

Description:

None

The upper and lower nibbles of regis-

ter ‘f’ are exchanged. If ‘d’ is ‘0’, the

result is placed in the W register. If ‘d’

is ‘1’, the result is placed in register ‘f’.

XORWF

Exclusive OR W with f

TRIS

Load TRIS Register with W

Syntax:

[ label ] XORWF f,d

Syntax:

[ label ] TRIS f

5  f  7

Operands:

0  f  127

d  [0,1]

Operands:

Operation:

Status Affected:

Description:

(W)  TRIS register ‘f’

None

Operation:

(W) .XOR. (f) destination)

Status Affected:

Description:

Z

Move data from W register to TRIS

register.

When ‘f’ = 5, TRISA is loaded.

When ‘f’ = 6, TRISB is loaded.

When ‘f’ = 7, TRISC is loaded.

Exclusive OR the contents of the W

register with register ‘f’. If ‘d’ is ‘0’, the

result is stored in the W register. If ‘d’

is ‘1’, the result is stored back in regis-

ter ‘f’.

DS40001579E-page 354

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

30.0 ELECTRICAL SPECIFICATIONS

(†)

30.1 Absolute Maximum Ratings

Ambient temperature under bias...................................................................................................... -40°C to +125°C

Storage temperature ........................................................................................................................ -65°C to +150°C

Voltage on pins with respect to VSS

on VDD pin

PIC16F1782/3 ........................................................................................................... -0.3V to +6.5V

PIC16LF1782/3 ......................................................................................................... -0.3V to +4.0V

on MCLR pin ........................................................................................................................... -0.3V to +9.0V

on all other pins ............................................................................................................ -0.3V to (VDD + 0.3V)

Maximum current

on VSS pin⁽¹⁾

-40°C  TA  +85°C .............................................................................................................. 170 mA

-40°C  TA  +125°C .............................................................................................................. 70 mA

on VDD pin⁽¹⁾

-40°C  TA  +85°C ................................................................................................................ 85 mA

-40°C  TA  +125°C .............................................................................................................. 35 mA

on any I/O pin ..................................................................................................................................... 25 mA

Clamp current, IK (VPIN < 0 or VPIN > VDD) ................................................................................................... 20 mA

Note 1: Maximum current rating requires even load distribution across I/O pins. Maximum current rating may be

limited by the device package power dissipation characterizations, see Section 30.4 “Thermal

Considerations” to calculate device specifications.

† NOTICE: Stresses above those listed under “Absolute Maximum Ratings” may cause permanent damage to the

device. This is a stress rating only and functional operation of the device at those or any other conditions above those

indicated in the operation listings of this specification is not implied. Exposure above maximum rating conditions for

extended periods may affect device reliability.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 355

PIC16(L)F1782/3

30.2 Standard Operating Conditions

The standard operating conditions for any device are defined as:

Operating Voltage:

Operating Temperature:

VDDMIN VDD VDDMAX

TA_MIN TA TA_MAX

VDD — Operating Supply Voltage⁽¹⁾

PIC16LF1782/3

VDDMIN (Fosc  16 MHz).......................................................................................................... +1.8V

VDDMIN (16 MHz < Fosc  32 MHz) ......................................................................................... +2.7V

VDDMAX .................................................................................................................................... +3.6V

PIC16F1782/3

VDDMIN (Fosc  16 MHz).......................................................................................................... +2.3V

VDDMIN (16 MHz < Fosc  32 MHz) ......................................................................................... +2.7V

VDDMAX .................................................................................................................................... +5.5V

TA — Operating Ambient Temperature Range

Industrial Temperature

TA_MIN ...................................................................................................................................... -40°C

TA_MAX .................................................................................................................................... +85°C

Extended Temperature

TA_MIN ...................................................................................................................................... -40°C

TA_MAX .................................................................................................................................. +125°C

Note 1: See Parameter D001, DC Characteristics: Supply Voltage.

DS40001579E-page 356

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 30-1:

PIC16F1782/3 VOLTAGE FREQUENCY GRAPH, -40°C  TA +125°C

5.5

2.7

2.3

0

4

10

16

32

Frequency (MHz)

Note 1: The shaded region indicates the permissible combinations of voltage and frequency.

2: Refer to Table 30-6 for each Oscillator mode’s supported frequencies.

FIGURE 30-2:

PIC16LF1782/3 VOLTAGE FREQUENCY GRAPH, -40°C  TA +125°C

3.6

2.7

1.8

0

4

10

16

32

Frequency (MHz)

Note 1: The shaded region indicates the permissible combinations of voltage and frequency.

2: Refer to Table 30-6 for each Oscillator mode’s supported frequencies.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 357

PIC16(L)F1782/3

30.3

DC Characteristics

TABLE 30-1: SUPPLY VOLTAGE

PIC16LF1782/3

Standard Operating Conditions (unless otherwise stated)

PIC16F1782/3

Param

. No.

Sym.

Characteristic

Min.

Typ†

Max.

Units

Conditions

D001

VDD

Supply Voltage (VDDMIN, VDDMAX)

1.8

2.7

—

3.6

V

FOSC  16 MHz:

FOSC  32 MHz (Note 2)

D001

2.3

2.7

—

5.5

V

FOSC  16 MHz:

FOSC  32 MHz (Note 2)

(1)

D002* VDR

D002*

RAM Data Retention Voltage

1.5

1.7

—

V

Device in Sleep mode

VPOR*

Power-on Reset Release Voltage

Power-on Reset Rearm Voltage

1.6

VPORR*

—

0.8

1.5

—

4

V

Device in Sleep mode

1.024V, VDD  2.5V

2.048V, VDD  2.5V

4.096V, VDD  4.75V

D003

VFVR

Fixed Voltage Reference

Voltage

-4

%

(3)

-4

—

4

-5

—

5

D004* SVDD

VDD Rise Rate to ensure internal

Power-on Reset signal

0.05

—

V/ms See Section 5.1 “Power-On Reset

(POR)” for details.

*

These parameters are characterized but not tested.

†

Data in “Typ” column is at 3.3V, 25°C unless otherwise stated. These parameters are for design guidance only and are

not tested.

Note 1: This is the limit to which VDD can be lowered in Sleep mode without losing RAM data.

2: PLL required for 32 MHz operation.

3: Industrial temperature range only.

DS40001579E-page 358

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 30-3:

POR AND POR REARM WITH SLOW RISING VDD

VDD

VPOR

VPORR

SVDD

VSS

NPOR⁽¹⁾

POR REARM

VSS

(2)

(3)

TPOR

TVLOW

Note 1: When NPOR is low, the device is held in Reset.

2: TPOR 1 s typical.

3: TVLOW 2.7 s typical.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 359

PIC16(L)F1782/3

TABLE 30-2: SUPPLY VOLTAGE (IDD)^(1,2)

PIC16LF1782/3

Standard Operating Conditions (unless otherwise stated)

PIC16F1782/3

Conditions

Note

Param

No.

Device

Characteristics

Min.

Typ†

Max.

Units

VDD

LDO Regulator

D009

—

75

15

—

A

—

High-Power mode, normal operation

Sleep VREGCON<1> = 0

0.3

Sleep VREGCON<1> = 1

D010

—

8

20

24

A

1.8

3.0

FOSC = 32 kHz

LP Oscillator mode (Note 4),

-40°C  TA  +85°C

12

—

18

20

63

74

A

2.3

3.0

5.0

1.8

3.0

2.3

3.0

5.0

FOSC = 32 kHz

LP Oscillator mode (Note 4, 5),

-40°C  TA  +85°C

22

79

D012

160

320

260

330

380

650

1000

700

1100

1300

FOSC = 4 MHz

XT Oscillator mode

FOSC = 4 MHz

XT Oscillator mode (Note 5)

Note 1: The test conditions for all IDD measurements in active operation mode are: OSC1 = external square wave, from

rail-to-rail; all I/O pins tri-stated, pulled to VDD; MCLR = VDD; WDT disabled.

2: The supply current is mainly a function of the operating voltage and frequency. Other factors, such as I/O pin loading

and switching rate, oscillator type, internal code execution pattern and temperature, also have an impact on the current

consumption.

3: For RC oscillator configurations, current through REXT is not included. The current through the resistor can be extended

by the formula IR = VDD/2REXT (mA) with REXT in k

4: FVR and BOR are disabled.

5: 0.1 F capacitor on VCAP.

6: 8 MHz crystal oscillator with 4x PLL enabled.

DS40001579E-page 360

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 30-2: SUPPLY VOLTAGE (IDD)^(1,2)(CONTINUED)

PIC16LF1782/3

Standard Operating Conditions (unless otherwise stated)

PIC16F1782/3

Conditions

Note

Param

No.

Device

Characteristics

Min.

Typ†

Max.

Units

VDD

D014

—

125

280

550

A

1.8

3.0

FOSC = 4 MHz

EC Oscillator mode

Medium-Power mode

1100

D014

—

220

290

350

2.1

2.5

2.1

2.2

130

150

170

220

0.8

1.2

1.0

1.3

1.4

2.1

2.5

2.1

2.2

2.1

2.5

2.1

2.2

650

1000

1200

6.2

A

2.3

3.0

5.0

3.0

3.6

3.0

5.0

1.8

3.0

2.3

3.0

5.0

1.8

3.0

2.3

3.0

5.0

3.0

3.6

3.0

5.0

3.0

3.6

3.0

5.0

FOSC = 4 MHz

EC Oscillator mode (Note 5)

Medium-Power mode

A

D015

D017

mA

A

FOSC = 32 MHz

EC Oscillator High-Power mode

7.5

6.5

FOSC = 32 MHz

EC Oscillator High-Power mode (Note 5)

7.5

180

250

330

430

2.2

FOSC = 500 kHz

MFINTOSC mode

A

FOSC = 500 kHz

MFINTOSC mode (Note 5)

A

D019

mA

FOSC = 16 MHz

HFINTOSC mode

3.7

2.3

FOSC = 16 MHz

HFINTOSC mode (Note 5)

3.9

4.1

D020

D022

6.2

FOSC = 32 MHz

HFINTOSC mode

7.5

6.5

FOSC = 32 MHz

HFINTOSC mode

7.5

6.2

FOSC = 32 MHz

HS Oscillator mode (Note 6)

7.5

6.5

FOSC = 32 MHz

HS Oscillator mode (Note 5, 6)

7.5

Note 1: The test conditions for all IDD measurements in active operation mode are: OSC1 = external square wave, from

rail-to-rail; all I/O pins tri-stated, pulled to VDD; MCLR = VDD; WDT disabled.

2: The supply current is mainly a function of the operating voltage and frequency. Other factors, such as I/O pin loading

and switching rate, oscillator type, internal code execution pattern and temperature, also have an impact on the current

consumption.

3: For RC oscillator configurations, current through REXT is not included. The current through the resistor can be extended

by the formula IR = VDD/2REXT (mA) with REXT in k

4: FVR and BOR are disabled.

5: 0.1 F capacitor on VCAP.

6: 8 MHz crystal oscillator with 4x PLL enabled.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 361

PIC16(L)F1782/3

TABLE 30-3: POWER-DOWN CURRENTS (IPD)^(1,2,4)

Operating Conditions: (unless otherwise stated)

Low-Power Sleep Mode

PIC16LF1782/3

PIC16F1782/3

Param

Low-Power Sleep Mode, VREGPM = 1

Conditions

Note

Max.

+85°C +125°C

Max.

Device Characteristics

Min.

Typ†

Units

No.

VDD

(2)

Power-down Base Current (IPD)

D023

—

0.05

0.08

0.3

0.4

0.5

0.8

0.9

1.0

15

1.0

2.0

3

8.0

9.0

11

12

15

14

17

15

20

22

30

33

35

37

39

28

31

10

14

17

9

A

1.8

3.0

2.3

3.0

5.0

1.8

3.0

2.3

3.0

5.0

1.8

3.0

2.3

3.0

5.0

3.0

5.0

3.0

5.0

1.8

3.0

2.3

3.0

5.0

WDT, BOR, FVR, and T1OSC

disabled, all Peripherals Inactive

D023

WDT, BOR, FVR, and T1OSC

disabled, all Peripherals Inactive

4

6

D024

6

LPWDT Current

7

6

7

8

D025

28

30

33

35

37

25

28

4

FVR Current

18

19

20

D026

7.5

40

BOR Current

87

D027

0.5

0.8

1

LPBOR Current

6

8

D028

0.5

0.8

1.1

1.3

1.4

5

SOSC Current

8.5

6

12

10

20

25

8.5

10

*

These parameters are characterized but not tested.

†

Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are

not tested.

Note 1: The peripheral current is the sum of the base IPD and the additional current consumed when this peripheral is enabled.

The peripheral  current can be determined by subtracting the base IDD or IPD current from this limit. Max values should

be used when calculating total current consumption.

2: The power-down current in Sleep mode does not depend on the oscillator type. Power-down current is measured with

the part in Sleep mode, with all I/O pins in high-impedance state and tied to VSS.

3: ADC oscillator source is FRC.

4: 0.1 F capacitor on VCAP.

5: VREGPM = 0.

DS40001579E-page 362

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 30-3: POWER-DOWN CURRENTS (IPD)^(1,2,4)(CONTINUED)

Operating Conditions: (unless otherwise stated)

Low-Power Sleep Mode

PIC16LF1782/3

PIC16F1782/3

Param

Low-Power Sleep Mode, VREGPM = 1

Conditions

Note

Max.

+85°C +125°C

Max.

Device Characteristics

Min.

Typ†

Units

No.

VDD

(2)

Power-down Base Current (IPD)

D029

—

0.05

0.08

0.3

2

3

9

A

1.8

3.0

2.3

3.0

5.0

1.8

3.0

2.3

3.0

5.0

3.0

5.0

1.8

3.0

2.3

3.0

5.0

ADC Current (Note 3),

no conversion in progress

10

12

13

16

—

D029

4

ADC Current (Note 3),

no conversion in progress

0.4

5

0.5

7

D030

250

280

230

250

350

250

350

250

300

280

300

310

—

ADC Current (Note 3),

conversion in progress

—

ADC Current (Note 3, Note 4,

Note 5), conversion in progress

—

D031

650

700

650

700

Op Amp (High power)

Op Amp (High power) (Note 5)

—

D032

Comparator, Normal-Power mode

(Note 5)

*

These parameters are characterized but not tested.

†

Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are

not tested.

Note 1: The peripheral current is the sum of the base IPD and the additional current consumed when this peripheral is enabled.

The peripheral  current can be determined by subtracting the base IDD or IPD current from this limit. Max values should

be used when calculating total current consumption.

2: The power-down current in Sleep mode does not depend on the oscillator type. Power-down current is measured with

the part in Sleep mode, with all I/O pins in high-impedance state and tied to VSS.

3: ADC oscillator source is FRC.

4: 0.1 F capacitor on VCAP.

5: VREGPM = 0.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 363

PIC16(L)F1782/3

TABLE 30-4: I/O PORTS

Standard Operating Conditions (unless otherwise stated)

Param

No.

Sym.

Characteristic

Min.

Typ†

Max.

Units

Conditions

VIL

Input Low Voltage

I/O PORT:

D034

D034A

D035

with TTL buffer

—

0.8

V

4.5V  VDD  5.5V

0.15 VDD

0.2 VDD

0.3 VDD

0.8

1.8V  VDD  4.5V

2.0V  VDD  5.5V

with Schmitt Trigger buffer

with I²C™ levels

with SMBus levels

MCLR, OSC1 (RC mode)⁽¹⁾

OSC1 (HS mode)

Input High Voltage

I/O ports:

2.7V  VDD  5.5V

D036

0.2 VDD

0.3 VDD

D036A

VIH

D040

with TTL buffer

2.0

—

V

4.5V  VDD 5.5V

1.8V  VDD  4.5V

D040A

0.25 VDD +

0.8

D041

with Schmitt Trigger buffer

with I²C™ levels

with SMBus levels

MCLR

0.8 VDD

0.7 VDD

2.1

—

V

2.0V  VDD  5.5V

2.7V  VDD  5.5V

D042

0.8 VDD

0.7 VDD

0.9 VDD

D043A

D043B

OSC1 (HS mode)

OSC1 (RC mode)

(Note 1)

(2)

IIL

Input Leakage Current

D060

I/O ports

—

± 5

± 125

nA

VSS  VPIN  VDD, Pin at

high-impedance @ 85°C

± 5

± 1000

± 200

nA 125°C

D061

MCLR⁽³⁾

± 50

nA

A

V

VSS  VPIN  VDD @ 85°C

IPUR

VOL

Weak Pull-up Current

D070*

25

100

140

200

300

VDD = 3.3V, VPIN = VSS

VDD = 5.0V, VPIN = VSS

(4)

Output Low Voltage

D080

I/O ports

IOL = 8mA, VDD = 5V

IOL = 6mA, VDD = 3.3V

IOL = 1.8mA, VDD = 1.8V

—

0.6

—

(4)

VOH

Output High Voltage

D090

I/O ports

IOH = 3.5mA, VDD = 5V

IOH = 3mA, VDD = 3.3V

IOH = 1mA, VDD = 1.8V

VDD - 0.7

V

*

These parameters are characterized but not tested.

†

Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are

not tested.

Note 1: In RC oscillator configuration, the OSC1/CLKIN pin is a Schmitt Trigger input. It is not recommended to use an external

clock in RC mode.

2: Negative current is defined as current sourced by the pin.

3: The leakage current on the MCLR pin is strongly dependent on the applied voltage level. The specified levels represent

normal operating conditions. Higher leakage current may be measured at different input voltages.

4: Including OSC2 in CLKOUT mode.

DS40001579E-page 364

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 30-4: I/O PORTS (CONTINUED)

Standard Operating Conditions (unless otherwise stated)

Param

No.

Sym.

Characteristic

Min.

Typ†

—

Max.

15

Units

pF

Conditions

Capacitive Loading Specs on Output Pins

D101*

COSC2 OSC2 pin

—

In XT, HS and LP modes when

external clock is used to drive

OSC1

D101A* CIO

All I/O pins

—

50

pF

VCAP Capacitor Charging

Charging current

D102

—

200

0.0

—

A

mA

D102A

Source/sink capability when

charging complete

*

These parameters are characterized but not tested.

†

Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are

not tested.

Note 1: In RC oscillator configuration, the OSC1/CLKIN pin is a Schmitt Trigger input. It is not recommended to use an external

clock in RC mode.

2: Negative current is defined as current sourced by the pin.

3: The leakage current on the MCLR pin is strongly dependent on the applied voltage level. The specified levels represent

normal operating conditions. Higher leakage current may be measured at different input voltages.

4: Including OSC2 in CLKOUT mode.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 365

PIC16(L)F1782/3

TABLE 30-5: MEMORY PROGRAMMING REQUIREMENTS

Standard Operating Conditions (unless otherwise stated)

Param

Sym.

Characteristic

Min.

Typ†

Max.

Units

Conditions

No.

Program Memory

Programming Specifications

D110

D111

VIHH

IDDP

Voltage on MCLR/VPP/RE3 pin

8.0

—

9.0

10

V

(Note 3)

Supply Current during

Programming

mA

VDD for Bulk Erase

2.7

—

VDDMAX

V

D112

D113

VPEW

VDD for Write or Row Erase

VDDMIN

IPPPGM Current on MCLR/VPP during

Erase/Write

—

1.0

mA

D114

D115

IDDPGM Current on VDD during Erase/Write

—

5.0

mA

Data EEPROM Memory

—

D116

D117

D118

D119

ED

Byte Endurance

100K

VDDMIN

—

VDDMAX

5.0

E/W -40C to +85C

VDRW VDD for Read/Write

V

TDEW Erase/Write Cycle Time

TRETD Characteristic Retention

4.0

40

ms

—

Year Provided no other

specifications are violated

D120

TREF

Number of Total Erase/Write

Cycles before Refresh

100k

—

E/W -40°C to +85°C

(2)

Program Flash Memory

Cell Endurance

—

2

D121

D122

D123

D124

EP

10K

VDDMIN

—

VDDMAX

2.5

E/W -40C to +85C (Note 1)

VPR

TIW

VDD for Read

V

Self-timed Write Cycle Time

ms

TRETD Characteristic Retention

—

40

—

Year Provided no other

specifications are violated

†

Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance

only and are not tested.

Note 1: Self-write and Block Erase.

2: Refer to Section 12.2 “Using the Data EEPROM” for a more detailed discussion on data EEPROM

endurance.

3: Required only if single-supply programming is disabled.

DS40001579E-page 366

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

30.4 Thermal Considerations

Standard Operating Conditions (unless otherwise stated)

Param

No.

Sym.

Characteristic

Typ.

Units

Conditions

28-pin SPDIP package

TH01

JA

Thermal Resistance Junction to Ambient

60

80

C/W

C

28-pin SOIC package

90

28-pin SSOP package

27.5

31.4

24

28-pin UQFN 4x4mm package

28-pin QFN 6x6mm package

28-pin SPDIP package

TH02

JC

Thermal Resistance Junction to Case

28-pin SOIC package

24

28-pin SSOP package

24

28-pin UQFN 4x4mm package

28-pin QFN 6x6mm package

24

TH03

TH04

TH05

TH06

TH07

TJMAX

PD

Maximum Junction Temperature

Power Dissipation

150

—

W

PD = PINTERNAL + PI/O

(1)

PINTERNAL Internal Power Dissipation

—

W

PINTERNAL = IDD x VDD

PI/O

I/O Power Dissipation

Derated Power

—

W

PI/O =  (IOL * VOL) +  (IOH * (VDD - VOH))

(2)

PDER

—

W

PDER = PDMAX (TJ - TA)/JA

Note 1: IDD is current to run the chip alone without driving any load on the output pins.

2: TA = Ambient Temperature

3: TJ = Junction Temperature

 2011-2014 Microchip Technology Inc.

DS40001579E-page 367

PIC16(L)F1782/3

30.5 AC Characteristics

Timing Parameter Symbology has been created with one of the following formats:

1. TppS2ppS

2. TppS

T

F

Frequency

Lowercase letters (pp) and their meanings:

pp

cc

T

Time

CCP1

CLKOUT

CS

osc

rd

OSC1

RD

ck

cs

di

rw

sc

ss

t0

RD or WR

SCK

SDI

do

dt

SDO

SS

Data in

I/O PORT

MCLR

T0CKI

T1CKI

WR

io

t1

mc

wr

Uppercase letters and their meanings:

S

F

H

I

Fall

P

R

V

Z

Period

High

Rise

Invalid (High-impedance)

Low

Valid

L

High-impedance

FIGURE 30-4:

LOAD CONDITIONS

Rev. 10-000133A

8/1/2013

Load Condition

CL

VSS

Legend: CL=50 pF for all pins

DS40001579E-page 368

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 30-5:

CLOCK TIMING

Q4

Q1

Q2

Q3

Q4

Q1

OSC1/CLKIN

OS02

OS04

OS03

OSC2/CLKOUT

(LP,XT,HS Modes)

OSC2/CLKOUT

(CLKOUT Mode)

TABLE 30-6: CLOCK OSCILLATOR TIMING REQUIREMENTS

Standard Operating Conditions (unless otherwise stated)

Param

Sym.

Characteristic

Min.

Typ†

Max.

Units

Conditions

No.

OS01

FOSC

External CLKIN Frequency⁽¹⁾

DC

—

0.5

4

MHz EC Oscillator mode (low)

MHz EC Oscillator mode (medium)

MHz EC Oscillator mode (high)

—

20

—

4

Oscillator Frequency⁽¹⁾

32.768

—

kHz

LP Oscillator mode

0.1

1

MHz XT Oscillator mode

—

4

MHz HS Oscillator mode

1

—

20

4

MHz HS Oscillator mode, VDD > 2.7V

MHz RC Oscillator mode, VDD > 2.0V

DC

27

250

50

—

OS02

TOSC

External CLKIN Period⁽¹⁾

Oscillator Period⁽¹⁾

—



s

ns

s

ns

s

ns

LP Oscillator mode

XT Oscillator mode

HS Oscillator mode

EC Oscillator mode

LP Oscillator mode

XT Oscillator mode

HS Oscillator mode

RC Oscillator mode

TCY = 4/FOSC

—



—



—



30.5

—

10,000

1,000

—

DC

—



250

50

250

200

2

—

OS03

TCY

Instruction Cycle Time⁽¹⁾

TCY

—

OS04*

TosH,

TosL

External CLKIN High,

External CLKIN Low

LP oscillator

100

20

0

—

XT oscillator

—

HS oscillator

OS05*

TosR,

TosF

External CLKIN Rise,

External CLKIN Fall

—

LP oscillator

0

—



XT oscillator

0

—



HS oscillator

*

These parameters are characterized but not tested.

†

Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are not

tested.

Note 1: Instruction cycle period (TCY) equals four times the input oscillator time base period. All specified values are based on

characterization data for that particular oscillator type under standard operating conditions with the device executing code.

Exceeding these specified limits may result in an unstable oscillator operation and/or higher than expected current

consumption. All devices are tested to operate at “min” values with an external clock applied to OSC1 pin. When an

external clock input is used, the “max” cycle time limit is “DC” (no clock) for all devices.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 369

PIC16(L)F1782/3

TABLE 30-7: OSCILLATOR PARAMETERS

Standard Operating Conditions (unless otherwise stated)

Param

No.

Freq.

Tolerance

Sym.

Characteristic

Min. Typ† Max. Units

Conditions

OS08

HFOSC

Internal Calibrated HFINTOSC

Frequency⁽²⁾

±2%

±3%

—

16.0

—

MHz 0°C  TA  +60°C, VDD 2.5V

MHz 60°C TA 85°C, VDD 2.5V

±5%

—

16.0

—

MHz -40°C  TA  +125°C

OS08A MFOSC Internal Calibrated MFINTOSC

Frequency⁽²⁾

±2%

±3%

—

500

—

kHz 0°C  TA  +60°C, VDD 2.5V

kHz 60°C TA 85°C, VDD 2.5V

±5%

—

500

31

—

8

kHz -40°C  TA  +125°C

OS09

OS10* TIOSC ST HFINTOSC

Wake-up from Sleep Start-up Time

LFOSC

Internal LFINTOSC Frequency

—

3.2

s

VREGPM = 0

MFINTOSC

Wake-up from Sleep Start-up Time

—

24

35

s

VREGPM = 0

*

These parameters are characterized but not tested.

†

Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are not

tested.

Note 1: Instruction cycle period (TCY) equals four times the input oscillator time base period. All specified values are based on

characterization data for that particular oscillator type under standard operating conditions with the device executing code.

Exceeding these specified limits may result in an unstable oscillator operation and/or higher than expected current

consumption. All devices are tested to operate at “min” values with an external clock applied to the OSC1 pin. When an

external clock input is used, the “max” cycle time limit is “DC” (no clock) for all devices.

2: To ensure these oscillator frequency tolerances, VDD and VSS must be capacitively decoupled as close to the device as

possible. 0.1 F and 0.01 F values in parallel are recommended.

3: By design.

FIGURE 30-6:

HFINTOSC FREQUENCY ACCURACY OVER DEVICE VDD AND TEMPERATURE

± 5%

125

85

60

25

± 3%

± 2%

0

-20

± 5%

-40

1.8

2.0

2.5

3.5

4.0

VDD (V)

4.5

5.0

5.5

3.0

DS40001579E-page 370

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 30-8: PLL CLOCK TIMING SPECIFICATIONS

Standard Operating Conditions (unless otherwise stated)

Param

No.

Sym.

Characteristic

Min.

Typ†

Max.

Units Conditions

F10

FOSC Oscillator Frequency Range

4

16

—

8

32

MHz

ms

F11

FSYS On-Chip VCO System Frequency

F12

F13*

TRC

PLL Start-up Time (Lock Time)

—

2

CLK CLKOUT Stability (Jitter)

-0.25%

+0.25%

%

*

These parameters are characterized but not tested.

†

Data in “Typ” column is at 5V, 25C unless otherwise stated. These parameters are for design guidance

only and are not tested.

FIGURE 30-7:

CLKOUT AND I/O TIMING

Cycle

Write

Q4

Fetch

Q1

Read

Q2

Execute

Q3

FOSC

OS12

OS11

OS20

OS21

CLKOUT

OS19

OS13

OS18

OS16

OS17

I/O pin

(Input)

OS14

OS15

I/O pin

(Output)

New Value

Old Value

OS18, OS19

 2011-2014 Microchip Technology Inc.

DS40001579E-page 371

PIC16(L)F1782/3

TABLE 30-9: CLKOUT AND I/O TIMING PARAMETERS

Standard Operating Conditions (unless otherwise stated)

Param

No.

Sym.

Characteristic

Min.

Typ† Max. Units

Conditions

OS11 TosH2ckL FOSC to CLKOUT ⁽¹⁾

OS12 TosH2ckH FOSC to CLKOUT ⁽¹⁾

OS13 TckL2ioV CLKOUT to Port out valid⁽¹⁾

—

70

72

20

ns VDD = 3.3-5.0V

ns

OS14 TioV2ckH Port input valid before CLKOUT⁽¹⁾

OS15 TosH2ioV Fosc (Q1 cycle) to Port out valid

TOSC + 200 ns

—

50

—

70*

—

ns

—

ns VDD = 3.3-5.0V

OS16 TosH2ioI

Fosc (Q2 cycle) to Port input invalid

50

(I/O in hold time)

OS17 TioV2osH Port input valid to Fosc(Q2 cycle)

20

—

ns

(I/O in setup time)

OS18* TioR

OS19* TioF

Port output rise time

—

40

15

72

32

ns

VDD = 1.8V

VDD = 3.3-5.0V

Port output fall time

—

28

15

55

30

VDD = 1.8V

VDD = 3.3-5.0V

OS20* Tinp

OS21* Tioc

INT pin input high or low time

25

—

ns

Interrupt-on-change new input level

time

*

†

These parameters are characterized but not tested.

Data in “Typ” column is at 3.0V, 25C unless otherwise stated.

Note 1: Measurements are taken in RC mode where CLKOUT output is 4 x TOSC.

DS40001579E-page 372

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 30-8:

RESET, WATCHDOG TIMER, OSCILLATOR START-UP TIMER AND POWER-UP

TIMER TIMING

VDD

MCLR

30

Internal

POR

33

PWRT

Time-out

32

OSC

Start-up Time

Internal Reset(1)

Watchdog Timer

Reset(1)

31

34

I/O pins

Note 1: Asserted low.

FIGURE 30-9:

BROWN-OUT RESET TIMING AND CHARACTERISTICS

VDD

VBOR and VHYST

VBOR

(Device in Brown-out Reset)

(Device not in Brown-out Reset)

37

TPWRT

Reset

33⁽¹⁾

(due to BOR)

Note 1: The delay, (TPWRT) releasing Reset, only occurs when the Power-up Timer is enabled, (PWRTE = 0).

 2011-2014 Microchip Technology Inc.

DS40001579E-page 373

PIC16(L)F1782/3

TABLE 30-10: RESET, WATCHDOG TIMER, OSCILLATOR START-UP TIMER, POWER-UP TIMER

AND BROWN-OUT RESET PARAMETERS

Standard Operating Conditions (unless otherwise stated)

Param

Sym.

TMCL

Characteristic

Min. Typ† Max. Units

Conditions

No.

30

MCLR Pulse Width (low)

2

5

—

s VDD = 3.3-5V, -40°C to +85°C

s VDD = 3.3-5V

31

TWDTLP Low-Power Watchdog Timer

Time-out Period

10

16

27

ms VDD = 3.3V-5V

1:16 Prescaler used

32

TOST

Oscillator Start-up Timer Period^{(1), (2)}

—

1024

65

—

140

2.0

Tosc (Note 3)

33*

34*

TPWRT Power-up Timer Period, PWRTE = 0 40

ms

TIOZ

I/O high-impedance from MCLR Low

or Watchdog Timer Reset

—

s

35

VBOR

Brown-out Reset Voltage

2.55 2.70 2.85

2.30 2.45 2.6

1.80 1.90 2.10

V

BORV = 0

BORV=1 (F device)

BORV=1 (LF device)

35A

36*

37*

VLPBOR Low-Power Brown-out

Brown-out Reset Hysteresis

1.8

0

2.1

25

3

2.5

75

5

V

LPBOR = 1

VHYST

mV -40°C to +85°C

TBORDC Brown-out Reset DC Response

Time

1

s VDD  VBOR

*

These parameters are characterized but not tested.

†

Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance

only and are not tested.

Note 1: Instruction cycle period (TCY) equals four times the input oscillator time base period. All specified values are

based on characterization data for that particular oscillator type under standard operating conditions with the

device executing code. Exceeding these specified limits may result in an unstable oscillator operation and/or

higher than expected current consumption. All devices are tested to operate at “min” values with an external

clock applied to the OSC1 pin. When an external clock input is used, the “max” cycle time limit is “DC” (no

clock) for all devices.

2: By design.

3: Period of the slower clock.

4: To ensure these voltage tolerances, VDD and VSS must be capacitively decoupled as close to the device as

possible. 0.1 F and 0.01 F values in parallel are recommended.

DS40001579E-page 374

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 30-10:

TIMER0 AND TIMER1 EXTERNAL CLOCK TIMINGS

T0CKI

40

41

42

T1CKI

45

46

49

47

TMR0 or

TMR1

TABLE 30-11: TIMER0 AND TIMER1 EXTERNAL CLOCK REQUIREMENTS

Standard Operating Conditions (unless otherwise stated)

Param

Sym.

TT0H

Characteristic

Min.

Typ†

Max.

Units

Conditions

No.

40*

T0CKI High Pulse Width

No Prescaler

With Prescaler

No Prescaler

With Prescaler

0.5 TCY + 20

—

ns

10

0.5 TCY + 20

10

41*

42*

TT0L

TT0P

T0CKI Low Pulse Width

T0CKI Period

Greater of:

20 or TCY + 40

N

ns N = prescale value

(2, 4, ..., 256)

45*

TT1H

T1CKI High Synchronous, No Prescaler

0.5 TCY + 20

15

—

ns

Time

Synchronous,

with Prescaler

Asynchronous

30

—

ns

46*

47*

TT1L

TT1P

T1CKI Low Synchronous, No Prescaler

0.5 TCY + 20

Time

Synchronous, with Prescaler

Asynchronous

15

30

T1CKI Input Synchronous

Period

Greater of:

30 or TCY + 40

N

ns N = prescale value

(1, 2, 4, 8)

Asynchronous

60

—

ns

48

FT1

Timer1 Oscillator Input Frequency Range

(oscillator enabled by setting bit T1OSCEN)

32.4

32.768 33.1

kHz

49*

TCKEZTMR1 Delay from External Clock Edge to Timer

Increment

2 TOSC

—

7 TOSC

—

Timers in Sync

mode

*

These parameters are characterized but not tested.

†

Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are not

tested.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 375

PIC16(L)F1782/3

FIGURE 30-11:

CAPTURE/COMPARE/PWM TIMINGS (CCP)

CCPx

(Capture mode)

CC01

CC02

CC03

Note: Refer to Figure 30-5 for load conditions.

TABLE 30-12: CAPTURE/COMPARE/PWM REQUIREMENTS (CCP)

Standard Operating Conditions (unless otherwise stated)

Param

No.

Sym.

Characteristic

Min.

Typ† Max. Units

Conditions

CC01* TccL CCPx Input Low Time

CC02* TccH CCPx Input High Time

CC03* TccP CCPx Input Period

No Prescaler

With Prescaler

No Prescaler

With Prescaler

0.5TCY + 20

—

ns

20

0.5TCY + 20

20

3TCY + 40

N

ns N = prescale value (1, 4 or 16)

*

These parameters are characterized but not tested.

†

Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are not

tested.

DS40001579E-page 376

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 30-13: ADC CONVERTER (ADC) 12-BIT DIFFERENTIAL CHARACTERISTICS:

Operating Conditions

VDD = 3V, Temp. = 25°C, Single-ended 2 s TAD, VREF+ = 3V, VREF- = VSS

Param

No.

Sym.

Characteristic

Min.

Typ†

Max. Units

Conditions

AD01 NR

AD02 EIL

AD03 EDL

Resolution

—

1.8

—

±1

—

10

±1.6

±1.4

±3.5

±2

bit

Integral Error

LSb

Differential Error

LSb No missing codes

AD04 EOFF Offset Error

LSb

AD05 EGN Gain Error

AD06 VREF Reference Voltage⁽³⁾

VDD

VREF

10

V

VREF = (VREF+ minus VREF-) (Note 5)

AD07 VAIN Full-Scale Range

AD08 ZAIN Recommended Impedance of

Analog Voltage Source

Can go higher if external 0.01F capacitor is

present on input pin.

k

AD09 NR

AD10 EIL

AD11 EDL

Resolution

—

1.8

—

±2

±1

—

12

—

bit

LSb

V

Integral Error

Differential Error

—

AD12 EOFF Offset Error

—

AD13 EGN Gain Error

AD14 VREF Reference Voltage⁽³⁾

—

VDD

VREF

10

VREF = (VREF+ minus VREF-) (Note 5)

AD15 VAIN Full-Scale Range

V

AD16 ZAIN Recommended Impedance of

Analog Voltage Source

Can go higher if external 0.01F capacitor is

present on input pin.

k

*

These parameters are characterized but not tested.

†

Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are not

tested.

Note 1: Total Absolute Error includes integral, differential, offset and gain errors.

2: The ADC conversion result never decreases with an increase in the input voltage and has no missing codes.

3: ADC VREF is from external VREF, VDD pin or FVR, whichever is selected as reference input.

4: When ADC is off, it will not consume any current other than leakage current. The power-down current specification

includes any such leakage from the ADC module.

5: FVR voltage selected must be 2.048V or 4.096V.

TABLE 30-14: ADC CONVERSION REQUIREMENTS

Standard Operating Conditions (unless otherwise stated)

Param

No.

Sym.

Characteristic

ADC Clock Period

Min.

Typ†

Max. Units

Conditions

AD130* TAD

1.0

—

9.0

6.0

s

TOSC-based

ADCS<1:0> = 11(ADRC mode)

ADC Internal RC Oscillator

Period

2.5

AD131 TCNV Conversion Time (not including

Acquisition Time)⁽¹⁾

—

15 (12-bit)

13 (10-bit)

—

TAD Set GO/DONE bit to conversion

complete

AD132* TACQ Acquisition Time

—

5.0

s

*

These parameters are characterized but not tested.

†

Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance only and are not

tested.

Note 1: The ADRES register may be read on the following TCY cycle.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 377

PIC16(L)F1782/3

FIGURE 30-12:

ADC CONVERSION TIMING (NORMAL MODE)

BSF ADCON0, GO

1 Tcy

AD134

Q4

(TOSC/2⁽¹⁾

)

AD131

AD130

ADC CLK

7

6

5

4

3

2

1

0

ADC Data

ADRES

NEW_DATA

1 Tcy

OLD_DATA

ADIF

GO

DONE

Sampling Stopped

AD132

Sample

Note 1: If the ADC clock source is selected as RC, a time of TCY is added before the ADC clock starts. This

allows the SLEEPinstruction to be executed.

FIGURE 30-13:

ADC CONVERSION TIMING (SLEEP MODE)

BSF ADCON0, GO

AD134

Q4

(1)

(TOSC/2 + TCY

1 Tcy

)

AD131

AD130

ADC CLK

ADC Data

7

6

5

3

2

1

0

4

NEW_DATA

1 Tcy

OLD_DATA

ADRES

ADIF

GO

DONE

Sampling Stopped

AD132

Sample

Note 1: If the ADC clock source is selected as RC, a time of TCY is added before the ADC clock starts. This

allows the SLEEPinstruction to be executed.

DS40001579E-page 378

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 30-15: OPERATIONAL AMPLIFIER (OPA)

Standard Operating Conditions (unless otherwise stated):

VDD = 3.0 Temperature 25°C, High-Power Mode

DC CHARACTERISTICS

Param.

Symbol

No.

Parameters

Min.

Typ.

Max.

Units

Conditions

OPA01* GBWP Gain Bandwidth Product

—

55

—

0

2

—

MHz

s

High-Power mode

OPA02*

OPA03*

OPA04*

OPA05

OPA06

OPA07*

OPA08

TON

PM

Turn on Time

Phase Margin

Slew Rate

Offset

10

40

3

—

degrees

V/s

mV

SR

—

OFF

±3

70

90

—

80

±9

—

CMRR Common Mode Rejection Ratio

dB

AOL

Open Loop Gain

—

dB

VICM

Input Common Mode Voltage

VDD

—

V

VDD > 2.5

OPA09* PSRR Power Supply Rejection Ratio

—

dB

TABLE 30-16: COMPARATOR SPECIFICATIONS

Operating Conditions: VDD = 3.0V, Temperature = 25°C (unless otherwise stated).

Param.

Sym.

Characteristics

Min.

Typ.

Max. Units

Comments

No.

CM01

VIOFF

Input Offset Voltage

—

±2.5

±9

mV Normal-Power mode

VICM = VDD/2

CM02

CM03

CM04A

VICM

Input Common Mode Voltage

Common Mode Rejection Ratio

Response Time Rising Edge

0

—

50

60

VDD

—

V

CMRR

40

—

dB

125

ns Normal-Power mode

measured at VDD/2 (Note 1)

CM04B

CM04C

CM04D

CM05

Response Time Falling Edge

Response Time Rising Edge

Response Time Falling Edge

—

20

60

85

—

45

110

—

ns Normal-Power mode

measured at VDD/2 (Note 1)

TRESP

ns Low-Power mode measured

at VDD/2 (Note 1)

—

ns Low-Power mode measured

at VDD/2 (Note 1)

Tmc2ov Comparator Mode Change to

Output Valid*

10

75

s

CM06

CHYSTER Comparator Hysteresis

mV Hystersis ON, High Power

measured at VDD/2 (Note 2)

*

These parameters are characterized but not tested.

Note 1: Response time measured with one comparator input at VDD/2, while the other input transitions

from VSS to VDD.

2: Comparator Hysteresis is available when the CxHYS bit of the CMxCON0 register is enabled.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 379

PIC16(L)F1782/3

TABLE 30-17: DIGITAL-TO-ANALOG CONVERTER (DAC) SPECIFICATIONS

Operating Conditions: VDD = 3V, Temperature = 25°C (unless otherwise stated).

Param.

No.

Sym.

Characteristics

Step Size

Min.

Typ.

Max.

Units

Comments

DAC01*

DAC02*

DAC03*

DAC04*

*

CLSB

—

VDD/256

—

 1.5

—

V

LSb



CACC

CR

Absolute Accuracy

Unit Resistor Value (R)

Settling Time⁽¹⁾

600

CST

—

10

s

These parameters are characterized but not tested.

Note 1: Settling time measured while DACR<7:0> transitions from ‘0x00’ to ‘0xFF’.

FIGURE 30-14:

EUSART SYNCHRONOUS TRANSMISSION (MASTER/SLAVE) TIMING

CK

DT

US121

US122

US120

Refer to Figure 30-4 for load conditions.

Note:

TABLE 30-18: EUSART SYNCHRONOUS TRANSMISSION REQUIREMENTS

Standard Operating Conditions (unless otherwise stated)

Param.

No.

Symbol

Characteristic

Min.

Max.

Units Conditions

US120 TCKH2DTV SYNC XMIT (Master and Slave)

Clock high to data-out valid

3.0-5.5V

1.8-5.5V

3.0-5.5V

1.8-5.5V

3.0-5.5V

1.8-5.5V

—

80

100

45

ns

US121 TCKRF

Clock out rise time and fall time

(Master mode)

50

US122 TDTRF

Data-out rise time and fall time

45

50

FIGURE 30-15:

EUSART SYNCHRONOUS RECEIVE (MASTER/SLAVE) TIMING

CK

DT

US125

US126

Note: Refer to Figure 30-4 for load conditions.

DS40001579E-page 380

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 30-19: EUSART SYNCHRONOUS RECEIVE REQUIREMENTS

Standard Operating Conditions (unless otherwise stated)

Param.

No.

Symbol

Characteristic

Min.

Max. Units

Conditions

US125 TDTV2CKL SYNC RCV (Master and Slave)

Data-hold before CK  (DT hold time)

10

15

—

ns

US126 TCKL2DTL Data-hold after CK  (DT hold time)

 2011-2014 Microchip Technology Inc.

DS40001579E-page 381

PIC16(L)F1782/3

FIGURE 30-16:

SPI MASTER MODE TIMING (CKE = 0, SMP = 0)

SS

SP70

SCK

(CKP = 0)

SP71

SP72

SP78

SP79

SCK

(CKP = 1)

SP78

LSb

SP80

MSb

bit 6 - - - - - -1

SDO

SDI

SP75, SP76

bit 6 - - - -1

MSb In

LSb In

SP74

SP73

Note: Refer to Figure 30-4 for load conditions.

FIGURE 30-17:

SPI MASTER MODE TIMING (CKE = 1, SMP = 1)

SS

SP81

SCK

(CKP = 0)

SP71

SP73

SP72

SP79

SCK

(CKP = 1)

SP80

SP78

LSb

MSb

bit 6 - - - - - -1

SDO

SDI

SP75, SP76

bit 6 - - - -1

MSb In

SP74

Note: Refer to Figure 30-4 for load conditions.

LSb In

DS40001579E-page 382

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

FIGURE 30-18:

SPI SLAVE MODE TIMING (CKE = 0)

SS

SP70

SCK

(CKP = 0)

SP83

SP79

SP71

SP72

SP78

SP79

SCK

(CKP = 1)

SP78

LSb

SP80

MSb

SDO

SDI

bit 6 - - - - - -1

SP75, SP76

bit 6 - - - -1

SP77

MSb In

SP74

SP73

LSb In

Note: Refer to Figure 30-4 for load conditions.

FIGURE 30-19:

SPI SLAVE MODE TIMING (CKE = 1)

SP82

SP70

SS

SP83

SCK

(CKP = 0)

SP72

SP71

SCK

(CKP = 1)

SP80

MSb

bit 6 - - - - - -1

LSb

SDO

SDI

SP77

SP75, SP76

bit 6 - - - -1

MSb In

SP74

LSb In

Note: Refer to Figure 30-4 for load conditions.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 383

PIC16(L)F1782/3

TABLE 30-20: SPI MODE REQUIREMENTS

Standard Operating Conditions (unless otherwise stated)

Param

No.

Symbol

Characteristic

Min.

Typ† Max. Units Conditions

SP70* TSSL2SCH, SS to SCK or SCK input

2.25*TCY

—

ns

TSSL2SCL

SP71* TSCH

SP72* TSCL

SCK input high time (Slave mode)

SCK input low time (Slave mode)

TCY + 20

100

—

ns

SP73* TDIV2SCH, Setup time of SDI data input to SCK edge

TDIV2SCL

SP74* TSCH2DIL, Hold time of SDI data input to SCK edge

TSCL2DIL

100

—

ns

SP75* TDOR

SDO data output rise time

3.0-5.5V

1.8-5.5V

—

10

—

Tcy

10

25

10

—

10

25

10

—

25

50

25

50

25

50

25

50

145

—

ns

SP76* TDOF

SDO data output fall time

SP77* TSSH2DOZ SS to SDO output high-impedance

SP78* TSCR

SCK output rise time

(Master mode)

3.0-5.5V

1.8-5.5V

SP79* TSCF

SCK output fall time (Master mode)

SP80* TSCH2DOV, SDO data output valid after

TSCL2DOV SCK edge

3.0-5.5V

1.8-5.5V

SP81* TDOV2SCH, SDO data output setup to SCK edge

TDOV2SCL

SP82* TSSL2DOV SDO data output valid after SS edge

—

50

—

ns

SP83* TSCH2SSH, SS after SCK edge

1.5TCY + 40

TSCL2SSH

*

These parameters are characterized but not tested.

†

Data in “Typ” column is at 3.0V, 25°C unless otherwise stated. These parameters are for design guidance

only and are not tested.

FIGURE 30-20:

I²C™ BUS START/STOP BITS TIMING

SCL

SP93

SP91

SP90

SP92

SDA

Stop

Condition

Start

Condition

Note: Refer to Figure 30-4 for load conditions.

DS40001579E-page 384

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

TABLE 30-21: I²C™ BUS START/STOP BITS REQUIREMENTS

Standard Operating Conditions (unless otherwise stated)

Param

No.

Symbol

Characteristic

Min. Typ Max. Units

Conditions

SP90* TSU:STA Start condition

Setup time

100 kHz mode

400 kHz mode

100 kHz mode

400 kHz mode

100 kHz mode

400 kHz mode

100 kHz mode

400 kHz mode

4700

600

—

ns Only relevant for Repeated

Start condition

SP91* THD:STA Start condition

Hold time

4000

600

ns After this period, the first

clock pulse is generated

SP92* TSU:STO Stop condition

Setup time

4700

600

ns

SP93 THD:STO Stop condition

Hold time

4000

600

ns

*

These parameters are characterized but not tested.

FIGURE 30-21:

I²C™ BUS DATA TIMING

SP100

SP103

SP102

SP101

SCL

SP90

SP106

SP107

SP92

SP91

SDA

In

SP110

SP109

SDA

Out

Note: Refer to Figure 30-4 for load conditions.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 385

PIC16(L)F1782/3

TABLE 30-22: I²C™ BUS DATA REQUIREMENTS

Standard Operating Conditions (unless otherwise stated)

Param.

No.

Symbol

Characteristic

Min.

Max. Units

Conditions

SP100* THIGH

SP101* TLOW

Clock high time

Clock low time

100 kHz mode

4.0

—

s

Device must operate at a

minimum of 1.5 MHz

400 kHz mode

0.6

Device must operate at a

minimum of 10 MHz

SSP module

1.5TCY

4.7

—

100 kHz mode

s

Device must operate at a

minimum of 1.5 MHz

400 kHz mode

SSP module

1.3

—

Device must operate at a

minimum of 10 MHz

1.5TCY

—

SP102* TR

SP103* TF

SDA and SCL rise 100 kHz mode

time

1000

ns

400 kHz mode

20 + 0.1CB 300

CB is specified to be from

10-400 pF

SDA and SCL fall

time

100 kHz mode

400 kHz mode

—

250

ns

20 + 0.1CB 250

CB is specified to be from

10-400 pF

SP106* THD:DAT Data input hold time 100 kHz mode

400 kHz mode

0

—

0.9

—

ns

s

ns

s

0

SP107* TSU:DAT Data input setup

time

100 kHz mode

400 kHz mode

100 kHz mode

400 kHz mode

100 kHz mode

400 kHz mode

250

100

—

(Note 2)

(Note 1)

—

SP109* TAA

Output valid from

clock

3500

—

SP110* TBUF

Bus free time

4.7

1.3

—

Time the bus must be free

before a new transmission

can start

—

SP111 CB

Bus capacitive loading

—

400

pF

*

These parameters are characterized but not tested.

Note 1: As a transmitter, the device must provide this internal minimum delay time to bridge the undefined region

(min. 300 ns) of the falling edge of SCL to avoid unintended generation of Start or Stop conditions.

2: A Fast mode (400 kHz) I²C™ bus device can be used in a Standard mode (100 kHz) I²C bus system, but

the requirement TSU:DAT 250 ns must then be met. This will automatically be the case if the device does

not stretch the low period of the SCL signal. If such a device does stretch the low period of the SCL signal,

it must output the next data bit to the SDA line TR max. + TSU:DAT = 1000 + 250 = 1250 ns (according to

the Standard mode I²C bus specification), before the SCL line is released.

DS40001579E-page 386

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

NOTES:

 2011-2014 Microchip Technology Inc.

DS40001579E-page 387

PIC16(L)F1782/3

DS40001579E-page 388

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

31.0 DC AND AC

CHARACTERISTICS GRAPHS

AND CHARTS

The graphs and tables provided in this section are for design guidance and are not tested.

In some graphs or tables, the data presented are outside specified operating range (i.e., outside specified VDD

range). This is for information only and devices are ensured to operate properly only within the specified range.

Unless otherwise noted, all graphs apply to both the L and LF devices.

Note:

The graphs and tables provided following this note are a statistical summary based on a limited number of

samples and are provided for informational purposes only. The performance characteristics listed herein

are not tested or guaranteed. In some graphs or tables, the data presented may be outside the specified

operating range (e.g., outside specified power supply range) and therefore, outside the warranted range.

“Typical” represents the mean of the distribution at 25C. “Maximum”, “Max.”, “Minimum” or “Min.”

represents (mean + 3) or (mean - 3) respectively, where  is a standard deviation, over each

temperature range.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 389

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

35

14

Max.

Max: 85°C + 3σ

Typical: 25°C

Max.

Max: 85°C + 3σ

Typical: 25°C

30

25

20

15

10

5

12

10

8

Typical

6

4

2

0

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

VDD (V)

FIGURE 31-1:

IDD, LP Oscillator Mode,

FIGURE 31-2:

IDD, LP Oscillator Mode,

Fosc = 32 kHz, PIC16LF1782/3 Only.

Fosc = 32 kHz, PIC16F1782/3 Only.

500

450

400

4 MHz XT

Max: 85°C + 3σ

Typical: 25°C

350

300

250

200

150

100

50

400

350

300

250

200

150

100

50

4 MHz XT

4 MHz EXTRC

1 MHz XT

1 MHz EXTRC

0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

VDD (V)

FIGURE 31-3:

IDD Typical, XT and EXTRC

FIGURE 31-4:

IDD Maximum, XT and

Oscillator, PIC16LF1782/3 Only.

EXTRC Oscillator, PIC16LF1782/3 Only.

600

450

4 MHz XT

Max: 85°C + 3σ

400

350

300

250

200

150

100

50

Typical: 25°C

500

400

300

200

100

0

4 MHz EXTRC

1 MHz XT

1 MHz EXTRC

0

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

VDD (V)

FIGURE 31-5:

IDD Typical, XT and EXTRC

FIGURE 31-6:

IDD Maximum, XT and

Oscillator, PIC16F1782/3 Only.

EXTRC Oscillator, PIC16F1782/3 Only.

DS40001579E-page 390

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

9

8

7

6

5

4

3

2

1

0

30

25

20

15

10

5

Max.

Max: 85°C + 3σ

Typical: 25°C

Max.

Max: 85°C + 3σ

Typical: 25°C

Typical

0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

VDD (V)

FIGURE 31-7:

IDD, EC Oscillator LP Mode,

FIGURE 31-8:

IDD, EC Oscillator LP Mode,

Fosc = 32 kHz, PIC16LF1782/3 Only.

Fosc = 32 kHz, PIC16F1782/3 Only.

70

60

Max.

Max: 85°C + 3σ

60

50

40

30

20

10

0

Typical: 25°C

50

Typical: 25°C

Max.

40

Typical

30

20

10

0

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

VDD (V)

FIGURE 31-9:

IDD, EC Oscillator LP Mode,

FIGURE 31-10:

IDD, EC Oscillator LP Mode,

Fosc = 500 kHz, PIC16LF1782/3 Only.

Fosc = 500 kHz, PIC16F1782/3 Only.

350

400

4 MHz

350

300

250

200

150

100

50

Max: 85°C + 3σ

4 MHz

300

250

200

150

100

50

Typical: 25°C

1 MHz

0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

VDD (V)

FIGURE 31-11:

IDD Typical, EC Oscillator

FIGURE 31-12:

IDD Maximum, EC Oscillator

MP Mode, PIC16LF1782/3 Only.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 391

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

450

400

350

300

250

200

150

100

50

400

350

300

250

200

150

100

50

Max: 85°C + 3σ

Typical: 25°C

4 MHz

1 MHz

4 MHz

1 MHz

0

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

VDD (V)

FIGURE 31-13:

IDD Typical, EC Oscillator

FIGURE 31-14:

IDD Maximum, EC Oscillator

MP Mode, PIC16F1782/3 Only.

3.5

3.0

Typical: 25°C

Max: 85°C + 3σ

3.0

2.5

32 MHz

2.5

2.0

1.5

2.0

1.5

16 MHz

1.0

0.5

0.0

1.0

0.5

0.0

8 MHz

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

VDD (V)

FIGURE 31-15:

IDD Typical, EC Oscillator

FIGURE 31-16:

IDD Maximum, EC Oscillator

HP Mode, PIC16LF1782/3 Only.

3.0

2.5

32 MHz

Max: 85°C + 3σ

32 MHz

Typical: 25°C

2.5

2.0

1.5

16 MHz

1.5

1.0

0.5

0.0

16 MHz

1.0

8 MHz

0.5

0.0

2.0

2.5

3.0

3.5

4.0

VDD (V)

4.5

5.0

5.5

6.0

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

VDD (V)

FIGURE 31-17:

IDD Typical, EC Oscillator

FIGURE 31-18:

IDD Maximum, EC Oscillator

HP Mode, PIC16F1782/3 Only.

DS40001579E-page 392

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

9

8

7

6

5

4

3

2

1

0

30

25

20

15

10

5

Max.

Max: 85°C + 3σ

Typical: 25°C

Typical

Max: 85°C + 3σ

Typical: 25°C

0

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

VDD (V)

FIGURE 31-19:

IDD, LFINTOSC Mode,

FIGURE 31-20:

IDD, LFINTOSC Mode,

Fosc = 31 kHz, PIC16LF1782/3 Only.

Fosc = 31 kHz, PIC16F1782/3 Only.

700

600

550

Max.

Max: 85°C + 3σ

Typical: 25°C

Max.

600

Max: 85°C + 3σ

Typical: 25°C

500

Typical

450

400

500

400

300

200

100

350

Typical

300

250

200

150

100

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

VDD (V)

FIGURE 31-21:

IDD, MFINTOSC Mode,

FIGURE 31-22:

IDD, MFINTOSC Mode,

Fosc = 500 kHz, PIC16LF1782/3 Only.

Fosc = 500 kHz, PIC16F1782/3 Only.

1.8

16 MHz

1.6

1.4

1.2

1.0

0.8

0.6

0.4

0.2

0.0

1.6

1.4

1.2

1.0

0.8

0.6

0.4

0.2

0.0

16 MHz

Max: 85°C + 3σ

Typical: 25°C

8 MHz

4 MHz

8 MHz

4 MHz

2 MHz

1 MHz

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

VDD (V)

FIGURE 31-23:

IDD Typical, HFINTOSC

FIGURE 31-24:

IDD Maximum, HFINTOSC

Mode, PIC16LF1782/3 Only.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 393

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

1.6

1.8

16 MHz

1.4

1.2

1.0

0.8

0.6

0.4

0.2

0.0

1.6

1.4

1.2

1.0

0.8

0.6

0.4

0.2

0.0

Typical: 25°C

Max: 85°C + 3σ

8 MHz

4 MHz

8 MHz

4 MHz

2 MHz

1 MHz

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

VDD (V)

FIGURE 31-25:

IDD Typical, HFINTOSC

FIGURE 31-26:

IDD Maximum, HFINTOSC

Mode, PIC16F1782/3 Only.

2.0

1.8

1.6

1.4

1.2

1.0

0.8

0.6

0.4

0.2

0.0

20 MHz

16 MHz

Max: 85°C + 3σ

1.8

1.6

1.4

1.2

1.0

0.8

0.6

0.4

0.2

0.0

20 MHz

16 MHz

8 MHz

4 MHz

8 MHz

4 MHz

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

2.4

2.6

2.8

3.0

3.2

VDD (V)

3.4

3.6

3.8

VDD (V)

FIGURE 31-27:

IDD Typical, HS Oscillator,

FIGURE 31-28:

IDD Maximum, HS Oscillator,

25°C, PIC16LF1782/3 Only.

PIC16LF1782/3 Only.

2.1

2.0

1.8

1.6

1.4

1.2

1.0

0.8

0.6

0.4

0.2

0.0

20 MHz

16 MHz

Max: 85°C + 3σ

20 MHz

16 MHz

1.8

1.5

1.2

0.9

0.6

0.3

0.0

8 MHz

4 MHz

8 MHz

4 MHz

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

VDD (V)

FIGURE 31-29:

IDD Typical, HS Oscillator,

FIGURE 31-30:

IDD Maximum, HS Oscillator,

25°C, PIC16F1782/3 Only.

PIC16F1782/3 Only.

DS40001579E-page 394

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

4.0

3.5

3.0

2.5

2.0

1.5

1.0

0.5

0.0

4.0

3.5

3.0

2.5

2.0

1.5

1.0

0.5

0.0

Max.

Typical

Typical: 25°C

Max: 85°C + 3σ

2.4

2.6

2.8

3.0

3.2

VDD (V)

3.4

3.6

3.8

2.0

2.5

3.0

3.5

4.0

VDD (V)

4.5

5.0

5.5

6.0

FIGURE 31-31:

IDD, HS Oscillator, 32 MHz

FIGURE 31-32:

IDD, HS Oscillator, 32 MHz

(8 MHz + 4x PLL), PIC16LF1782/3 Only.

(8 MHz + 4x PLL), PIC16F1782/3 Only.

450

1.2

400

Max.

1.0

350

300

250

0.8

Max: 85°C + 3σ

Typical: 25°C

0.6

0.4

0.2

0.0

Max: 85°C + 3σ

Typical: 25°C

200

150

100

50

Typical

0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

2.0

2.5

3.0

3.5

4.0

VDD (V)

4.5

5.0

5.5

6.0

VDD (V)

FIGURE 31-33:

IPD Base, LP Sleep Mode,

FIGURE 31-34:

IPD Base, LP Sleep Mode

PIC16LF1782/3 Only.

(VREGPM = 1), PIC16F1782/3 Only.

2.5

3.0

Max: 85°C + 3σ

Typical: 25°C

2.5

Max: 85°C + 3σ

Typical: 25°C

2.0

Max.

2.0

1.5

1.0

0.5

0.0

1.5

1.0

Typical

0.5

0.0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

VDD (V)

FIGURE 31-35:

IPD, Watchdog Timer (WDT),

FIGURE 31-36:

IPD, Watchdog Timer (WDT),

PIC16LF1782/3 Only.

PIC16F1782/3 Only.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 395

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

35

30

25

20

15

10

5

35

30

25

20

15

10

5

Max: 85°C + 3σ

Typical: 25°C

Max.

Typical

Max: 85°C + 3σ

Typical: 25°C

0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

2.0

2.5

3.0

3.5

4.0

VDD (V)

4.5

5.0

5.5

6.0

VDD (V)

FIGURE 31-37:

IPD, Fixed Voltage Reference

FIGURE 31-38:

IPD, Fixed Voltage Reference

(FVR), PIC16LF1782/3 Only.

(FVR), PIC16F1782/3 Only.

13

11

Max: 85°C + 3σ

Typical: 25°C

Max: 85°C + 3σ

Typical: 25°C

12

11

10

9

Max.

10

9

Max.

Typical

8

Typical

8

7

6

5

4

7

6

5

4

2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2 4.4 4.6 4.8 5.0 5.2 5.4 5.6

2.9

3.0

3.1

3.2

3.3

3.4

3.5

3.6

3.7

VDD (V)

FIGURE 31-39:

IPD, Brown-Out Reset

FIGURE 31-40:

IPD, Brown-Out Reset

(BOR), BORV = 1, PIC16LF1782/3 Only.

(BOR), BORV = 1, PIC16F1782/3 Only.

Ipd, Low-Power Brown-Out Reset (LPBOR = 0)

1.8

Max.

Max: 85°C + 3σ

Typical: 25°C

1.6

Max.

1.4

1.2

1.0

0.8

0.6

Max: 85°C + 3σ

1.0

0.8

0.6

0.4

0.2

0.0

Typical: 25°C

Typical

0.4

0.2

0.0

2.9

3.0

3.1

3.2

3.3

3.4

3.5

3.6

3.7

2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2 4.4 4.6 4.8 5.0 5.2 5.4 5.6

FIGURE 31-41:

IPD, LP Brown-Out Reset

FIGURE 31-42:

IPD, LP Brown-Out Reset

(LPBOR = 0), PIC16LF1782/3 Only.

(LPBOR = 0), PIC16F1782/3 Only.

DS40001579E-page 396

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

7

6

5

4

3

2

1

0

12

10

8

Max: 85°C + 3σ

Typical: 25°C

Max: 85°C + 3σ

Typical: 25°C

Max.

6

Typical

4

2

0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

2.0

2.5

3.0

3.5

4.0

VDD (V)

4.5

5.0

5.5

6.0

VDD (V)

FIGURE 31-43:

IPD, Timer1 Oscillator,

FIGURE 31-44:

IPD, Timer1 Oscillator,

FOSC = 32 kHz, PIC16LF1782/3 Only.

FOSC = 32 kHz, PIC16F1782/3 Only.

700

900

Max: 85°C + 3σ

Typical: 25°C

Max: 85°C + 3σ

Typical: 25°C

800

600

500

400

300

200

100

0

Max.

700

600

Max.

500

Typical

400

300

200

100

0

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

VDD (V)

FIGURE 31-45:

IPD, Op Amp, High GBWP

FIGURE 31-46:

IPD, Op Amp, High GBWP

Mode (OPAxSP = 1), PIC16LF1782/3 Only.

Mode (OPAxSP = 1), PIC16F1782/3 Only.

500

1.4

Max: 85°C + 3σ

Typical: 25°C

450

400

350

300

250

200

150

100

50

Max: 85°C + 3σ

Max.

Typical: 25°C

1.2

1.0

0.8

0.6

0.4

0.2

0.0

Max.

Typical

0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

1.5

2.0

2.5

3.0

3.5

4.0

VDD (V)

4.5

5.0

5.5

6.0

VDD (V)

FIGURE 31-47:

PIC16LF1782/3 Only.

IPD, ADC Non-Converting,

FIGURE 31-48:

PIC16F1782/3 Only.

IPD, ADC Non-Converting,

 2011-2014 Microchip Technology Inc.

DS40001579E-page 397

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

800

700

600

500

400

300

200

800

700

600

500

400

300

200

Max: -40°C + 3σ

Typical: 25°C

Max: -40°C + 3σ

Typical: 25°C

Max.

Typical

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

VDD (V)

FIGURE 31-49:

IPD, Comparator, NP Mode

FIGURE 31-50:

IPD, Comparator, NP Mode

(CxSP = 1), PIC16LF1782/3 Only.

(CxSP = 1), PIC16F1782/3 Only.

6

5

4

3

5

Max: -40°C max + 3σ

Typical;:statistical mean @ 25°C

4

3

2

1

0

Min: +125°C min - 3σ

Min.

Typical

Max.

Typical

Min.

2

1

0

Max: -40°C max + 3σ

Typical: statistical mean @ 25°C

Min: +125°C min - 3σ

-30

-25

-20

-15

IOH (mA)

-10

-5

0

10

20

30

40

IOL (mA)

50

60

70

80

FIGURE 31-51:

VOH vs. IOH Over

FIGURE 31-52:

VOL vs. IOL Over

Temperature, VDD = 5.0V, PIC16F1782/3 Only.

3.0

3.5

Max: -40°C max + 3σ

Typical: statistical mean @ 25°C

3.0

2.5

2.0

1.5

1.0

0.5

0.0

2.5

2.0

1.5

1.0

0.5

0.0

Min: +125°C min - 3σ

Max.

Typical

Min.

Max.

Typical

Min.

-14

-12

-10

-8

-6

-4

-2

0

5

10

15

20

25

30

IOH (mA)

IOL (mA)

FIGURE 31-53:

Temperature, VDD = 3.0V.

VOH vs. IOH Over

FIGURE 31-54:

Temperature, VDD = 3.0V.

VOL vs. IOL Over

DS40001579E-page 398

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

Voh vs. Ioh over Temperature, Vdd = 1.8V

Vol vs. Iol over Temperature, Vdd = 1.8V

2.0

1.8

Max: -40°C max + 3σ

1.8

1.6

1.4

1.2

1

Typical: statistical mean @ 25°C

Min: +125°C min - 3σ

1.6

1.4

1.2

1.0

Min.

Typical

Max.

Min.

Typical

Max.

0.8

0.6

0.4

0.2

0

0.8

0.6

0.4

0.2

0.0

-4

-3.5

-3

-2.5

-2

-1.5

-1

-0.5

0

1

2

3

4

5

6

7

8

9

10

FIGURE 31-55:

VOH vs. IOH Over

FIGURE 31-56:

VOL vs. IOL Over

Temperature, VDD = 1.8V, PIC16LF1782/3 Only.

LFINTOSC Frequency

40

38

40

Max.

36

38

Max.

36

34

Typical

34

32

Typical

32

30

Min.

28

26

Max: Typical + 3σ (-40°C to +125°C)

24

Typical; statistical mean @ 25°C

24

22

20

Max: Typical + 3σ (-40°C to +125°C)

Typical; statistical mean @ 25°C

Min: Typical - 3σ (-40°C to +125°C)

22

20

1.5

1.8

2.1

2.4

2.7

3.0

3.3

3.6

VDD (V)

2

2.5

3

3.5

VDD (V)

4

4.5

5

5.5

6

FIGURE 31-57:

LFINTOSC Frequency,

FIGURE 31-58:

LFINTOSC Frequency,

PIC16LF1782/3 Only.

PIC16F1782/3 Only.

24

22

20

18

16

14

12

10

24

22

20

18

16

14

12

10

Max.

Typical

Min.

Typical

Min.

Max: Typical + 3σ (-40°C to +125°C)

Typical; statistical mean @ 25°C

Min: Typical - 3σ (-40°C to +125°C)

Max: Typical + 3σ (-40°C to +125°C)

Typical; statistical mean @ 25°C

Min: Typical - 3σ (-40°C to +125°C)

2.0

2.5

3.0

3.5

VDD (V)

4.0

4.5

5.0

5.5

6.0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

VDD (V)

FIGURE 31-59:

WDT Time-Out Period,

FIGURE 31-60:

WDT Time-Out Period,

PIC16F1782/3 Only.

PIC16LF1782/3 Only.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 399

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

70

60

50

40

30

20

10

0

2.00

1.95

1.90

1.85

1.80

Max: Typical + 3σ

Typical: Statistical Mean

Min: Typical - 3σ

Max.

Typical

Min.

Typical

Min.

Max: Typical + 3σ

Typical: Statistical Mean

Min: Typical - 3σ

-60

-40

-20

0

20

40

60

80

100

120

140

-60

-40

-20

0

20

40

60

80

100

120

140

Temperature (°C)

FIGURE 31-61:

Brown-Out Reset Voltage,

FIGURE 31-62:

Brown-Out Reset Hysteresis,

Low Trip Point (BORV = 1), PIC16LF1782/3 Only.

70

2.60

Max: Typical + 3σ

Typical: Statistical Mean

60

50

40

30

20

10

0

Min: Typical - 3σ

2.55

Max.

Typical

2.50

Min.

Typical

Min.

2.45

2.40

Max: Typical + 3σ

2.35

2.30

Typical: Statistical Mean

Min: Typical - 3σ

-60

-40

-20

0

20

40

60

80

100

120

140

-60

-40

-20

0

20

40

60

80

100

120

140

Temperature (°C)

FIGURE 31-63:

Brown-Out Reset Voltage,

FIGURE 31-64:

Brown-Out Reset Hysteresis,

Low Trip Point (BORV = 1), PIC16F1782/3 Only.

2.85

80

Max: Typical + 3σ

Typical: Statistical Mean

70

Min: Typical - 3σ

2.80

Max.

60

Max.

50

2.75

Typical

40

Min.

2.70

2.65

2.60

30

20

Min.

10

0

-60

-40

-20

0

20

40

60

80

100

120

140

-60

-40

-20

0

20

40

60

80

100

120

140

Temperature (°C)

FIGURE 31-65:

Brown-Out Reset Voltage,

FIGURE 31-66:

Brown-Out Reset Hysteresis,

High Trip Point (BORV = 0).

DS40001579E-page 400

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

2.6

2.5

2.4

2.3

2.2

2.1

2.0

1.9

1.8

1.7

50

45

40

35

30

25

20

15

10

5

Max.

Max: Typical + 3σ

Typical: Statistical Mean

Min: Typical - 3σ

Max: Typical + 3σ

Typical: Statistical Mean

Typical

Min.

Typical

0

-60

-40

-20

0

20

40

60

80

100

120

140

-60

-40

-20

0

20

40

60

80

100

120

140

Temperature (°C)

FIGURE 31-67:

LPBOR Reset Voltage.

FIGURE 31-68:

LPBOR Reset Hysteresis.

110

100

90

100

90

80

70

60

50

40

Max: Typical + 3σ (-40°C to +125°C)

Typical; statistical mean @ 25°C

Min: Typical - 3σ (-40°C to +125°C)

Max: Typical + 3σ (-40°C to +125°C)

Typical; statistical mean @ 25°C

Min: Typical - 3σ (-40°C to +125°C)

Max.

80

Typical

Min.

Typical

70

60

Min.

50

40

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

2.0

2.5

3.0

3.5

VDD (V)

4.0

4.5

5.0

5.5

6.0

VDD (V)

FIGURE 31-69:

PWRT Period,

FIGURE 31-70:

PWRT Period,

PIC16F1782/3 Only.

PIC16LF1782/3 Only.

1.58

1.70

1.68

1.66

1.64

1.62

1.60

1.58

1.56

Max: Typical + 3σ

Typical: 25°C

Min: Typical - 3σ

1.56

Max.

1.54

Typical

Min.

1.52

Min.

1.50

1.5

1.48

Max: Typical + 3σ

Typical: Statistical Mean

Min: Typical - 3σ

Max: Typical + 3σ

Typical: Statistical Mean

Min: Typical - 3σ

1.54

1.52

1.50

1.46

-40

-20

0

20

40

Temperature (°C)

20 40 60

60

80

100

120

140

1.44

-60

-40

-20

0

80

100

120

-60

-40

-20

0

20

40

60

80

100

120

140

Temperature (°C)

FIGURE 31-71:

POR Release Voltage.

FIGURE 31-72:

POR Rearm Voltage,

NP Mode (VREGPM = 0), PIC16F1782/3 Only.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 401

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

1.4

1.3

1.2

1.1

1.0

0.9

0.8

0.7

0.6

12

10

8

Max.

Typical

Max.

6

Typical

4

Min.

Max: Typical + 3σ (-40°C to +125°C)

Max: Typical + 3σ

Typical: Statistical Mean

Min: Typical - 3σ

2

Typical; statistical mean @ 25°C

0

-60

-40

-20

0

20

40

60

80

100

120

140

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

Temperature (°C)

VDD (V)

FIGURE 31-73:

POR Rearm Voltage,

FIGURE 31-74:

Wake From Sleep,

NP Mode, PIC16LF1782/3 Only.

VREGPM = 0.

50

45

40

35

30

25

Max: Typical + 3σ

Typical: statistical mean @ 25°C

40

Max.

35

30

Typical

25

20

15

10

20

Note:

The FVR Stabilization Period applies when:

1) coming out of Reset or exiting Sleep mode for PIC12/16LFxxxx devices.

2) when exiting Sleep mode with VREGPM = 1 for PIC12/16Fxxxx devices

In all other cases, the FVR is stable when released from Reset.

Max: Typical + 3σ (-40°C to +125°C)

Typical; statistical mean @ 25°C

15

10

5

0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

VDD (mV)

VDD (V)

FIGURE 31-75:

Wake From Sleep,

FIGURE 31-76:

FVR Stabilization Period.

VREGPM = 1.

1.0

0.5

1.0

0.5

0.0

-0.5

-1.0

-0.5

-1.0

0

128

256

384

512

640

768

896

1024

0

128

256

384

512

640

768

896

1024

Output Code

FIGURE 31-77:

ADC 10-bit Mode,

FIGURE 31-78:

ADC 10-bit Mode,

Single-Ended DNL, VDD = 3.0V, TAD = 1 S, 25°C.

Single-Ended DNL, VDD = 3.0V, TAD = 4 S, 25°C.

DS40001579E-page 402

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

1.0

2.0

1.0

1.5

1.0

0.5

0.0

-0.5

-1.0

-1.5

-0.5

-2.0

-0.5

-1.0

0

512

128

1024

256

1536

384

2048

2560

640

3072

768

3584

896

4096

1024

Output Code

-1.0

512

0

128

256

384

512

640

768

896

1024

Output Code

FIGURE 31-79:

ADC 10-bit Mode,

FIGURE 31-80:

ADC 10-bit Mode,

Single-Ended INL, VDD = 3.0V, TAD = 1 S, 25°C.

Single-Ended INL, VDD = 3.0V, TAD = 4 S, 25°C.

2.0

1.5

2.5

2.0

1.5

Max -40C

1.0

0.5

Max 125C

Max 25C

1.0

Max -40C

Max 25C

0.5

0.0

Min 25C

-0.5

Min 25C

Min 125C

-0.5

-1.0

Min 125C

Min -40C

-1.0

Min -40C

-1.5

-2.0

-2.5

-1.5

-2.0

0.5

1.0

2.0

4.0

8.0

0.5

1.0

2.0

4.0

8.0

TAD (μs)

FIGURE 31-81:

ADC 10-bit Mode,

FIGURE 31-82:

ADC 10-bit Mode,

Single-Ended DNL, VDD = 3.0V, VREF = 3.0V.

Single-Ended INL, VDD = 3.0V, VREF = 3.0V.

2.0

Max -40C

1.5

Max 125C

1.5

Max 125C

Max 25C

1.0

0.5

1.0

Max -40C

Max 25C

0.5

0.0

Min -40C

Min 25C

0.0

-0.5

-1.0

-1.5

Min -40C

-0.5

Min 125C

Min 25C

-1.0

Min 125C

-2.0

-2.5

-3.0

-1.5

-2.0

1.8

2.3

3.0

1.8

2.3

3.0

Reference Voltage (V)

FIGURE 31-83:

ADC 10-bit Mode,

FIGURE 31-84:

ADC 10-bit Mode,

Single-Ended DNL, VDD = 3.0V, TAD = 1 S.

Single-Ended INL, VDD = 3.0V, TAD = 1 S.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 403

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

3.0

2.5

2.0

1.5

1.0

0.5

0.0

-0.5

-1.0

-1.5

2.5

2.0

1.5

1.0

0.5

0.0

-0.5

-1.0

-1.5

0

500

1000

1500

2000

2500

3000

3500

4000

0

500

1000

1500

2000

2500

3000

3500

4000

Output Code

FIGURE 31-85:

ADC 12-bit Mode,

FIGURE 31-86:

ADC 12-bit Mode,

Single-Ended DNL, VDD = 3.0V, TAD = 1 S, 25°C.

Single-Ended DNL, VDD = 3.0V, TAD = 4 S, 25°C.

3.0

2.5

2.0

1.5

1.0

0.5

0.0

-0.5

-1.0

-1.5

3.5

3.0

2.5

2.0

1.5

1.0

0.5

0.0

-0.5

-1.0

-1.5

0

500

1000

1500

2000

2500

3000

3500

4000

0

500

1000

1500

2000

2500

3000

3500

4000

Output Code

FIGURE 31-87:

ADC 12-bit Mode,

FIGURE 31-88:

ADC 12-bit Mode,

Single-Ended INL, VDD = 3.0V, TAD = 1 S, 25°C.

Single-Ended INL, VDD = 3.0V, TAD = 4 S, 25°C.

4.5

5.5

Max -40C

3

Max 125C

3.5

Max 125C

Max 25C

1.5

0

-0.5

Min 25C

Min -40C

Min 125C

Min -40C

-1.5

-2.5

Min 125C

8.0

-3

-4.5

0.5

1.0

2.0

4.0

8.0

0.5

1.0

2.0

4.0

TAD (μs)

FIGURE 31-89:

ADC 12-bit Mode,

FIGURE 31-90:

ADC 12-bit Mode,

Single-Ended DNL, VDD = 3.0V, VREF = 3.0V.

Single-Ended INL, VDD = 3.0V, VREF = 3.0V.

DS40001579E-page 404

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

6

5

4

Max -40C

4

Max -40C

Max 25C

3

Max 25C

Max 125C

2

1

Max 125C

1

0

Min 125C

-1

-2

-3

-4

0

Min 125C

Min 25C

Min -40C

Min 25C

-1

-2

1.8

2.3

3.0

1.8

2.3

3.0

Reference Voltage (V)

FIGURE 31-91:

ADC 12-bit Mode,

FIGURE 31-92:

ADC 12-bit Mode,

Single-Ended DNL, VDD = 3.0V, TAD = 1 S.

Single-Ended INL, VDD = 3.0V, TAD = 1 S.

2.5

2.0

2.5

2.0

1.5

1.0

0.5

0.0

-0.5

-1.0

1.5

1.0

0.5

0.0

-0.5

-1.0

-1.5

0

500

1000

1500

2000

2500

3000

3500

4000

0

500

1000

1500

2000

2500

3000

3500

4000

Output Code

FIGURE 31-93:

ADC 12-bit Mode,

FIGURE 31-94:

ADC 12-bit Mode,

Single-Ended DNL, VDD = 5.5V, TAD = 1 S, 25°C.

Single-Ended DNL, VDD = 5.5V, TAD = 4 S, 25°C.

3.5

2.0

3.5

3.0

2.5

2.0

1.5

1.0

0.5

0.0

-0.5

3.0

1.5

1.0

2.5

0.5

2.0

0.0

1.5

-0.5

1.0

-1.0

0.5

-1.5

0.0

-2.0

0

512

500

1024

1000

1536

1500

2048

2560

3072

3000

3584

3500

4096

4000

-0.5

Output Code

2000

2500

0

500

1000

1500

2000

2500

3000

3500

4000

Output Code

FIGURE 31-95:

ADC 12-bit Mode,

FIGURE 31-96:

ADC 12-bit Mode,

Single-Ended INL, VDD = 5.5V, TAD = 1 S, 25°C.

Single-Ended INL, VDD = 5.5V, TAD = 4 S, 25°C.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 405

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

4

3

Max 25C

Max -40C

3

Max -40C

Max 125C

Max 25C

2

Max 125C

1

0

Min 25C

Min -40C

-1

Min 25C

Min -40C

Min 125C

-2

1.0

2.0

TAD (μs)

4.0

1.0

2.0

TAD (μs)

4.0

FIGURE 31-97:

ADC 12-bit Mode,

FIGURE 31-98:

ADC 12-bit Mode,

Single-Ended DNL, VDD = 5.5V, VREF = 5.5V.

Single-Ended INL, VDD = 5.5V, VREF = 5.5V.

900

800

ADC Vref+ set to Vdd

ADC Vref- set to Gnd

ADC Vref+ set to Vdd

ADC Vref- set to Gnd

Max.

700

800

700

600

500

400

300

Max.

Typical

600

500

Typical

Min.

400

300

Min.

Max: Typical + 3σ

Typical; statistical mean

Min: Typical - 3σ

200

Max: Typical + 3σ

Typical; statistical mean

100

0

Min: Typical - 3σ

2

2.4

2.8

3.2

3.6

4

4.4

4.8

5.2

5.6

6

2.5

3.0

3.5

4.0

VDD (V)

4.5

5.0

5.5

6.0

VDD (V)

FIGURE 31-99:

Temp. Indicator Initial Offset,

FIGURE 31-100:

Temp. Indicator Initial Offset,

High Range, Temp. = 20°C, PIC16F1782/3 Only.

Low Range, Temp. = 20°C, PIC16F1782/3 Only.

800

150

ADC Vref+ set to Vdd

ADC Vref- set to Gnd

ADC Vref+ set to Vdd

Max.

ADC Vref- set to Gnd

125

100

75

700

Max.

600

Min.

500

50

Min.

25

400

0

Typical

300

200

100

Max: Typical + 3σ

Typical; statistical mean

Min: Typical - 3σ

-25

-50

-75

Max: Typical + 3σ

Typical; statistical mean

Min: Typical - 3σ

Typical

-60 -40

1.6

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

3.8

-20

0

20

40

60

80

100

120

140

VDD (V)

Temperature (°C)

FIGURE 31-101:

Temp. Indicator Initial Offset,

FIGURE 31-102:

Temp. Indicator Slope

Low Range, Temp. = 20°C, PIC16LF1782/3 Only.

Normalized to 20°C, High Range, VDD = 5.5V,

PIC16F1782/3 Only.

DS40001579E-page 406

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

250

200

150

100

50

150

100

50

Max.

Min.

Max.

Min.

ADC Vref+ set to Vdd

ADC Vref- set to Gnd

ADC Vref+ set to Vdd

ADC Vref- set to Gnd

0

-50

-100

-150

-50

-100

Typical

Max: Typical + 3σ

Typical

Max: Typical + 3σ

Typical; statistical mean

Min: Typical - 3σ

-60

-40

-20

0

20

40

60

80

100

120

140

-60

-40

-20

0

20

40

60

80

100

120

140

Temperature (°C)

FIGURE 31-103:

Temp. Indicator Slope

FIGURE 31-104:

Temp. Indicator Slope

Normalized to 20°C, High Range, VDD = 3.6V,

PIC16F1782/3 Only.

Normalized to 20°C, Low Range, VDD = 3.0V,

PIC16F1782/3 Only.

250

150

Max.

ADC Vref+ set to Vdd

ADC Vref- set to Gnd

ADC Vref+ set to Vdd

ADC Vref- set to Gnd

Max.

200

150

100

50

100

50

Min.

0

-50

-100

-150

-50

-100

Typical

Max: Typical + 3σ

Typical; statistical mean

Min: Typical - 3σ

-60

-40

-20

0

20

40

60

80

100

120

140

-60

-40

-20

0

20

40

60

80

100

120

140

Temperature (°C)

FIGURE 31-105:

Temp. Indicator Slope

FIGURE 31-106:

Temp. Indicator Slope

Normalized to 20°C, Low Range, VDD = 1.8V,

PIC16LF1782/3 Only.

Normalized to 20°C, Low Range, VDD = 3.0V,

PIC16LF1782/3 Only.

250

80

ADC Vref+ set to Vdd

ADC Vref- set to Gnd

Max

Max.

200

150

100

50

75

70

Min.

Typical

65

60

Min

55

0

50

-50

-100

-150

Max: Typical + 3σ

Typical

Typical; statistical mean

45

Typical; statistical mean

Min: Typical - 3σ

40

-50

-30

-10

10

30

50

70

90

110

130

-60

-40

-20

0

20

40

60

80

100

120

140

Temperature (°C)

FIGURE 31-107:

Temp. Indicator Slope

FIGURE 31-108:

Op Amp, Common Mode

Normalized to 20°C, High Range, VDD = 3.6V,

PIC16LF1782/3 Only.

Rejection Ratio (CMRR), VDD = 3.0V.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 407

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

35%

8

Sample Size = 3,200

Max

30%

6

4

25%

Typical

2

20%

-40°C

0

25°C

Min

15%

85°C

-2

-4

125°C

10%

Max: Typical + 3σ

Typical; statistical mean

Min: Typical - 3σ

-6

5%

-8

0%

0.0

0.3

0.6

0.9

1.2

1.5

1.8

2.1

2.4

2.7

3.0

-7

-5

-4

-3

-2

-1

0

1

2

3

4

5

6

7

Common Mode Voltage (V)

Offset Voltage (mV)

FIGURE 31-109:

Op Amp, Output Voltage

FIGURE 31-110:

Op Amp, Offset Over

Histogram, VDD = 3.0V, VCM = VDD/2.

Common Mode Voltage, VDD = 3.0V,

Temp. = 25°C.

8

3.8

3.7

3.6

3.5

3.4

3.3

3.2

3.1

3.0

Max

Vdd = 3.6V

Vdd = 5.5V

6

4

Typical

2

0

Vdd = 2.3V

Vdd = 3V

-2

-4

Min

Max: Typical + 3σ

Typical; statistical mean

-6

-8

Min: Typical - 3σ

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

-60

-40

-20

0

20

40

60

80

100

120

140

Common Mode Voltage (V)

Temperature (°C)

FIGURE 31-111:

Op Amp, Offset Over

FIGURE 31-112:

Op Amp, Output Slew Rate,

Common Mode Voltage, VDD = 5.0V,

Temp. = 25°C, PIC16F1782/3 Only.

Rising Edge.

5.4

5.2

5.0

4.8

4.6

4.4

4.2

4.0

3.8

3.6

45

43

41

39

37

35

33

31

29

27

25

Vdd = 2.3V

Vdd = 3.6V

-40°C

25°C

85°C

125°

Vdd = 5.5V

Vdd = 3V

-60

-40

-20

0

20

40

60

80

100

120

140

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

Temperature (°C)

Common Mode Voltage (V)

FIGURE 31-113:

Op Amp, Output Slew Rate,

FIGURE 31-114:

Comparator Hysteresis,

Falling Edge.

NP Mode (CxSP = 1), VDD = 3.0V, Typical

Measured Values.

DS40001579E-page 408

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

30

25

20

15

10

5

30

25

20

15

10

5

MAX

MIN

0

-5

-10

-15

-20

-10

-15

-20

MIN

0.0

0.5

1.0

1.5

2.0

2.5

3.0

0.0

0.5

1.0

1.5

2.0

2.5

3.0

Common Mode Voltage (V)

FIGURE 31-115:

Comparator Offset, NP Mode

FIGURE 31-116:

Comparator Offset, NP Mode

(CxSP = 1), VDD = 3.0V, Typical Measured Values

at 25°C.

From -40°C to 125°C.

30

25

20

15

50

45

40

MAX

10

25°C

125°

5

0

35

85°

30

-5

-40°C

-10

MIN

25

-15

-20

20

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

Common Mode Voltage (V)

FIGURE 31-117:

Comparator Hysteresis,

FIGURE 31-118:

Comparator Offset, NP Mode

NP Mode (CxSP = 1), VDD = 5.5V, Typical

(CxSP = 1), VDD = 5.0V, Typical Measured Values

Measured Values, PIC16F1782/3 Only.

at 25°C, PIC16F1782/3 Only.

140

40

30

20

Max: Typical + 3σ (-40°C to +125°C)

Typical; statistical mean @ 25°C

120

Min: Typical - 3σ (-40°C to +125°C)

100

125°C

MAX

80

10

25°C

60

0

40

-40°C

-10

20

MIN

-20

0

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

1.8

2.1

2.4

2.7

3.0

3.3

3.6

Common Mode Voltage (V)

VDD (V)

FIGURE 31-119:

Comparator Offset, NP Mode

FIGURE 31-120:

Comparator Response Time

(CxSP = 1), VDD = 5.0V, Typical Measured Values

Over Voltage, NP Mode (CxSP = 1), Typical

From -40°C to 125°C, PIC16F1782/3 Only.

Measured Values, PIC16LF1782/3 Only.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 409

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

90

80

70

60

50

40

30

20

10

0

1,400

1,200

1,000

800

Max: Typical + 3σ (-40°C to +125°C)

Typical; statistical mean @ 25°C

Min: Typical - 3σ (-40°C to +125°C)

Max: Typical + 3σ (-40°C to +125°C)

Typical; statistical mean @ 25°C

Min: Typical - 3σ (-40°C to +125°C)

125°C

25°C

125°C

25°C

600

400

-40°C

200

-40°C

0

2.2

2.5

2.8

3.1

3.4

3.7

4.0

4.3

4.6

4.9

5.2

5.5

1.8

2.0

2.2

2.4

2.6

2.8

3.0

3.2

3.4

3.6

VDD (V)

FIGURE 31-122:

Delay Time Over Temp., NP Mode (CxSP = 1),

Typical Measured Values, PIC16LF1782/3 Only.

Comparator Output Filter

FIGURE 31-121:

Over Voltage, NP Mode (CxSP = 1), Typical

Measured Values, PIC16F1782/3 Only.

Comparator Response Time

0.025

0.020

0.015

0.010

800

Max: Typical + 3σ (-40°C to +125°C)

Typical; statistical mean @ 25°C

700

600

500

400

300

200

100

0

Min: Typical - 3σ (-40°C to +125°C)

0.005

125°C

-40°C

25°C

0.000

85°C

25°C

-0.005

-0.010

-0.015

-0.020

125°C

-40°C

3.4

2.2

2.5

2.8

3.1

3.7

4.0

4.3

4.6

4.9

5.2

5.5

0

16 32 48 64 80 96 112 128 144 160 176 192 208 224 240

Output Code

VDD (V)

FIGURE 31-123:

Comparator Output Filter

FIGURE 31-124:

Typical DAC DNL Error,

Delay Time Over Temp., NP Mode (CxSP = 1),

VDD = 3.0V, VREF = External 3V.

Typical Measured Values, PIC16F1782/3 Only.

0.020

0.015

0.010

0.005

0.000

-0.005

-0.010

-0.015

0.00

-0.05

-0.10

-0.15

-0.20

-40°C

25°C

85°C

125°C

-40°C

25°C

-0.25

85°C

-0.30

-0.35

-0.40

-0.45

125°C

0

16 32 48 64 80 96 112 128 144 160 176 192 208 224 240

0

16 32 48 64 80 96 112 128 144 160 176 192 208 224 240

Output Code

FIGURE 31-125:

Typical DAC INL Error,

FIGURE 31-126:

Typical DAC INL Error,

VDD = 3.0V, VREF = External 3V.

VDD = 5.0V, VREF = External 5V, PIC16F1782/3

Only.

DS40001579E-page 410

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: Unless otherwise noted, VIN = 5V, FOSC = 300 kHz, CIN = 0.1 µF, TA = 25°C.

0.45

0.4

0.00

-0.05

-0.10

-0.15

-0.20

-0.25

-0.30

-0.35

-0.40

-0.45

Vref = Int. Vdd

0.35

0.3

Vref = Ext.

1.8V

Vref = Ext.

2.0V

0.25

0.2

Vref = Int. Vdd

Vref = Ext. 1.8V

Vref = Ext. 2.0V

Vref = Ext. 3.0V

-40°C

25°C

85°C

125°C

0.15

0.2

0.1

0.05

0

0.1

-50

0

50

Temperature (°C)

100

150

0.0

-60

-40

-20

0

20

40

60

80

100

120

140

0

16 32 48 64 80 96 112 128 144 160 176 192 208 224 240

Temperature (°C)

Output Code

FIGURE 31-128:

Error, VDD = 3.0V, VREF = VDD.

Absolute Value of DAC DNL

FIGURE 31-127:

VDD = 5.0V, VREF = External 5V, PIC16F1782/3

Only.

Typical DAC INL Error,

0.90

-2.1

00.3.30

0.25

-2.3

Vref = Int. Vdd

Vref = Ext.

Vref = Int. Vdd

0.88

0.26

0.2

Vref = Ext.

-2.5

1.8V

Vref = Ext.

0.86

-2.7

-40

25

-40

25

2.0V

0.15

Vref = Ext.

0.22

3.0V

-2.9

0.84

-3.1

85

Vref = Ext.

85

0.1

5.0V

125

0.18

0.05

-3.3

0.82

-3.5

0

0.0

1.0

2.0

3.0

4.0

5.0

0.0

-60

1.0

2.0

0

3.0

Temperature (°C)

4.0

5.0

6.0

0.14

0.80

Temperature (°C)

0.78

0.10

-60

-40

-20

0

20

40

60

80

100

120

140

-40

-20

20

40

60

80

100

120

140

Temperature (°C)

FIGURE 31-129:

Absolute Value of DAC INL

FIGURE 31-130:

Absolute Value of DAC DNL

Error, VDD = 3.0V.

Error, VDD = 5.0V, PIC16F1782/3 Only.

0.9

-2.1

-2.3

Vref = Int. Vdd

0.88

-2.5

Vref = Ext.

1.8V

Vref = Ext.

0.86

-2.7

-40

25

2.0V

Vref = Ext.

-2.9

0.84

-3.1

3.0V

85

125

-3.3

0.82

-3.5

0.0

1.0

2.0

3.0

4.0

5.0

6.0

0.8

Temperature (°C)

0.78

-60

-40

-20

0

20

40

60

80

100

120

140

Temperature (°C)

FIGURE 31-131:

Absolute Value of DAC INL

Error, VDD = 5.0V, PIC16F1782/3 Only.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 411

PIC16(L)F1782/3

32.1 MPLAB X Integrated Development

Environment Software

32.0 DEVELOPMENT SUPPORT

The PIC^®microcontrollers (MCU) and dsPIC^®digital

signal controllers (DSC) are supported with a full range

of software and hardware development tools:

The MPLAB X IDE is a single, unified graphical user

interface for Microchip and third-party software, and

hardware development tool that runs on Windows^®,

Linux and Mac OS^®X. Based on the NetBeans IDE,

MPLAB X IDE is an entirely new IDE with a host of free

software components and plug-ins for high-

performance application development and debugging.

Moving between tools and upgrading from software

simulators to hardware debugging and programming

tools is simple with the seamless user interface.

• Integrated Development Environment

- MPLAB^®X IDE Software

• Compilers/Assemblers/Linkers

- MPLAB XC Compiler

- MPASM^TMAssembler

- MPLINK^TMObject Linker/

MPLIB^TMObject Librarian

- MPLAB Assembler/Linker/Librarian for

Various Device Families

With complete project management, visual call graphs,

a configurable watch window and a feature-rich editor

that includes code completion and context menus,

MPLAB X IDE is flexible and friendly enough for new

users. With the ability to support multiple tools on

multiple projects with simultaneous debugging, MPLAB

X IDE is also suitable for the needs of experienced

users.

• Simulators

- MPLAB X SIM Software Simulator

• Emulators

- MPLAB REAL ICE™ In-Circuit Emulator

• In-Circuit Debuggers/Programmers

- MPLAB ICD 3

Feature-Rich Editor:

- PICkit™ 3

• Color syntax highlighting

• Device Programmers

- MPLAB PM3 Device Programmer

• Smart code completion makes suggestions and

provides hints as you type

• Low-Cost Demonstration/Development Boards,

Evaluation Kits and Starter Kits

• Automatic code formatting based on user-defined

rules

• Third-party development tools

• Live parsing

User-Friendly, Customizable Interface:

• Fully customizable interface: toolbars, toolbar

buttons, windows, window placement, etc.

• Call graph window

Project-Based Workspaces:

• Multiple projects

• Multiple tools

• Multiple configurations

• Simultaneous debugging sessions

File History and Bug Tracking:

• Local file history feature

• Built-in support for Bugzilla issue tracker

DS40001579E-page 412

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

32.2 MPLAB XC Compilers

32.4 MPLINK Object Linker/

MPLIB Object Librarian

The MPLAB XC Compilers are complete ANSI C

compilers for all of Microchip’s 8, 16, and 32-bit MCU

and DSC devices. These compilers provide powerful

integration capabilities, superior code optimization and

ease of use. MPLAB XC Compilers run on Windows,

Linux or MAC OS X.

The MPLINK Object Linker combines relocatable

objects created by the MPASM Assembler. It can link

relocatable objects from precompiled libraries, using

directives from a linker script.

The MPLIB Object Librarian manages the creation and

modification of library files of precompiled code. When

a routine from a library is called from a source file, only

the modules that contain that routine will be linked in

with the application. This allows large libraries to be

used efficiently in many different applications.

For easy source level debugging, the compilers provide

debug information that is optimized to the MPLAB X

IDE.

The free MPLAB XC Compiler editions support all

devices and commands, with no time or memory

restrictions, and offer sufficient code optimization for

most applications.

The object linker/library features include:

• Efficient linking of single libraries instead of many

smaller files

MPLAB XC Compilers include an assembler, linker and

utilities. The assembler generates relocatable object

files that can then be archived or linked with other relo-

catable object files and archives to create an execut-

able file. MPLAB XC Compiler uses the assembler to

produce its object file. Notable features of the assem-

bler include:

• Enhanced code maintainability by grouping

related modules together

• Flexible creation of libraries with easy module

listing, replacement, deletion and extraction

32.5 MPLAB Assembler, Linker and

Librarian for Various Device

Families

• Support for the entire device instruction set

• Support for fixed-point and floating-point data

• Command-line interface

MPLAB Assembler produces relocatable machine

code from symbolic assembly language for PIC24,

PIC32 and dsPIC DSC devices. MPLAB XC Compiler

uses the assembler to produce its object file. The

assembler generates relocatable object files that can

then be archived or linked with other relocatable object

files and archives to create an executable file. Notable

features of the assembler include:

• Rich directive set

• Flexible macro language

• MPLAB X IDE compatibility

32.3 MPASM Assembler

The MPASM Assembler is a full-featured, universal

macro assembler for PIC10/12/16/18 MCUs.

• Support for the entire device instruction set

• Support for fixed-point and floating-point data

• Command-line interface

The MPASM Assembler generates relocatable object

files for the MPLINK Object Linker, Intel^®standard HEX

files, MAP files to detail memory usage and symbol

reference, absolute LST files that contain source lines

and generated machine code, and COFF files for

debugging.

• Rich directive set

• Flexible macro language

• MPLAB X IDE compatibility

The MPASM Assembler features include:

• Integration into MPLAB X IDE projects

• User-defined macros to streamline

assembly code

• Conditional assembly for multipurpose

source files

• Directives that allow complete control over the

assembly process

 2011-2014 Microchip Technology Inc.

DS40001579E-page 413

PIC16(L)F1782/3

32.6 MPLAB X SIM Software Simulator

32.8 MPLAB ICD 3 In-Circuit Debugger

System

The MPLAB X SIM Software Simulator allows code

development in a PC-hosted environment by simulat-

ing the PIC MCUs and dsPIC DSCs on an instruction

level. On any given instruction, the data areas can be

examined or modified and stimuli can be applied from

a comprehensive stimulus controller. Registers can be

logged to files for further run-time analysis. The trace

buffer and logic analyzer display extend the power of

the simulator to record and track program execution,

actions on I/O, most peripherals and internal registers.

The MPLAB ICD 3 In-Circuit Debugger System is

Microchip’s most cost-effective, high-speed hardware

debugger/programmer for Microchip Flash DSC and

MCU devices. It debugs and programs PIC Flash

microcontrollers and dsPIC DSCs with the powerful,

yet easy-to-use graphical user interface of the MPLAB

IDE.

The MPLAB ICD 3 In-Circuit Debugger probe is

connected to the design engineer’s PC using a high-

speed USB 2.0 interface and is connected to the target

with a connector compatible with the MPLAB ICD 2 or

MPLAB REAL ICE systems (RJ-11). MPLAB ICD 3

supports all MPLAB ICD 2 headers.

The MPLAB X SIM Software Simulator fully supports

symbolic debugging using the MPLAB XC Compilers,

and the MPASM and MPLAB Assemblers. The soft-

ware simulator offers the flexibility to develop and

debug code outside of the hardware laboratory envi-

ronment, making it an excellent, economical software

development tool.

32.9 PICkit 3 In-Circuit Debugger/

Programmer

The MPLAB PICkit 3 allows debugging and program-

ming of PIC and dsPIC Flash microcontrollers at a most

affordable price point using the powerful graphical user

interface of the MPLAB IDE. The MPLAB PICkit 3 is

connected to the design engineer’s PC using a full-

speed USB interface and can be connected to the tar-

get via a Microchip debug (RJ-11) connector (compati-

ble with MPLAB ICD 3 and MPLAB REAL ICE). The

connector uses two device I/O pins and the Reset line

to implement in-circuit debugging and In-Circuit Serial

Programming™ (ICSP™).

32.7 MPLAB REAL ICE In-Circuit

Emulator System

The MPLAB REAL ICE In-Circuit Emulator System is

Microchip’s next generation high-speed emulator for

Microchip Flash DSC and MCU devices. It debugs and

programs all 8, 16 and 32-bit MCU, and DSC devices

with the easy-to-use, powerful graphical user interface of

the MPLAB X IDE.

The emulator is connected to the design engineer’s

PC using a high-speed USB 2.0 interface and is

connected to the target with either a connector

compatible with in-circuit debugger systems (RJ-11)

or with the new high-speed, noise tolerant, Low-

Voltage Differential Signal (LVDS) interconnection

(CAT5).

32.10 MPLAB PM3 Device Programmer

The MPLAB PM3 Device Programmer is a universal,

CE compliant device programmer with programmable

voltage verification at VDDMIN and VDDMAX for

maximum reliability. It features a large LCD display

(128 x 64) for menus and error messages, and a mod-

ular, detachable socket assembly to support various

package types. The ICSP cable assembly is included

as a standard item. In Stand-Alone mode, the MPLAB

PM3 Device Programmer can read, verify and program

PIC devices without a PC connection. It can also set

code protection in this mode. The MPLAB PM3

connects to the host PC via an RS-232 or USB cable.

The MPLAB PM3 has high-speed communications and

optimized algorithms for quick programming of large

memory devices, and incorporates an MMC card for file

storage and data applications.

The emulator is field upgradable through future firmware

downloads in MPLAB X IDE. MPLAB REAL ICE offers

significant advantages over competitive emulators

including full-speed emulation, run-time variable

watches, trace analysis, complex breakpoints, logic

probes, a ruggedized probe interface and long (up to

three meters) interconnection cables.

DS40001579E-page 414

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

32.11 Demonstration/Development

Boards, Evaluation Kits, and

Starter Kits

32.12 Third-Party Development Tools

Microchip also offers a great collection of tools from

third-party vendors. These tools are carefully selected

to offer good value and unique functionality.

A wide variety of demonstration, development and

evaluation boards for various PIC MCUs and dsPIC

DSCs allows quick application development on fully

functional systems. Most boards include prototyping

areas for adding custom circuitry and provide applica-

tion firmware and source code for examination and

modification.

• Device Programmers and Gang Programmers

from companies, such as SoftLog and CCS

• Software Tools from companies, such as Gimpel

and Trace Systems

• Protocol Analyzers from companies, such as

Saleae and Total Phase

The boards support a variety of features, including LEDs,

temperature sensors, switches, speakers, RS-232

interfaces, LCD displays, potentiometers and additional

EEPROM memory.

• Demonstration Boards from companies, such as

MikroElektronika, Digilent^®and Olimex

• Embedded Ethernet Solutions from companies,

such as EZ Web Lynx, WIZnet and IPLogika^®

The demonstration and development boards can be

used in teaching environments, for prototyping custom

circuits and for learning about various microcontroller

applications.

In addition to the PICDEM™ and dsPICDEM™

demonstration/development board series of circuits,

Microchip has a line of evaluation kits and demonstra-

®

tion software for analog filter design, KEELOQ security

ICs, CAN, IrDA^®, PowerSmart battery management,

SEEVAL^®evaluation system, Sigma-Delta ADC, flow

rate sensing, plus many more.

Also available are starter kits that contain everything

needed to experience the specified device. This usually

includes a single application and debug capability, all

on one board.

Check the Microchip web page (www.microchip.com)

for the complete list of demonstration, development

and evaluation kits.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 415

PIC16(L)F1782/3

33.0 PACKAGING INFORMATION

33.1 Package Marking Information

28-Lead SPDIP (.300”)

Example

PIC16F1782

e

3

-I/SP

1204017

28-Lead SOIC (7.50 mm)

Example

PIC16F1782

-I/SO

XXXXXXXXXXXXXXXXXXXX

e

3

1204017

YYWWNNN

28-Lead SSOP (5.30 mm)

Example

PIC16F1782

e

3

-I/SS

1204017

Legend: XX...X Customer-specific information

Y

YY

Year code (last digit of calendar year)

Year code (last 2 digits of calendar year)

WW

NNN

Week code (week of January 1 is week ‘01’)

Alphanumeric traceability code

Pb-free JEDEC^®designator for Matte Tin (Sn)

e

3

*

This package is Pb-free. The Pb-free JEDEC designator (

can be found on the outer packaging for this package.

)

e3

Note: In the event the full Microchip part number cannot be marked on one line, it will

be carried over to the next line, thus limiting the number of available

characters for customer-specific information.

DS40001579E-page 416

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Package Marking Information (Continued)

28-Lead QFN (6x6 mm)

Example

PIN 1

16F1782

XXXXXXXX

YYWWNNN

e

3

-I/ML

120417

28-Lead UQFN (4x4x0.5 mm)

Example

PIC16

LF1782

I/MV

PIN 1

204017

Legend: XX...X Customer-specific information

Y

YY

WW

NNN

Year code (last digit of calendar year)

Year code (last 2 digits of calendar year)

Week code (week of January 1 is week ‘01’)

Alphanumeric traceability code

Pb-free JEDEC^®designator for Matte Tin (Sn)

e

3

*

This package is Pb-free. The Pb-free JEDEC designator (

can be found on the outer packaging for this package.

)

e3

Note: In the event the full Microchip part number cannot be marked on one line, it will

be carried over to the next line, thus limiting the number of available

characters for customer-specific information.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 417

PIC16(L)F1782/3

33.2 Package Details

The following sections give the technical details of the packages.

ꢀꢁꢂꢃꢄꢅꢆꢇꢈꢉꢊꢋꢋꢌꢇꢍꢎꢅꢏꢐꢊꢑꢇꢒꢓꢅꢎꢇꢔꢋꢂꢃꢊꢋꢄꢇꢕꢈꢍꢖꢇMꢇꢗꢘꢘꢇꢙꢊꢎꢇꢚꢛꢆꢌꢇꢜꢈꢍꢒꢔꢍ

!ꢛꢐꢄ" 4ꢊꢈꢄ'ꢌꢇꢄ(ꢊ"'ꢄꢋ#ꢈꢈꢇꢃ'ꢄꢒꢅꢋ5ꢅꢐꢇꢄ$ꢈꢅ+ꢂꢃꢐ")ꢄꢒꢆꢇꢅ"ꢇꢄ"ꢇꢇꢄ'ꢌꢇꢄꢓꢂꢋꢈꢊꢋꢌꢂꢒꢄ ꢅꢋ5ꢅꢐꢂꢃꢐꢄꢏꢒꢇꢋꢂ&ꢂꢋꢅ'ꢂꢊꢃꢄꢆꢊꢋꢅ'ꢇ$ꢄꢅ'ꢄ

ꢌ''ꢒ366+++ꢁ(ꢂꢋꢈꢊꢋꢌꢂꢒꢁꢋꢊ(6ꢒꢅꢋ5ꢅꢐꢂꢃꢐ

N

NOTE 1

E1

1

2 3

D

E

A2

A

L

c

b1

A1

b

e

eB

7ꢃꢂ'"

ꢑꢂ(ꢇꢃ"ꢂꢊꢃꢄ:ꢂ(ꢂ'"

ꢙ8-9/ꢏ

8;ꢓ

ꢍ=

ꢁꢀꢔꢔꢄ2ꢏ-

M

ꢓꢙ8

ꢓꢖ<

8#(*ꢇꢈꢄꢊ&ꢄ ꢂꢃ"

ꢂ'ꢋꢌ

8

ꢇ

ꢖ

ꢘꢊꢒꢄ'ꢊꢄꢏꢇꢅ'ꢂꢃꢐꢄ ꢆꢅꢃꢇ

M

ꢁꢍꢔꢔ

ꢁꢀꢗꢔ

M

ꢓꢊꢆ$ꢇ$ꢄ ꢅꢋ5ꢅꢐꢇꢄꢘꢌꢂꢋ5ꢃꢇ""

2ꢅ"ꢇꢄ'ꢊꢄꢏꢇꢅ'ꢂꢃꢐꢄ ꢆꢅꢃꢇ

ꢏꢌꢊ#ꢆ$ꢇꢈꢄ'ꢊꢄꢏꢌꢊ#ꢆ$ꢇꢈꢄ?ꢂ$'ꢌ

ꢓꢊꢆ$ꢇ$ꢄ ꢅꢋ5ꢅꢐꢇꢄ?ꢂ$'ꢌ

;!ꢇꢈꢅꢆꢆꢄ:ꢇꢃꢐ'ꢌ

ꢘꢂꢒꢄ'ꢊꢄꢏꢇꢅ'ꢂꢃꢐꢄ ꢆꢅꢃꢇ

:ꢇꢅ$ꢄꢘꢌꢂꢋ5ꢃꢇ""

7ꢒꢒꢇꢈꢄ:ꢇꢅ$ꢄ?ꢂ$'ꢌ

ꢖꢍ

ꢖꢀ

/

/ꢀ

ꢑ

:

ꢋ

*ꢀ

*

ꢇ2

ꢁꢀꢍꢔ

ꢁꢔꢀꢗ

ꢁꢍꢚꢔ

ꢁꢍꢕꢔ

ꢀꢁ.ꢕꢗ

ꢁꢀꢀꢔ

ꢁꢔꢔ=

ꢁꢔꢕꢔ

ꢁꢔꢀꢕ

M

ꢁꢀ.ꢗ

M

ꢁ.ꢀꢔ

ꢁꢍ=ꢗ

ꢀꢁ.@ꢗ

ꢁꢀ.ꢔ

ꢁꢔꢀꢔ

ꢁꢔꢗꢔ

ꢁꢔꢀ=

M

ꢁ..ꢗ

ꢁꢍꢚꢗ

ꢀꢁꢕꢔꢔ

ꢁꢀꢗꢔ

ꢁꢔꢀꢗ

ꢁꢔꢛꢔ

ꢁꢔꢍꢍ

ꢁꢕ.ꢔ

:ꢊ+ꢇꢈꢄ:ꢇꢅ$ꢄ?ꢂ$'ꢌ

;!ꢇꢈꢅꢆꢆꢄꢜꢊ+ꢄꢏꢒꢅꢋꢂꢃꢐꢄꢄꢎ

!ꢛꢐꢄꢏ"

ꢀꢁ ꢂꢃꢄꢀꢄ!ꢂ"#ꢅꢆꢄꢂꢃ$ꢇ%ꢄ&ꢇꢅ'#ꢈꢇꢄ(ꢅꢉꢄ!ꢅꢈꢉ)ꢄ*#'ꢄ(#"'ꢄ*ꢇꢄꢆꢊꢋꢅ'ꢇ$ꢄ+ꢂ'ꢌꢂꢃꢄ'ꢌꢇꢄꢌꢅ'ꢋꢌꢇ$ꢄꢅꢈꢇꢅꢁ

ꢍꢁ ꢎꢄꢏꢂꢐꢃꢂ&ꢂꢋꢅꢃ'ꢄ-ꢌꢅꢈꢅꢋ'ꢇꢈꢂ"'ꢂꢋꢁ

.ꢁ ꢑꢂ(ꢇꢃ"ꢂꢊꢃ"ꢄꢑꢄꢅꢃ$ꢄ/ꢀꢄ$ꢊꢄꢃꢊ'ꢄꢂꢃꢋꢆ#$ꢇꢄ(ꢊꢆ$ꢄ&ꢆꢅ"ꢌꢄꢊꢈꢄꢒꢈꢊ'ꢈ#"ꢂꢊꢃ"ꢁꢄꢓꢊꢆ$ꢄ&ꢆꢅ"ꢌꢄꢊꢈꢄꢒꢈꢊ'ꢈ#"ꢂꢊꢃ"ꢄ"ꢌꢅꢆꢆꢄꢃꢊ'ꢄꢇ%ꢋꢇꢇ$ꢄꢁꢔꢀꢔ0ꢄꢒꢇꢈꢄ"ꢂ$ꢇꢁ

ꢕꢁ ꢑꢂ(ꢇꢃ"ꢂꢊꢃꢂꢃꢐꢄꢅꢃ$ꢄ'ꢊꢆꢇꢈꢅꢃꢋꢂꢃꢐꢄꢒꢇꢈꢄꢖꢏꢓ/ꢄ1ꢀꢕꢁꢗꢓꢁ

2ꢏ-3 2ꢅ"ꢂꢋꢄꢑꢂ(ꢇꢃ"ꢂꢊꢃꢁꢄꢘꢌꢇꢊꢈꢇ'ꢂꢋꢅꢆꢆꢉꢄꢇ%ꢅꢋ'ꢄ!ꢅꢆ#ꢇꢄ"ꢌꢊ+ꢃꢄ+ꢂ'ꢌꢊ#'ꢄ'ꢊꢆꢇꢈꢅꢃꢋꢇ"ꢁ

ꢓꢂꢋꢈꢊꢋꢌꢂꢒ ꢘꢇꢋꢌꢃꢊꢆꢊꢐꢉ ꢑꢈꢅ+ꢂꢃꢐ -ꢔꢕꢝꢔꢛꢔ2

DS40001579E-page 418

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: For the most current package drawings, please see the Microchip Packaging Specification located at

http://www.microchip.com/packaging

 2011-2014 Microchip Technology Inc.

DS40001579E-page 419

PIC16(L)F1782/3

Note: For the most current package drawings, please see the Microchip Packaging Specification located at

http://www.microchip.com/packaging

DS40001579E-page 420

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: For the most current package drawings, please see the Microchip Packaging Specification located at

http://www.microchip.com/packaging

 2011-2014 Microchip Technology Inc.

DS40001579E-page 421

PIC16(L)F1782/3

ꢀꢁꢂꢃꢄꢅꢆꢇꢍꢎꢅꢏꢐꢊꢑꢇꢈ#$ꢊꢋꢉꢇꢈꢙꢅꢎꢎꢇ%ꢓꢐꢎꢊꢋꢄꢇꢕꢈꢈꢖꢇMꢇ&'ꢗꢘꢇꢙꢙꢇꢚꢛꢆꢌꢇꢜꢈꢈ%ꢍ

!ꢛꢐꢄ" 4ꢊꢈꢄ'ꢌꢇꢄ(ꢊ"'ꢄꢋ#ꢈꢈꢇꢃ'ꢄꢒꢅꢋ5ꢅꢐꢇꢄ$ꢈꢅ+ꢂꢃꢐ")ꢄꢒꢆꢇꢅ"ꢇꢄ"ꢇꢇꢄ'ꢌꢇꢄꢓꢂꢋꢈꢊꢋꢌꢂꢒꢄ ꢅꢋ5ꢅꢐꢂꢃꢐꢄꢏꢒꢇꢋꢂ&ꢂꢋꢅ'ꢂꢊꢃꢄꢆꢊꢋꢅ'ꢇ$ꢄꢅ'ꢄ

ꢌ''ꢒ366+++ꢁ(ꢂꢋꢈꢊꢋꢌꢂꢒꢁꢋꢊ(6ꢒꢅꢋ5ꢅꢐꢂꢃꢐ

D

N

E

E1

1

2

b

NOTE 1

e

c

A2

A

φ

A1

L

L1

7ꢃꢂ'"

ꢓꢙ::ꢙꢓ/ꢘ/ꢜꢏ

ꢑꢂ(ꢇꢃ"ꢂꢊꢃꢄ:ꢂ(ꢂ'"

ꢓꢙ8

8;ꢓ

ꢓꢖ<

8#(*ꢇꢈꢄꢊ&ꢄ ꢂꢃ"

ꢂ'ꢋꢌ

8

ꢇ

ꢍ=

ꢔꢁ@ꢗꢄ2ꢏ-

;!ꢇꢈꢅꢆꢆꢄ9ꢇꢂꢐꢌ'

ꢓꢊꢆ$ꢇ$ꢄ ꢅꢋ5ꢅꢐꢇꢄꢘꢌꢂꢋ5ꢃꢇ""

ꢏ'ꢅꢃ$ꢊ&&ꢄ

;!ꢇꢈꢅꢆꢆꢄ?ꢂ$'ꢌ

ꢓꢊꢆ$ꢇ$ꢄ ꢅꢋ5ꢅꢐꢇꢄ?ꢂ$'ꢌ

;!ꢇꢈꢅꢆꢆꢄ:ꢇꢃꢐ'ꢌ

4ꢊꢊ'ꢄ:ꢇꢃꢐ'ꢌ

4ꢊꢊ'ꢒꢈꢂꢃ'

:ꢇꢅ$ꢄꢘꢌꢂꢋ5ꢃꢇ""

4ꢊꢊ'ꢄꢖꢃꢐꢆꢇ

ꢖ

M

ꢀꢁꢛꢗ

M

ꢛꢁ=ꢔ

ꢗꢁ.ꢔ

ꢀꢔꢁꢍꢔ

ꢔꢁꢛꢗ

ꢀꢁꢍꢗꢄꢜ/4

M

ꢍꢁꢔꢔ

ꢀꢁ=ꢗ

M

=ꢁꢍꢔ

ꢗꢁ@ꢔ

ꢀꢔꢁꢗꢔ

ꢔꢁꢚꢗ

ꢖꢍ

ꢖꢀ

/

/ꢀ

ꢑ

:

:ꢀ

ꢋ

ꢀꢁ@ꢗ

ꢔꢁꢔꢗ

ꢛꢁꢕꢔ

ꢗꢁꢔꢔ

ꢚꢁꢚꢔ

ꢔꢁꢗꢗ

ꢔꢁꢔꢚ

ꢔꢞ

ꢔꢁꢍꢗ

=ꢞ

ꢀ

ꢕꢞ

:ꢇꢅ$ꢄ?ꢂ$'ꢌ

*

ꢔꢁꢍꢍ

M

ꢔꢁ.=

!ꢛꢐꢄꢏ"

ꢀꢁ ꢂꢃꢄꢀꢄ!ꢂ"#ꢅꢆꢄꢂꢃ$ꢇ%ꢄ&ꢇꢅ'#ꢈꢇꢄ(ꢅꢉꢄ!ꢅꢈꢉ)ꢄ*#'ꢄ(#"'ꢄ*ꢇꢄꢆꢊꢋꢅ'ꢇ$ꢄ+ꢂ'ꢌꢂꢃꢄ'ꢌꢇꢄꢌꢅ'ꢋꢌꢇ$ꢄꢅꢈꢇꢅꢁ

ꢍꢁ ꢑꢂ(ꢇꢃ"ꢂꢊꢃ"ꢄꢑꢄꢅꢃ$ꢄ/ꢀꢄ$ꢊꢄꢃꢊ'ꢄꢂꢃꢋꢆ#$ꢇꢄ(ꢊꢆ$ꢄ&ꢆꢅ"ꢌꢄꢊꢈꢄꢒꢈꢊ'ꢈ#"ꢂꢊꢃ"ꢁꢄꢓꢊꢆ$ꢄ&ꢆꢅ"ꢌꢄꢊꢈꢄꢒꢈꢊ'ꢈ#"ꢂꢊꢃ"ꢄ"ꢌꢅꢆꢆꢄꢃꢊ'ꢄꢇ%ꢋꢇꢇ$ꢄꢔꢁꢍꢔꢄ((ꢄꢒꢇꢈꢄ"ꢂ$ꢇꢁ

.ꢁ ꢑꢂ(ꢇꢃ"ꢂꢊꢃꢂꢃꢐꢄꢅꢃ$ꢄ'ꢊꢆꢇꢈꢅꢃꢋꢂꢃꢐꢄꢒꢇꢈꢄꢖꢏꢓ/ꢄ1ꢀꢕꢁꢗꢓꢁ

2ꢏ-3 2ꢅ"ꢂꢋꢄꢑꢂ(ꢇꢃ"ꢂꢊꢃꢁꢄꢘꢌꢇꢊꢈꢇ'ꢂꢋꢅꢆꢆꢉꢄꢇ%ꢅꢋ'ꢄ!ꢅꢆ#ꢇꢄ"ꢌꢊ+ꢃꢄ+ꢂ'ꢌꢊ#'ꢄ'ꢊꢆꢇꢈꢅꢃꢋꢇ"ꢁ

ꢜ/43 ꢜꢇ&ꢇꢈꢇꢃꢋꢇꢄꢑꢂ(ꢇꢃ"ꢂꢊꢃ)ꢄ#"#ꢅꢆꢆꢉꢄ+ꢂ'ꢌꢊ#'ꢄ'ꢊꢆꢇꢈꢅꢃꢋꢇ)ꢄ&ꢊꢈꢄꢂꢃ&ꢊꢈ(ꢅ'ꢂꢊꢃꢄꢒ#ꢈꢒꢊ"ꢇ"ꢄꢊꢃꢆꢉꢁ

ꢓꢂꢋꢈꢊꢋꢌꢂꢒ ꢘꢇꢋꢌꢃꢊꢆꢊꢐꢉ ꢑꢈꢅ+ꢂꢃꢐ -ꢔꢕꢝꢔꢛ.2

DS40001579E-page 422

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: For the most current package drawings, please see the Microchip Packaging Specification located at

http://www.microchip.com/packaging

 2011-2014 Microchip Technology Inc.

DS40001579E-page 423

PIC16(L)F1782/3

ꢀꢁꢂꢃꢄꢅꢆꢇꢍꢎꢅꢏꢐꢊꢑꢇ(ꢓꢅꢆꢇ)ꢎꢅꢐ*ꢇ!ꢛꢇꢃꢄꢅꢆꢇꢍꢅꢑꢉꢅ+ꢄꢇꢕ,ꢃꢖꢇMꢇ-.-ꢇꢙꢙꢇꢚꢛꢆꢌꢇꢜ()!

/ꢊꢐ#ꢇꢘ'&&ꢇꢙꢙꢇ0ꢛꢋꢐꢅꢑꢐꢇꢃꢄꢋ+ꢐ#

!ꢛꢐꢄ" 4ꢊꢈꢄ'ꢌꢇꢄ(ꢊ"'ꢄꢋ#ꢈꢈꢇꢃ'ꢄꢒꢅꢋ5ꢅꢐꢇꢄ$ꢈꢅ+ꢂꢃꢐ")ꢄꢒꢆꢇꢅ"ꢇꢄ"ꢇꢇꢄ'ꢌꢇꢄꢓꢂꢋꢈꢊꢋꢌꢂꢒꢄ ꢅꢋ5ꢅꢐꢂꢃꢐꢄꢏꢒꢇꢋꢂ&ꢂꢋꢅ'ꢂꢊꢃꢄꢆꢊꢋꢅ'ꢇ$ꢄꢅ'ꢄ

ꢌ''ꢒ366+++ꢁ(ꢂꢋꢈꢊꢋꢌꢂꢒꢁꢋꢊ(6ꢒꢅꢋ5ꢅꢐꢂꢃꢐ

D

D2

EXPOSED

PAD

e

E

b

E2

2

1

2

1

K

N

NOTE 1

L

BOTTOM VIEW

TOP VIEW

A

A3

A1

7ꢃꢂ'"

ꢑꢂ(ꢇꢃ"ꢂꢊꢃꢄ:ꢂ(ꢂ'"

ꢓꢙ::ꢙꢓ/ꢘ/ꢜꢏ

8;ꢓ

ꢓꢙ8

ꢓꢖ<

8#(*ꢇꢈꢄꢊ&ꢄ ꢂꢃ"

ꢂ'ꢋꢌ

;!ꢇꢈꢅꢆꢆꢄ9ꢇꢂꢐꢌ'

ꢏ'ꢅꢃ$ꢊ&&ꢄ

-ꢊꢃ'ꢅꢋ'ꢄꢘꢌꢂꢋ5ꢃꢇ""

;!ꢇꢈꢅꢆꢆꢄ?ꢂ$'ꢌ

/%ꢒꢊ"ꢇ$ꢄ ꢅ$ꢄ?ꢂ$'ꢌ

;!ꢇꢈꢅꢆꢆꢄ:ꢇꢃꢐ'ꢌ

/%ꢒꢊ"ꢇ$ꢄ ꢅ$ꢄ:ꢇꢃꢐ'ꢌ

-ꢊꢃ'ꢅꢋ'ꢄ?ꢂ$'ꢌ

-ꢊꢃ'ꢅꢋ'ꢄ:ꢇꢃꢐ'ꢌ

-ꢊꢃ'ꢅꢋ'ꢝ'ꢊꢝ/%ꢒꢊ"ꢇ$ꢄ ꢅ$

8

ꢇ

ꢖ

ꢖꢀ

ꢖ.

/

/ꢍ

ꢑ

ꢍ=

ꢔꢁ@ꢗꢄ2ꢏ-

ꢔꢁꢚꢔ

ꢔꢁ=ꢔ

ꢔꢁꢔꢔ

ꢀꢁꢔꢔ

ꢔꢁꢔꢗ

ꢔꢁꢔꢍ

ꢔꢁꢍꢔꢄꢜ/4

@ꢁꢔꢔꢄ2ꢏ-

.ꢁꢛꢔ

@ꢁꢔꢔꢄ2ꢏ-

.ꢁꢛꢔ

ꢔꢁ.ꢔ

ꢔꢁꢗꢗ

M

.ꢁ@ꢗ

ꢕꢁꢍꢔ

ꢑꢍ

*

:

.ꢁ@ꢗ

ꢔꢁꢍ.

ꢔꢁꢗꢔ

ꢔꢁꢍꢔ

ꢕꢁꢍꢔ

ꢔꢁ.ꢗ

ꢔꢁꢛꢔ

M

B

!ꢛꢐꢄꢏ"

ꢀꢁ ꢂꢃꢄꢀꢄ!ꢂ"#ꢅꢆꢄꢂꢃ$ꢇ%ꢄ&ꢇꢅ'#ꢈꢇꢄ(ꢅꢉꢄ!ꢅꢈꢉ)ꢄ*#'ꢄ(#"'ꢄ*ꢇꢄꢆꢊꢋꢅ'ꢇ$ꢄ+ꢂ'ꢌꢂꢃꢄ'ꢌꢇꢄꢌꢅ'ꢋꢌꢇ$ꢄꢅꢈꢇꢅꢁ

ꢍꢁ ꢅꢋ5ꢅꢐꢇꢄꢂ"ꢄ"ꢅ+ꢄ"ꢂꢃꢐ#ꢆꢅ'ꢇ$ꢁ

.ꢁ ꢑꢂ(ꢇꢃ"ꢂꢊꢃꢂꢃꢐꢄꢅꢃ$ꢄ'ꢊꢆꢇꢈꢅꢃꢋꢂꢃꢐꢄꢒꢇꢈꢄꢖꢏꢓ/ꢄ1ꢀꢕꢁꢗꢓꢁ

2ꢏ-3 2ꢅ"ꢂꢋꢄꢑꢂ(ꢇꢃ"ꢂꢊꢃꢁꢄꢘꢌꢇꢊꢈꢇ'ꢂꢋꢅꢆꢆꢉꢄꢇ%ꢅꢋ'ꢄ!ꢅꢆ#ꢇꢄ"ꢌꢊ+ꢃꢄ+ꢂ'ꢌꢊ#'ꢄ'ꢊꢆꢇꢈꢅꢃꢋꢇ"ꢁ

ꢜ/43 ꢜꢇ&ꢇꢈꢇꢃꢋꢇꢄꢑꢂ(ꢇꢃ"ꢂꢊꢃ)ꢄ#"#ꢅꢆꢆꢉꢄ+ꢂ'ꢌꢊ#'ꢄ'ꢊꢆꢇꢈꢅꢃꢋꢇ)ꢄ&ꢊꢈꢄꢂꢃ&ꢊꢈ(ꢅ'ꢂꢊꢃꢄꢒ#ꢈꢒꢊ"ꢇ"ꢄꢊꢃꢆꢉꢁ

ꢓꢂꢋꢈꢊꢋꢌꢂꢒ ꢘꢇꢋꢌꢃꢊꢆꢊꢐꢉ ꢑꢈꢅ+ꢂꢃꢐ -ꢔꢕꢝꢀꢔꢗ2

DS40001579E-page 424

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

ꢀꢁꢂꢃꢄꢅꢆꢇꢍꢎꢅꢏꢐꢊꢑꢇ(ꢓꢅꢆꢇ)ꢎꢅꢐ*ꢇ!ꢛꢇꢃꢄꢅꢆꢇꢍꢅꢑꢉꢅ+ꢄꢇꢕ,ꢃꢖꢇMꢇ-.-ꢇꢙꢙꢇꢚꢛꢆꢌꢇꢜ()!

/ꢊꢐ#ꢇꢘ'&&ꢇꢙꢙꢇ0ꢛꢋꢐꢅꢑꢐꢇꢃꢄꢋ+ꢐ#

!ꢛꢐꢄ" 4ꢊꢈꢄ'ꢌꢇꢄ(ꢊ"'ꢄꢋ#ꢈꢈꢇꢃ'ꢄꢒꢅꢋ5ꢅꢐꢇꢄ$ꢈꢅ+ꢂꢃꢐ")ꢄꢒꢆꢇꢅ"ꢇꢄ"ꢇꢇꢄ'ꢌꢇꢄꢓꢂꢋꢈꢊꢋꢌꢂꢒꢄ ꢅꢋ5ꢅꢐꢂꢃꢐꢄꢏꢒꢇꢋꢂ&ꢂꢋꢅ'ꢂꢊꢃꢄꢆꢊꢋꢅ'ꢇ$ꢄꢅ'ꢄ

ꢌ''ꢒ366+++ꢁ(ꢂꢋꢈꢊꢋꢌꢂꢒꢁꢋꢊ(6ꢒꢅꢋ5ꢅꢐꢂꢃꢐ

 2011-2014 Microchip Technology Inc.

DS40001579E-page 425

PIC16(L)F1782/3

Note: For the most current package drawings, please see the Microchip Packaging Specification located at

http://www.microchip.com/packaging

DS40001579E-page 426

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

Note: For the most current package drawings, please see the Microchip Packaging Specification located at

http://www.microchip.com/packaging

 2011-2014 Microchip Technology Inc.

DS40001579E-page 427

PIC16(L)F1782/3

DS40001579E-page 428

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

APPENDIX A: DATA SHEET

REVISION HISTORY

Revision A (04/2011)

Original release.

Revision B (06/2011)

Revised Section 18.0; Revised Table 30-8; Add

Operational Amplifier Table.

Revision C (03/2012)

Electrical Specifications update.

Revision D (11/2012)

Revised: Table 5-4, Section 6.2.1.3, 9.0, Table 15-1

(LDO), Figure 16-1, Section 17.1.6, 17.2.3, 20.7, 24.1,

24.1.1-24.1.3, 24.2.7, 24.2.8, 24.3.4.1, 24.3.11,

24.8.1.1-24.8.1.3; Register 24.2 (PxMSRC descrip-

tion); Registers 24-9-24-13, 24-16, 25-1 (Bits 0-3

descriptions); Add Table 16-2, Section 24.2.7.3.

Electrical Specifications update: Revised 30.2 (D010,

D012), 30.3 (D023, D025, D026, D029-D031); Table

30-4 (delete Note 2); Table 30-1 (Param. OPA08,

OPA09), Table 30-11, Table 30-12 (Param. DAC02).

Revision E (3/2014)

Change from Preliminary to Final data sheet.

Corrected the following Tables: Family Types Table on

page 3, Table 3-3, Table 3-8, Table 20-3, Table 22-2,

Table 22-3, Table 23-1, Table 25-3, Table 30-1, Table

30-2, Table 30-3, Table 30-6, Table 30-7, Table 30-13,

Table 30-14, Table 30-15, Table 30-16, Table 30-20.

Corrected the following Sections: Section 3.2, Section

9.2, Section 13.3, Section 17.1.6, Section 15.1, Section

15.3, Section 17.2.5, Section 18.2, Section 18.3, Sec-

tion 19.0, Section 22.6.5, Section 22.9, Section 23.0,

Section 23.1, Section 24.2.4, Section 24.2.5, Section

24.2.7, Section 24.8, Section 25.0, Section 26.6.7.4,

Section 30.3.

Corrected the following Registers: Register 4-2, Regis-

ter 8-2, Register 8-5, Register 17-3, Register 18-1,

Register 24-3, Register 24-4.

Corrected Equation 17-1.

Corrected Figure 30-9. Removed Figure 24-21.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 429

PIC16(L)F1782/3

THE MICROCHIP WEB SITE

CUSTOMER SUPPORT

Microchip provides online support via our WWW site at

www.microchip.com. This web site is used as a means

to make files and information easily available to

customers. Accessible by using your favorite Internet

browser, the web site contains the following

information:

Users of Microchip products can receive assistance

through several channels:

• Distributor or Representative

• Local Sales Office

• Field Application Engineer (FAE)

• Technical Support

• Product Support – Data sheets and errata,

application notes and sample programs, design

resources, user’s guides and hardware support

documents, latest software releases and archived

software

Customers

should

contact

their

distributor,

representative or Field Application Engineer (FAE) for

support. Local sales offices are also available to help

customers. A listing of sales offices and locations is

included in the back of this document.

• General Technical Support – Frequently Asked

Questions (FAQ), technical support requests,

online discussion groups, Microchip consultant

program member listing

Technical support is available through the web site

at: http://microchip.com/support

• Business of Microchip – Product selector and

ordering guides, latest Microchip press releases,

listing of seminars and events, listings of

Microchip sales offices, distributors and factory

representatives

CUSTOMER CHANGE NOTIFICATION

SERVICE

Microchip’s customer notification service helps keep

customers current on Microchip products. Subscribers

will receive e-mail notification whenever there are

changes, updates, revisions or errata related to a

specified product family or development tool of interest.

To register, access the Microchip web site at

www.microchip.com. Under “Support”, click on

“Customer Change Notification” and follow the

registration instructions.

DS40001579E-page 430

 2011-2014 Microchip Technology Inc.

PIC16(L)F1782/3

PRODUCT IDENTIFICATION SYSTEM

To order or obtain information, e.g., on pricing or delivery, refer to the factory or the listed sales office.

(1)

[X]

PART NO.

X

/XX

XXX

-

Examples:

Device Tape and Reel

Option

Temperature

Range

Package

Pattern

a)

PIC16LF1782T- I/MV 301

Tape and Reel,

Industrial temperature,

UQFN package,

QTP pattern #301

b)

c)

PIC16LF1783- I/P

Industrial temperature

SPDIP package

Device:

PIC16F1782, PIC16LF1782,

PIC16F1783, PIC16LF1783

PIC16F1783- E/SS

Extended temperature,

SSOP package

Tape and Reel

Option:

Blank = Standard packaging (tube or tray)

T

= Tape and Reel⁽¹⁾

Temperature

Range:

I

E

=

-40C to +85C (Industrial)

-40C to +125C (Extended)

Package:

ML

MV

SP

SO

SS

= QFN

= UQFN

= SPDIP

= SOIC

= SSOP

Note 1:

Tape and Reel identifier only appears in

the catalog part number description. This

identifier is used for ordering purposes and

is not printed on the device package.

Check with your Microchip Sales Office

for package availability with the Tape and

Reel option.

Pattern:

QTP, SQTP, Code or Special Requirements

(blank otherwise)

2:

Small form-factor packaging options may

be available. Please check

www.microchip.com/packaging for

small-form factor package availability, or

contact your local Sales Office.

 2011-2014 Microchip Technology Inc.

DS40001579E-page 431

PIC16(L)F1782/3

NOTES:

DS40001579E-page 432

 2011-2014 Microchip Technology Inc.

Note the following details of the code protection feature on Microchip devices:

•

Microchip products meet the specification contained in their particular Microchip Data Sheet.

•

Microchip believes that its family of products is one of the most secure families of its kind on the market today, when used in the

intended manner and under normal conditions.

•

There are dishonest and possibly illegal methods used to breach the code protection feature. All of these methods, to our

knowledge, require using the Microchip products in a manner outside the operating specifications contained in Microchip’s Data

Sheets. Most likely, the person doing so is engaged in theft of intellectual property.

•

Microchip is willing to work with the customer who is concerned about the integrity of their code.

Neither Microchip nor any other semiconductor manufacturer can guarantee the security of their code. Code protection does not

mean that we are guaranteeing the product as “unbreakable.”

Code protection is constantly evolving. We at Microchip are committed to continuously improving the code protection features of our

products. Attempts to break Microchip’s code protection feature may be a violation of the Digital Millennium Copyright Act. If such acts

allow unauthorized access to your software or other copyrighted work, you may have a right to sue for relief under that Act.

Information contained in this publication regarding device

applications and the like is provided only for your convenience

and may be superseded by updates. It is your responsibility to

ensure that your application meets with your specifications.

MICROCHIP MAKES NO REPRESENTATIONS OR

WARRANTIES OF ANY KIND WHETHER EXPRESS OR

IMPLIED, WRITTEN OR ORAL, STATUTORY OR

OTHERWISE, RELATED TO THE INFORMATION,

INCLUDING BUT NOT LIMITED TO ITS CONDITION,

QUALITY, PERFORMANCE, MERCHANTABILITY OR

FITNESS FOR PURPOSE. Microchip disclaims all liability

arising from this information and its use. Use of Microchip

devices in life support and/or safety applications is entirely at

the buyer’s risk, and the buyer agrees to defend, indemnify and

hold harmless Microchip from any and all damages, claims,

suits, or expenses resulting from such use. No licenses are

conveyed, implicitly or otherwise, under any Microchip

intellectual property rights.

Trademarks

The Microchip name and logo, the Microchip logo, dsPIC,

FlashFlex, KEELOQ, KEELOQ logo, MPLAB, PIC, PICmicro,

PICSTART, PIC³²logo, rfPIC, SST, SST Logo, SuperFlash

and UNI/O are registered trademarks of Microchip Technology

Incorporated in the U.S.A. and other countries.

FilterLab, Hampshire, HI-TECH C, Linear Active Thermistor,

MTP, SEEVAL and The Embedded Control Solutions

Company are registered trademarks of Microchip Technology

Incorporated in the U.S.A.

Silicon Storage Technology is a registered trademark of

Microchip Technology Inc. in other countries.

Analog-for-the-Digital Age, Application Maestro, BodyCom,

chipKIT, chipKIT logo, CodeGuard, dsPICDEM,

dsPICDEM.net, dsPICworks, dsSPEAK, ECAN,

ECONOMONITOR, FanSense, HI-TIDE, In-Circuit Serial

Programming, ICSP, Mindi, MiWi, MPASM, MPF, MPLAB

Certified logo, MPLIB, MPLINK, mTouch, Omniscient Code

Generation, PICC, PICC-18, PICDEM, PICDEM.net, PICkit,

PICtail, REAL ICE, rfLAB, Select Mode, SQI, Serial Quad I/O,

Total Endurance, TSHARC, UniWinDriver, WiperLock, ZENA

and Z-Scale are trademarks of Microchip Technology

Incorporated in the U.S.A. and other countries.

SQTP is a service mark of Microchip Technology Incorporated

in the U.S.A.

GestIC and ULPP are registered trademarks of Microchip

Technology Germany II GmbH & Co. KG, a subsidiary of

Microchip Technology Inc., in other countries.

All other trademarks mentioned herein are property of their

respective companies.

Printed on recycled paper.

ISBN: 978-1-63276-249-8

QUALITY MANAGEMENT SYSTEM

CERTIFIED BY DNV

Microchip received ISO/TS-16949:2009 certification for its worldwide

headquarters, design and wafer fabrication facilities in Chandler and

Tempe, Arizona; Gresham, Oregon and design centers in California

and India. The Company’s quality system processes and procedures

are for its PIC^®MCUs and dsPIC^®DSCs, KEELOQ^®code hopping

devices, Serial EEPROMs, microperipherals, nonvolatile memory and

analog products. In addition, Microchip’s quality system for the design

and manufacture of development systems is ISO 9001:2000 certified.

== ISO/TS 16949 ==

 2011-2014 Microchip Technology Inc.

DS40001579E-page 433

Worldwide Sales and Service

AMERICAS

ASIA/PACIFIC

EUROPE

Corporate Office

2355 West Chandler Blvd.

Chandler, AZ 85224-6199

Tel: 480-792-7200

Fax: 480-792-7277

Technical Support:

http://www.microchip.com/

support

Asia Pacific Office

Suites 3707-14, 37th Floor

Tower 6, The Gateway

Harbour City, Kowloon

Hong Kong

Tel: 852-2943-5100

Fax: 852-2401-3431

India - Bangalore

Tel: 91-80-3090-4444

Fax: 91-80-3090-4123

Austria - Wels

Tel: 43-7242-2244-39

Fax: 43-7242-2244-393

Denmark - Copenhagen

Tel: 45-4450-2828

Fax: 45-4485-2829

India - New Delhi

Tel: 91-11-4160-8631

Fax: 91-11-4160-8632

France - Paris

Tel: 33-1-69-53-63-20

Fax: 33-1-69-30-90-79

India - Pune

Tel: 91-20-3019-1500

Australia - Sydney

Tel: 61-2-9868-6733

Fax: 61-2-9868-6755

Web Address:

www.microchip.com

Japan - Osaka

Tel: 81-6-6152-7160

Fax: 81-6-6152-9310

Germany - Dusseldorf

Tel: 49-2129-3766400

Atlanta

Duluth, GA

Tel: 678-957-9614

Fax: 678-957-1455

China - Beijing

Tel: 86-10-8569-7000

Fax: 86-10-8528-2104

Germany - Munich

Tel: 49-89-627-144-0

Fax: 49-89-627-144-44

Japan - Tokyo

Tel: 81-3-6880- 3770

Fax: 81-3-6880-3771

China - Chengdu

Tel: 86-28-8665-5511

Fax: 86-28-8665-7889

Austin, TX

Tel: 512-257-3370

Germany - Pforzheim

Tel: 49-7231-424750

Korea - Daegu

Tel: 82-53-744-4301

Fax: 82-53-744-4302

Boston

China - Chongqing

Tel: 86-23-8980-9588

Fax: 86-23-8980-9500

Italy - Milan

Tel: 39-0331-742611

Fax: 39-0331-466781

Westborough, MA

Tel: 774-760-0087

Fax: 774-760-0088

Korea - Seoul

Tel: 82-2-554-7200

Fax: 82-2-558-5932 or

82-2-558-5934

China - Hangzhou

Tel: 86-571-8792-8115

Fax: 86-571-8792-8116

Italy - Venice

Tel: 39-049-7625286

Chicago

Itasca, IL

Tel: 630-285-0071

Fax: 630-285-0075

Netherlands - Drunen

Tel: 31-416-690399

Fax: 31-416-690340

Malaysia - Kuala Lumpur

Tel: 60-3-6201-9857

Fax: 60-3-6201-9859

China - Hong Kong SAR

Tel: 852-2943-5100

Fax: 852-2401-3431

Cleveland

Independence, OH

Tel: 216-447-0464

Fax: 216-447-0643

Poland - Warsaw

Tel: 48-22-3325737

Malaysia - Penang

Tel: 60-4-227-8870

Fax: 60-4-227-4068

China - Nanjing

Tel: 86-25-8473-2460

Fax: 86-25-8473-2470

Spain - Madrid

Tel: 34-91-708-08-90

Fax: 34-91-708-08-91

Dallas

Addison, TX

Tel: 972-818-7423

Fax: 972-818-2924

Philippines - Manila

Tel: 63-2-634-9065

Fax: 63-2-634-9069

China - Qingdao

Tel: 86-532-8502-7355

Fax: 86-532-8502-7205

Sweden - Stockholm

Tel: 46-8-5090-4654

Singapore

Tel: 65-6334-8870

Fax: 65-6334-8850

Detroit

Novi, MI

Tel: 248-848-4000

China - Shanghai

Tel: 86-21-5407-5533

Fax: 86-21-5407-5066

UK - Wokingham

Tel: 44-118-921-5800

Fax: 44-118-921-5820

Taiwan - Hsin Chu

Tel: 886-3-5778-366

Fax: 886-3-5770-955

Houston, TX

Tel: 281-894-5983

China - Shenyang

Tel: 86-24-2334-2829

Fax: 86-24-2334-2393

Indianapolis

Noblesville, IN

Tel: 317-773-8323

Fax: 317-773-5453

Taiwan - Kaohsiung

Tel: 886-7-213-7830

China - Shenzhen

Tel: 86-755-8864-2200

Fax: 86-755-8203-1760

Taiwan - Taipei

Tel: 886-2-2508-8600

Fax: 886-2-2508-0102

Los Angeles

China - Wuhan

Tel: 86-27-5980-5300

Fax: 86-27-5980-5118

Mission Viejo, CA

Tel: 949-462-9523

Fax: 949-462-9608

Thailand - Bangkok

Tel: 66-2-694-1351

Fax: 66-2-694-1350

China - Xian

Tel: 86-29-8833-7252

Fax: 86-29-8833-7256

New York, NY

Tel: 631-435-6000

San Jose, CA

Tel: 408-735-9110

China - Xiamen

Tel: 86-592-2388138

Fax: 86-592-2388130

Canada - Toronto

Tel: 905-673-0699

Fax: 905-673-6509

China - Zhuhai

Tel: 86-756-3210040

Fax: 86-756-3210049

03/25/14

DS40001579E-page 434

 2011-2014 Microchip Technology Inc.


型号：	PIC16LF1782T-E/ML
厂家：	MICROCHIP
描述：	RISC MICROCONTROLLER
文件：	总434页 (文件大小：6461K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

PIC16LF1782T-E/ML [MICROCHIP]

相关型号：

PIC16LF1782T-I/ML

PIC16LF1782T-I/SO

PIC16LF1783

PIC16LF1783-E/SP

PIC16LF1783-E/SS

PIC16LF1783-I/SO

PIC16LF1783-I/SP

PIC16LF1784

PIC16LF1786

PIC16LF1787

PIC16LF1788

PIC16LF1789