CY7C63101A-QXC_技术文档

CY7C63001A

CY7C63101A

Universal Serial Bus Microcontroller

—Integrated USB transceiver

1.0

Features

—Up to 16 Schmitt trigger I/O pins with internal pull-up

• Low-cost solution for low-speed USB peripherals such

as mouse, joystick, and gamepad

—Up to eight I/O pins with LED drive capability

• USB Specification Compliance

—Special purpose I/O mode supports optimization of

photo transistor and LED in mouse application

— Conforms to USB 1.5-Mbps Specification,

Version 1.1

—Maskable Interrupts on all I/O pins

• 8-bit free-running timer

— Supports one device address and two endpoints

(one control endpoint and one data endpoint)

• Watchdog timer (WDT)

• 8-bit RISC microcontroller

— Harvard architecture

• Internal power-on reset (POR)

• Instant-On Now™ for Suspend and Periodic Wake-up

Modes

— 6-MHz external ceramic resonator

— 12-MHz internal operation

— USB optimized instruction set

• Internal memory

• Improved output drivers to reduce EMI

• Operating voltage from 4.0V to 5.25 VDC

• Operating temperature from 0–70°C

• Available in space saving and low-cost 20-pin PDIP,

20-pin SOIC, and 24-pin QSOP packages

— 128 bytes of RAM

— 4 Kbytes of EPROM

• Industry-standard programmer support

Logic Block Diagram

6-MHz

CERAMIC RESONATOR

R/C_EXT

OSC

INSTANT-ON

NOW™

RAM

128-Byte

8-bit

Timer

8-bit

RISC

core

EPROM

2/4 KByte

Power-

on Reset

USB

Engine

PORT

Interrupt

Controller

0

1

Watch

Dog

Timer

D+,D–

P0.0–P0.7

P1.0–P1.7

V_CC/V_SS

Cypress Semiconductor Corporation

Document #: 38-08026 Rev. *A

•

3901 North First Street

•

San Jose, CA 95134

•

408-943-2600

Revised October 5, 2004

CY7C63001A

CY7C63101A

2.0

Pin Configurations

(Top View)

24-pin

SOIC/QSOP

20-pin

CY7C63101A

DIE

DIP/SOIC

P0.4

P0.5

P0.6

P0.7

P1.1

P1.3

P1.5

P1.7

D+

P0.0

P0.1

P0.2

P0.3

P1.0

P1.2

P1.4

P1.6

1

2

3

4

5

6

7

8

24

23

22

21

20

19

18

17

16

15

P0.4

19 P0.5

P0.0

P0.1

P0.2

P0.3

P1.0

P1.2

20

1

2

3

4

5

6

7

8

9

4

3 2 1 24 23 22 21

5

20

19

18

17

P0.6

P0.7

P1.1

P1.3

D+

18

17

16

15

14

13

6

7

8

V

SS

D–

V

PP

V

12

11

9

CEXT

XTALIN 10

CC

SS

9

10 11 12 13 14 15 16

D–

XTALOUT

V

10

11

12

PP

V

14

13

CC

CEXT

XTALIN

XTALOUT

pins in Port 1 are equipped with programmable drivers strong

enough to drive LEDs. The GPIO ports feature low EMI

emissions as a result of controlled rise and fall times and

unique output driver circuits. The Cypress microcontrollers

have a range of GPIOs to fit various applications; the

CY7C6300XA has twelve GPIOs and the CY7C6310XA has

sixteen GPIOs. Notice that each part has eight ‘low-current’

ports (Port 0) with the remaining ports (Port 1) being ‘high-

current’ ports.

3.0

Functional Overview

The CY7C630/101A is a family of 8-bit RISC One Time

Programmable (OTP) microcontrollers with a built-in 1.5-Mbps

USB Serial Interface Engine (SIE). The microcontroller

features 35 instructions that are optimized for USB applica-

tions. In addition, the microcontroller features 128 bytes of

internal RAM and four Kbytes of program memory space. The

Cypress USB Controller accepts a 6-MHz ceramic resonator

as its clock source. This clock signal is doubled within the chip

to provide a 12- MHz clock for the microprocessor.

The 12-GPIO CY7C6300XA is available in 20-pin PDIP (-PC)

and 20-pin SOIC (-SC) packages. The 26-GPIO

CY7C6310XA is available in 24-pin QSOP (-QC) package.

The microcontroller features two ports of up to sixteen general

purpose I/Os (GPIOs). Each GPIO pin can be used to

generate an interrupt to the microcontroller. Additionally, all

4.0

Pin Definitions

Name

P0.0

I/O

I

20-Pin

1

24-pin

1

Die Pad #

Description

1

2

Port 0 bit 0

P0.1

2

Port 0 bit 1

P0.2

3

Port 0 bit 2

P0.3

4

Port 0 bit 3

P0.4

20

19

18

17

5

24

23

22

21

5

24

23

22

21

5

Port 0 bit 4

P0.5

Port 0 bit 5

P0.6

Port 0 bit 6

P0.7

Port 0 bit 7

P1.0

Port 1 bit 0

P1.1

16

6

20

6

20

6

Port 1 bit 1

P1.2

Port 1 bit 2

P1.3

15

–

19

7

19

7

Port 1 bit 3

P1.4

Port 1 bit 4

P1.5

–

18

8

18

8

Port 1 bit 5

P1.6

–

Port 1 bit 6

P1.7

–

17

12

13

17

12

13

Port 1 bit 7

XTALIN

XTALOUT

10

11

Ceramic resonator in

Ceramic resonator out

O

Document #: 38-08026 Rev. *A

Page 2 of 25

CY7C63001A

CY7C63101A

4.0

Pin Definitions (continued)

Name

CEXT

I/O

20-Pin

24-pin

Die Pad #

Description

I/O

9

11

Connects to external R/C timing circuit for optional

‘suspend’ wakeup

D+

D–

I/O

–

14

13

8

16

15

10

16

15

10

USB data+

USB data–

V_PP

Programming voltage supply, tie to ground during normal

operation

V_CC

V_SS

–

12

7

14

9

14

9

Voltage supply

Ground

5.0

Pin Description

Name

Description

V_CC

One pin. Connects to the USB power source or to a nominal 5V power supply. Actual V_CCrange can vary

between 4.0V and 5.25V.

V_SS

V_PP

One pin. Connects to ground.

One pin. Used in programming the on-chip EPROM. This pin should be tied to ground during normal opera-

tions.

XTALIN

One pin. Input from an external ceramic resonator.

XTALOUT

One pin. Return path for the ceramic resonator (leave unconnected if driving XTALIN from an external

oscillator).

P0.0–P0.7,

P1.0–P1.7

Sixteen pins. P0.0–P0.7 are the 8 I/O lines in Port 0. P1.0–P1.7 are the 8 I/O lines in Port 1. P1.0–P1.3 are

supported in the CY7C6300XA. All I/O pins include bit-programmable pull-up resistors. However, the sink

current of each pin can be programmed to one of sixteen levels. Besides functioning as GPIO lines, each

pin can be programmed as an interrupt input. The interrupt is edge-triggered, with programmable polarity.

D+, D–

CEXT

Two pins. Bidirectional USB data lines. An external pull-up resistor must be connected between the D pin

and V_CCto select low-speed USB operation.

One pin. Open-drain output with Schmitt trigger input. The input is connected to a rising edge-triggered

interrupt. CEXT may be connected to an external RC to generate a wake-up from Suspend mode. See

Section 6.4.

6.1.1

Program Memory Organization

6.0

Functional Description

The CY7C63001A and CY7C63101A each offer 4 Kbytes of

EPROM. The program memory space is divided into two

functional groups: interrupt vectors and program code.

The Cypress CY7C630/101A USB microcontrollers are

optimized for human-interface computer peripherals such as

a mouse, joystick, and gamepad. These USB microcontrollers

conform to the low-speed (1.5 Mbps) requirements of the USB

Specification version 1.1. Each microcontroller is a self-

contained unit with: a USB interface engine, USB transceivers,

an 8-bit RISC microcontroller, a clock oscillator, timers, and

program memory. Each microcontroller supports one USB

device address and two endpoints.

The interrupt vectors occupy the first 16 bytes of the program

space. Each vector is 2 bytes long. After a reset, the Program

Counter points to location zero of the program space. Figure

6-1 shows the organization of the Program Memory Space.

6.1.2

Security Fuse Bit

The 6-MHz clock is doubled to 12 MHz to drive the microcon-

troller. A RISC architecture with 35 instructions provides the

best balance between performance and product cost.

The Cypress USB microcontroller includes a security fuse bit.

When the security fuse is programmed, the EPROM program

memory outputs 0xFF to the EPROM programmer, thus

protecting the user’s code.

6.1

Memory Organization

The memory in the USB Controller is organized into user

program memory in EPROM space and data memory in SRAM

space.

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CY7C63001A

CY7C63101A

after reset

PC

Address

0x0000

Reset Vector

0x0002

0x0004

0x0006

0x0008

0x000A

0x000C

0x000E

0x0010

Interrupt Vector – 128 µs

Interrupt Vector – 1.024 ms

Interrupt Vector – USB Endpoint 0

Interrupt Vector – USB Endpoint 1

Reserved

Interrupt Vector – GPIO

Interrupt Vector – Cext

On-chip program Memory

0x07FF

2K ROM (CY7C63000A, CY7C63100A)

0x0FFF

4K ROM (CY7C63001A, CY7C63101A)

Figure 6-1. Program Memory Space

6.1.3

Data Memory Organization

The DSP pre-decrements by one whenever a PUSH

instruction is executed and it increments by one after a POP

instruction is used. The default value of the DSP after reset is

0x00, which would cause the first PUSH to write into USB

FIFO space for Endpoint 1. Therefore, the DSP should be

mapped to a location such as 0x70 before initiating any data

stack operations. Refer to the Reset section for more infor-

mation about DSP remapping after reset. Figure 6-2 illustrates

the Data Memory Space.

The USB Controller includes 128 bytes of data RAM. The

upper 16 bytes of the data memory are used as USB FIFOs

for Endpoint 0 and Endpoint 1. Each endpoint is associated

with an 8-byte FIFO.

The USB controller includes two pointers into data RAM, the

Program Stack Pointer (PSP) and the Data Stack Pointer

(DSP). The value of PSP after reset is 0x00. The PSP incre-

ments by two whenever a CALL instruction is executed and it

decrements by two whenever a RET instruction is used.

Document #: 38-08026 Rev. *A

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CY7C63001A

CY7C63101A

after reset

DSP

Address

0x00

PSP

0x02

0x04

user

firmware

0x70

USB FIFO – Endpoint 0

USB FIFO – Endpoint 1

DSP

0x77

0x78

0x7F

Figure 6-2. Data Memory Space

6.2

I/O Register Summary

I/O registers are accessed via the I/O Read (IORD) and I/O

Write (IOWR, IOWX) instructions.

Table 6-1. I/O Register Summary

Register Name I/O Address

Read/Write

R/W

W

Function

General purpose I/O Port (low current)

General purpose I/O Port (high current)

Interrupt enable for Port 0 pins

Interrupt enable for Port 1 pins

Pull-up resistor control for Port 0 pins

Pull-up resistor control for Port 1 pins

USB Endpoint 0 transmit configuration

USB Endpoint 1 transmit configuration

USB device address

Page

Figure 6-8

Figure 6-9

Figure 6-17

Figure 6-18

Figure 6-11

Figure 6-12

Figure 6-22

Figure 6-23

Figure 6-20

Figure 6-24

Figure 6-21

Figure 6-15

Figure 6-4

Figure 6-5

Figure 6-6

P0 Data

P1 Data

P0 IE

0x00

0x01

0x04

P1 IE

0x05

W

P0 Pull-up

P1 Pull-up

EP0 TX Config.

EP1 TX Config.

USB DA

USB SCR

EP0 RX Status

GIE

0x08

W

0x09

W

0x10

R/W

W

0x11

0x12

0x13

USB status and control

0x14

USB Endpoint 0 receive status

Global Interrupt Enable

0x20

WDT

0x21

Watchdog Timer clear

Cext

0x22

R/W

R

External R-C Timing circuit control

Free-running timer

Timer

0x23

P0 Isink

0x30-0x37

W

Input sink current control for Port 0 pins. There is one Figure 6-13

Isink register for each pin. Address of the Isink register

for pin 0 is located at 0x30 and the register address for

pin 7 is located at 0x37.

Document #: 38-08026 Rev. *A

Page 5 of 25

CY7C63001A

CY7C63101A

Table 6-1. I/O Register Summary (continued)

Register Name I/O Address

Read/Write

Function

Page

P1 Isink

0x38-0x3F

W

Input sink current control for Port 1 pins. There is one Figure 6-13

Isink register for each pin. Address of the Isink register

for pin 0 is located at 0x38 and the register address for

pin 7 is located at 0x3F. The number of Port 1 pins

depends on package type.

SCR

0xFF

R/W

Processor status and control register

Figure 6-3

The occurrence of a reset is recorded in the Status and Control

Register located at I/O address 0xFF (Figure 6-3). Reading

and writing this register are supported by the IORD and IOWR

instructions. Bits 1, 2, and 7 are reserved and must be written

as zeros during a write. During a read, reserved bit positions

should be ignored. Bits 4, 5, and 6 are used to record the

occurrence of POR, USB, and WDR Reset respectively. The

firmware can interrogate these bits to determine the cause of

a reset. If a Watchdog Reset occurs, firmware must clear the

WDR bit (bit 6) in the Status and Control Register to re-enable

the USB transmitter (please refer to the Watchdog Reset

section for further details). Bit 0, the “Run” control, is set to 1

at POR. Clearing this bit stops the microcontroller (firmware

normally should not clear this bit). Once this bit is set to LOW,

only a reset can set this bit HIGH.

6.3

Reset

The USB Controller supports three types of resets. All

registers are restored to theirWatchdog default states during a

reset. The USB Device Address is set to 0 and all interrupts

are disabled. In addition, the Program Stack Pointer (PSP) is

set to 0x00 and the Data Stack Pointer (DSP) is set to 0x00.

The user should set the DSP to a location such as 0x70 to

reserve 16 bytes of USB FIFO space. The assembly instruc-

tions to do so are:

MOV A, 70h

instead of 6F because the dsp is

; always decremented by 1 before the

data transfer of the PUSH instruction occurs

; Move 70 hex into Accumulator, use 70

SWAP A, DSP

; Move Accumulator value into dsp

The three reset types are:

1. Power-On Reset (POR)

2. Watchdog Reset (WDR)

3. USB Reset

The microcontroller resumes execution from ROM address

0x00 after a reset unless the Suspend bit (bit 3) of the Status

and Control Register is set. Setting the Suspend bit stops the

clock oscillator and the interrupt timers and powers down the

microcontroller. The detection of any USB activity, the occur-

rence of a GPIO Interrupt, or the occurrence of the Cext

Interrupt terminates the suspend condition.

b7

b6

b5

b4

b3

b2

b1

b0

Reserved

WDR

USBR

POR

SUSPEND

Reserved

RUN

R/W

0

R/W

0

R/W

1

R/W

0

R/W

1

0

Figure 6-3. Status and Control Register (SCR – Address 0xFF)

6.3.1

Power-On Reset

suspended mode at the end of POR to conserve power (the

clock oscillator, the timers, and the interrupt logic are turned

off in suspend mode). After POR, only a non-idle USB Bus

state terminates the suspend mode. The microcontroller then

begins execution from ROM address 0x00.

Power-On Reset (POR) occurs every time the power to the

device is switched on. Bit 4 of the Status and Control Register

is set to record this event (the register contents are set to

00011001 by the POR). The USB Controller is placed in

Document #: 38-08026 Rev. *A

Page 6 of 25

CY7C63001A

CY7C63101A

7.168 to

8.192 ms

Last write to

Watchdog Timer

Register

No write to WDT

register, so WDR

goes HIGH

Execution begins at

Reset Vector 0x00

Figure 6-4. Watchdog Reset

6.3.2

Watchdog Reset (WDR)

register. All logic blocks in the device are turned off except the

USB receiver, the GPIO interrupt logic, and the Cext interrupt

logic. The clock oscillator and the free-running and Watchdog

timers are shut down.

The Watchdog Timer Reset (WDR) occurs when the Most

Significant Bit of the 4-bit Watchdog Timer Register transitions

from LOW to HIGH. Writing any value to the write-only

Watchdog Restart Register at 0x21 clears the timer (firmware

should periodically write to the Watchdog Restart Register in

the ‘main loop’ of firmware). The Watchdog timer is clocked by

a 1.024-ms clock from the free-running timer. If 8 clocks occur

between writes to the timer, a WDR occurs and bit 6 of the

Status and Control Register is set to record the event. A

Watchdog Timer Reset lasts for 8.192 ms, at which time the

microcontroller begins execution at ROM address 0x00. The

USB transmitter is disabled by a Watchdog Reset because the

USB Device Address Register is cleared (otherwise, the USB

Controller would respond to all address 0 transactions). The

transmitter remains disabled until the WDR bit (bit 6) in the

Status and Control Register is reset to 0 by firmware.

The suspend mode is terminated when one of the following

three conditions occur:

1. USB activity

2. A GPIO interrupt

3. Cext interrupt

The clock oscillator, GPIO, and timers restart immediately

upon exiting suspend mode. The USB engine and microcon-

troller return to a fully functional state no more than 256 µs

later. Before servicing any interrupt requests, the microcon-

troller executes the instruction following the I/O write that

placed the device into suspend mode.

Both the GPIO interrupt and the Cext interrupt allow the USB

Controller to wake-up periodically and poll potentiometers,

optics, and other system components while maintaining a very

low average power consumption. The Cext Interrupt is

preferred for lowest power consumption.

6.3.3

USB Bus Reset

The USB Controller recognizes a USB Reset when a Single

Ended Zero (SE0) condition persists for at least 8–16 µs (the

Reset may be recognized for an SE0 as short as 8 µs, but it is

always recognized for an SE0 longer than 16 µs). SE0 is the

condition in which both the D+ line and the D– line are LOW.

Bit 5 of the Status and Control Register is set to record this

event. If the USB reset happens while the device is

suspended, the suspend condition is cleared and the clock

oscillator is restarted. However, the microcontroller is not

released until the USB reset is removed.

For Cext to generate an “Instant-on” interrupt, the pin must be

connected to ground with an external capacitor and connected

to V_CCwith an external resistor. A “0” is written to the Cext

register located at I/O address 0x22 to discharge the capacitor.

Then, a “1” is written to disable the open-drain output driver. A

Schmitt trigger input circuit monitors the input and generates

a wake-up interrupt when the input voltage rises above the

input threshold. By changing the values of the external resistor

and capacitor, the user can fine tune the charge rate of the R-

C timing circuit. The format of the Cext register is shown in

Figure 6-5. Reading the register returns the value of the Cext

pin. During a reset, the Cext pin is HIGH.

6.4

Instant-on Feature (Suspend Mode)

The USB Controller can be placed in a low-power state by

setting the Suspend bit (bit 3) of the Status and Control

b7

b6

b5

b4

b3

b2

b1

b0

CEXT

R/W

1

Reserved

0

Figure 6-5. The Cext Register (Address 0x22)

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CY7C63001A

CY7C63101A

mode is entered. Figure 6-6 illustrates the format of this

register and Figure 6-7 is its block diagram.

6.5

On-Chip Timer

The USB Controller is equipped with a free-running timer

driven by a clock one-sixth the resonator frequency. Bits 0

through 7 of the counter are readable from the read-only Timer

Register located at I/O address 0x23. The Timer Register is

cleared during a Power-On Reset and whenever Suspend

With a 6 MHz resonator, the timer resolution is 1 µs.

The timer generates two interrupts: the 128-µs interrupt and

the 1.024-ms interrupt.

Figure 6-6. Timer Register (Address 0x23)

b4 b3

T.4 T.3

b7

T.7

R

b6

T.6

R

b5

T.5

R

b2

T.2

R

b1

T.1

R

b0

T.0

R

0

R

0

1.024-ms interrupt

128- s interrupt

m

9

7

8

1

0

6

3

5

4

2

Resonator Clock/6

8

To Timer Register

Figure 6-7. Timer Block Diagram

Port 0 data register is located at I/O address 0x00 while the

Port 1 data register is located at I/O address 0x01. The

contents of both registers are set HIGH during a reset. Refer

to Figures 6-8 and 6-9 for the formats of the data registers. In

addition to supporting general input/output functions, each I/O

line can trigger an interrupt to the microcontroller. Please refer

to the interrupt section for more details.

6.6

General Purpose I/O Ports

Interface with peripherals is conducted via as many as 16

GPIO signals. These signals are divided into two ports: Port 0

and Port 1. Port 0 contains eight lines (P0.0–P0.7) and Port 1

contains up to eight lines (P1.0–P1.7). The number of external

I/O pins depends on the package type. Both ports can be

accessed by the IORD, IOWR, and IOWX instructions. The

b7

P0.7

R/W

1

b6

P0.6

R/W

1

b5

P0.5

R/W

1

b4

P0.4

R/W

1

b3

P0.3

R/W

1

b2

P0.2

R/W

1

b1

P0.1

R/W

1

b0

P0.0

R/W

1

Figure 6-8. Port 0 Data Register (Address 0x00)

b7

P1.7

R/W

1

b6

P1.6

R/W

1

b5

P1.5

R/W

1

b4

P1.4

R/W

1

b3

P1.3

R/W

1

b2

P1.2

R/W

1

b1

P1.1

R/W

1

b0

P1.0

R/W

1

Figure 6-9. Port 1 Data Register (Address 0x01)

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CY7C63001A

CY7C63101A

Each GPIO line includes an internal R_upresistor. This resistor

provides both the pull-up function and slew control. Two

factors govern the enabling and disabling of each resistor: the

state of its associated Port Pull-up register bit and the state of

the Data Register bit. NOTE: The control bits in the Port Pull-

up register are active LOW.

diagram of one I/O line. The Port Isink Register is used to

control the output current level and it is described later in this

section. NOTE: The Isink logic block is turned off during

suspend mode (please refer to the Instant-on Feature section

for more details). Therefore, to prevent higher I_CCcurrents

during USB suspend mode, firmware must set ALL Port 0 and

Port 1 Data Register bits (which are not externally driven to a

known state), including those that are not bonded out on a

particular package, to “1” and all Port 0 and Port 1 Pull-Up

Register data bits to “0” to enable port pull-ups before setting

the Suspend bit (bit 3 of the Status and Control Register).

Table 6-2 is the Output Control truth table.

A GPIO line is HIGH when a “1” is written to the Data Register

and a “0” is written to the respective Port Pull-up register.

Writing a “0” to the port Data Register disables the port’s Pull-

up resistor and outputs a LOW on the GPIO line regardless of

the setting in the Port Pull-up Register. The output goes to a

high-Z state if the Data Register bit and the Port Pull-up

Register bit are both “1”. Figure 6-10 illustrates the block

V_CC

Port Pull-Up

Register

R_up

Port Data

Register

GPIO

Port Isink

Register

Isink

DAC

Disable

Suspend

Bit

Schmitt

Trigger

Data Bus

Figure 6-10. Block Diagram of an I/O Line

Table 6-2. Output Control Truth Table

Data Register

Port Pull-up Register

Output at I/O Pin

Sink Current (‘0’)

Pull-up Resistor (‘1’)

Hi-Z

Interrupt Polarity

High to Low

0

1

0

1

0

1

Low to High

High to Low

Low to High

To configure a GPIO pin as an input, a “1” should be written to

the Port Data Register bit associated with that pin to disable

the pull-down function of the Isink DAC (see Figure 6-

10).When the Port Data Register is read, the bit value is a “1”

if the voltage on the pin is greater than the Schmitt trigger

threshold, or “0” if it is below the threshold. In applications

where an internal pull-up is required, the R_uppull-up resistor

can be engaged by writing a “0” to the appropriate bit in the

Port Pull-up Register.

Both Port 0 and Port 1 Pull-up Registers are write only (see

Figures 6-11 and 6-12). The Port 0 Pull-up Register is located

at I/O address 0x08 and Port 1 Pull-up Register is mapped to

address 0x09. The contents of the Port Pull-up Registers are

cleared during reset, allowing the outputs to be controlled by

the state of the Data Registers. The Port Pull-up Registers also

select the polarity of transition that generates a GPIO interrupt.

A “0” selects a HIGH to LOW transition while a “1” selects a

LOW to HIGH transition.

b7

b6

b5

b4

b3

b2

b1

b0

PULL0.7

PULL0.6

PULL0.5

PULL0.4

PULL0.3

PULL0.2

PULL0.1

PULL0.0

W

0

W

0

W

0

W

0

W

0

W

0

W

0

W

0

Figure 6-11. Port 0 Pull-up Register (Address 0x08)

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b7

PULL1.7

W

b6

b5

b4

b3

b2

b1

b0

PULL1.6

PULL1.5

PULL1.4

PULL1.3

PULL1.2

PULL1.1

PULL1.0

W

0

W

0

W

0

W

0

W

0

W

0

W

0

0x

Figure 6-12. Port 1 Pull-up Register (Address 0x09)

Writing a “0” to the Data Register drives the output LOW.

Instead of providing a fixed output drive, the USB Controller

allows the user to select an output sink current level for each

I/O pin. The sink current of each output is controlled by a

dedicated Port Isink Register. The lower four bits of this

register contain a code selecting one of sixteen sink current

levels. The upper four bits of the register are ignored. The

format of the Port Isink Register is shown in Figure 6-13.

b7

b6

b5

b4

b3

ISINK3

W

b2

ISINK2

W

b1

ISINK1

W

b0

ISINK0

W

Reserved

UNUSED

W

x

W

x

W

x

W

x

Figure 6-13. Port Isink Register for One GPIO Line

Port 0 is a low-current port suitable for connecting photo

transistors. Port 1 is a high current port capable of driving

LEDs. See section 8.0 for current ranges. 0000 is the lowest

drive strength. 1111 is the highest.

registers are cleared during a reset, resulting in the minimum

current sink setting.

6.7

XTALIN/XTALOUT

The write-only sink current control registers for Port 0 outputs

are assigned from I/O address 0x30 to 0x37 with the control

bits for P00 starting at 0x30. Port 1 sink current control

registers are assigned from I/O address 0x38 to 0x3F with the

control bits for P10 starting at 0x38. All sink current control

The XTALIN and XTALOUT pins support connection of a 6-

MHz ceramic resonator. The feedback capacitors and bias

resistor are internal to the IC, as shown in Figure 6-14 Leave

XTALOUT unconnected when driving XTALIN from an external

oscillator.

XTALOUT

clk1x

(to USB SIE)

Clock

clk2x

XTALIN

Doubler

(to Microcontroller)

30 pF

Figure 6-14. Clock Oscillator On-chip Circuit

instructions to address 0x20. Writing a “1” to a bit position

enables the interrupt associated with that position. During a

reset, the contents of the Interrupt Enable Register are

cleared, disabling all interrupts. Figure 6-15 illustrates the

format of the Global Interrupt Enable Register.

6.8

Interrupts

Interrupts are generated by the General Purpose I/O lines, the

Cext pin, the internal timer, and the USB engine. All interrupts

are maskable by the Global Interrupt Enable Register. Access

to this register is accomplished via IORD, IOWR, and IOWX

b7

CEXTIE

R/W

0

b6

GPIOIE

R/W

0

b5

b4

EP1IE

R/W

0

b3

EP0IE

R/W

0

b2

1024IE

R/W

0

b1

128IE

R/W

0

b0

Reserved

0

Figure 6-15. Global Interrupt Enable Register (GIER – Address 0x20)

The interrupt controller contains a separate latch for each

interrupt. See Figure 6-16 for the logic block diagram for the

interrupt controller. When an interrupt is generated, it is

latched as a pending interrupt. It stays as a pending interrupt

until it is serviced or a reset occurs. A pending interrupt only

generates an interrupt request if it is enabled in the Global

Interrupt Enable Register. The highest priority interrupt

request is serviced following the execution of the current

instruction.

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CY7C63001A

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When servicing an interrupt, the hardware first disables all

interrupts by clearing the Global Interrupt Enable Register.

Next, the interrupt latch of the current interrupt is cleared. This

is followed by a CALL instruction to the ROM address

associated with the interrupt being serviced (i.e., the interrupt

vector). The instruction in the interrupt table is typically a JMP

instruction to the address of the Interrupt Service Routine

(ISR). The user can re-enable interrupts in the interrupt service

routine by writing to the appropriate bits in the Global Interrupt

Enable Register. Interrupts can be nested to a level limited

only by the available stack space.

process. The user firmware is responsible for ensuring that the

processor state is preserved and restored during an interrupt.

For example the PUSH A instruction should be used as the

first command in the ISR to save the accumulator value. And,

the IPRET instruction should be used to exit the ISR with the

accumulator value restored and interrupts enabled. The PC,

CF, and ZF are restored when the IPRET or RET instructions

are executed.

The Interrupt Vectors supported by the USB Controller are

listed in Table 6-3. Interrupt Vector 0 (Reset) has the highest

priority, Interrupt Vector 7 has the lowest priority. Because the

JMP instruction is two bytes long, the interrupt vectors occupy

two bytes.

The Program Counter (PC) value and the Carry and Zero flags

(CF, ZF) are automatically stored onto the Program Stack by

the CALL instruction as part of the interrupt acknowledge

Table 6-3. Interrupt Vector Assignments

Interrupt Priority

ROM Address

0x00

Function

0 (Highest)

Reset

1

0x02

0x04

0x06

0x08

0x0A

0x0C

0x0E

128-µs timer interrupt

1.024-ms timer interrupt

USB endpoint 0 interrupt

USB endpoint 1 interrupt

Reserved

2

3

4

5

6

GPIO interrupt

7 (Lowest)

Wake-up interrupt

6.8.1

Interrupt Latency

For example, if a 5-clock-cycle instruction such as JC is being

executed when an interrupt occurs, the first instruction of the

Interrupt Service Routine executes a minimum of 16 clock

cycles (1+10+5) or a maximum of 20 clock cycles (5+10+5)

after the interrupt is issued. Therefore, the interrupt latency in

this example will be = 20 clock periods = 20 / (12 MHz) = 1.667

µs. The interrupt latches are sampled at the rising edge of the

last clock cycle in the current instruction.

Interrupt latency can be calculated from the following

equation:

Interrupt Latency = (Number of clock cycles remaining in the

current instruction) + (10 clock cycles for

the CALL instruction) + (5 clock cycles

for the JMP instruction)

128-

m

s CLR

s IRQ

CLR

D

Logic 1

128-

Q

m

Enable [1]

1-ms CLR

1-ms IRQ

m

s

CLK

Interrupt

IRQ

End P0 CLR

End P0 IRQ

End P1 CLR

End P1 IRQ

Global

Interrupt

Enable

Interrupt

Vector

Enable [7:0]

GPIO CLR

GPIO IRQ

Register

CLR

Logic 1

D

Q

Enable [6]

Enable [7]

GPIO

Interrupt

Acknowledge

CLK

Wake-up CLR

Wake-up IRQ

CLR

Logic 1

CEXT

D

Interrupt

Priority

CLK

Encoder

Figure 6-16. Interrupt Controller Logic Block Diagram

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CY7C63001A

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6.8.2

GPIO Interrupt

LOW interrupt trigger. Each GPIO interrupt is maskable on a

per-pin basis by a dedicated bit in the Port Interrupt Enable

Register. Writing a “1” enables the interrupt. Figure 6-17 and

Figure 6-18 illustrate the format of the Port Interrupt Enable

Registers for Port 0 and Port 1 located at I/O address 0x04 and

0x05 respectively. These write only registers are cleared

during reset, thus disabling all GPIO interrupts.

The General Purpose I/O interrupts are generated by signal

transitions at the Port 0 and Port 1 I/O pins. GPIO interrupts

are edge sensitive with programmable interrupt polarities.

Setting a bit HIGH in the Port Pull-up Register (see Figure 6-

11 and 6-12) selects a LOW to HIGH interrupt trigger for the

corresponding port pin. Setting a bit LOW activates a HIGH to

b7

IE0.7

W

b6

IE0.6

W

b5

IE0.5

W

b4

IE0.4

W

b3

IE0.3

W

b2

IE0.2

W

b1

IE0.1

W

b0

IE0.0

W

0

Figure 6-17. Port 0 Interrupt Enable Register (P0 IE – Address 0x04)

b7

IE1.7

W

b6

IE1.6

W

b5

IE1.5

W

b4

IE1.4

W

b3

IE1.3

W

b2

IE1.2

W

b1

IE1.1

W

b0

IE1.0

W

0

Figure 6-18. Port 1 Interrupt Enable Register (P1 IE – Address 0x05)

A block diagram of the GPIO interrupt logic is shown in Figure

6-19. The bit setting in the Port Pull-up Register selects the

interrupt polarity. If the selected signal polarity is detected on

the I/O pin, a HIGH signal is generated. If the Port Interrupt

Enable bit for this pin is HIGH and no other port pins are

requesting interrupts, the OR gate issues a LOW to HIGH

signal to clock the GPIO interrupt flip-flop. The output of the

flip-flop is further qualified by the Global GPIO Interrupt Enable

bit before it is processed by the Interrupt Priority Encoder. Both

the GPIO interrupt flip-flop and the Global GPIO Enable bit are

cleared by on-chip hardware during GPIO interrupt

acknowledge.

Port

Pull-Up

Register

→

^10=L^HÆ^H

L

GPIO Interrupt

Flip-Flop

OR Gate

(1 input per

GPIO pin)

I

D

Q

M

U

X

GPIO

CLR

Port Interrupt

Enable Register

1 = Enable

0 = Disable

Interrupt

Acknowledge

CLR

IRQ

Interrupt

Priority

Encoder

Global

GPIO Interrupt

Enable

1 = Enable

0 = Disable

Interrupt

Vector

(Bit 6, Register 0x20)

Figure 6-19. GPIO Interrupt Logic Block Diagram

Note. If one port pin triggers an interrupt, no other port pin can

cause a GPIO interrupt until the port pin that triggered the

interrupt has returned to its inactive (non-trigger) state or until

its corresponding port interrupt enable bit is cleared (these

events ‘reset’ the clock of the GPIO Interrupt flip-flop, which

must be ‘reset’ to ‘0’ before another GPIO interrupt event can

‘clock’ the GPIO Interrupt flip-flop and produce an IRQ).

enable bit is cleared and then set, a GPIO interrupt event

occurs as the GPIO Interrupt flip-flop clock transitions from ‘1’

to ‘0’ and then back to ‘1’ (please refer to Figure 6-19). The

USB Controller does not assign interrupt priority to different

port pins and the Port Interrupt Enable Registers are not

cleared during the interrupt acknowledge process. When a

GPIO interrupt is serviced, the ISR must poll the ports to

determine which pin caused the interrupt.

Note. If the port pin that triggered an interrupt is held in its

active (trigger) state while its corresponding port interrupt

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CY7C63001A

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6.8.3

USB Interrupt

6.9

USB Engine

A USB Endpoint 0 interrupt is generated after the host has

written data to Endpoint 0 or after the USB Controller has

transmitted a packet from Endpoint 0 and receives an ACK

from the host. An OUT packet from the host which is NAKed

by the USB Controller does not generate an interrupt. This

interrupt is masked by the USB EP0 Interrupt Enable bit (bit 3)

of the Global Interrupt Enable Register.

The USB engine includes the Serial Interface Engine (SIE)

and the low-speed USB I/O transceivers. The SIE block

performs most of the USB interface functions with only minimal

support from the microcontroller core. Two endpoints are

supported. Endpoint 0 is used to receive and transmit control

(including setup) packets while Endpoint 1 is only used to

transmit data packets.

A USB Endpoint 1 interrupt is generated after the USB

Controller has transmitted a packet from Endpoint 1 and has

received an ACK from the host. This interrupt is masked by the

USB EP1 Interrupt Enable bit (bit 4) of the Global Interrupt

Enable Register.

The USB SIE processes USB bus activity at the transaction

level independently. It does all the NRZI encoding/decoding

and bit stuffing/unstuffing. It also determines token type,

checks address and endpoint values, generates and checks

CRC values, and controls the flow of data bytes between the

bus and the Endpoint FIFOs. NOTE: the SIE stalls the CPU for

three cycles per byte when writing data to the endpoint FIFOs

(or 3 * 1/12 MHz * 8 bytes = 2 µs per 8-byte transfer).

6.8.4

Timer Interrupt

There are two timer interrupts: the 128-µs interrupt and the

1.024-ms interrupt. They are masked by bits 1 and 2 of the

Global Interrupt Enable Register respectively. The user should

disable both timer interrupts before going into the suspend

mode to avoid possible conflicts from timer interrupts occurring

just as suspend mode is entered.

The firmware handles higher level and function-specific tasks.

During control transfers the firmware must interpret device

requests and respond correctly. It also must coordinate

Suspend/Resume, verify and select DATA toggle values, and

perform function specific tasks.

The USB engine and the firmware communicate though the

Endpoint FIFOs, USB Endpoint interrupts, and the USB

registers described in the sections below.

6.8.5

Wake-Up Interrupt

A wake-up interrupt is generated when the Cext pin goes

HIGH. This interrupt is latched in the interrupt controller. It can

be masked by the Wake-up Interrupt Enable bit (bit 7) of the

Global Interrupt Enable Register. This interrupt can be used to

perform periodic checks on attached peripherals when the

USB Controller is placed in the low-power suspend mode. See

the Instant-On Feature section for more details.

6.9.1

USB Enumeration Process

The USB Controller provides a USB Device Address Register

at I/O location 0x12. Reading and writing this register is

achieved via the IORD and IOWR instructions. The register

contents are cleared during a reset, setting the USB address

of the USB Controller to 0. Figure 6-20 shows the format of the

USB Address Register.

b7

b6

ADR6

R/W

0

b5

ADR5

R/W

0

b4

ADR4

R/W

0

b3

ADR3

R/W

0

b2

ADR2

R/W

0

b1

ADR1

R/W

0

b0

ADR0

R/W

0

Reserved

0

Figure 6-20. USB Device Address Register (USB DA – Address 0x12)

Typical enumeration steps:

8. The host performs a control read sequence and the USB

Controller responds by sending its Device descriptor over

the USB bus.

1. The host computer sends a SETUP packet followed by a

DATA packet to USB address 0 requesting the Device

descriptor.

9. The host generates control reads to the USB Controller to

request the Configuration and Report descriptors.

2. The USB Controller decodes the request and retrieves its

Device descriptor from the program memory space.

10.The USB Controller retrieves the descriptors from its

program space and returns the data to the host over the

USB.

3. The host computer performs a control read sequence and

the USB Controller responds by sending the Device

descriptor over the USB bus.

11.Enumeration is complete after the host has received all the

descriptors.

4. After receiving the descriptor, the host computer sends a

SETUP packet followed by a DATA packet to address 0

assigning a new USB address to the device.

5. The USB Controller stores the new address in its USB

Device Address Register after the no-data control

sequence completes.

6. The host sends a request for the Device descriptor using

the new USB address.

7. The USB Controller decodes the request and retrieves the

Device descriptor from the program memory.

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6.9.2

Endpoint 0

6.9.2.1 Endpoint 0 Receive

All USB devices are required to have an endpoint number 0

that is used to initialize and manipulate the device. Endpoint 0

provides access to the device’s configuration information and

allows generic USB status and control accesses.

After receiving a packet and placing the data into the Endpoint

0 FIFO, the USB Controller updates the USB Endpoint 0 RX

register to record the receive status and then generates a USB

Endpoint 0 interrupt. The format of the Endpoint 0 RX Register

is shown in Figure 6-21.

Endpoint 0 can receive and transmit data. Both receive and

transmit data share the same 8-byte Endpoint 0 FIFO located

at data memory space 0x70 to 0x77. Received data may

overwrite the data previously in the FIFO.

b7

COUNT3

R/W

b6

COUNT2

R/W

b5

COUNT1

R/W

b4

COUNT0

R/W

b3

b2

IN

b1

OUT

R/W

0

b0

SETUP

R/W

0

TOGGLE

R

0

R/W

0

Figure 6-21. USB Endpoint 0 RX Register (Address 0x14)

This is a read/write register located at I/O address 0x14. Any

write to this register clears all bits except bit 3 which remains

unchanged. All bits are cleared during reset.

received. The count is always updated and the data is always

stored in the FIFO for DATA packets following a SETUP token.

The count for DATA following an OUT token is updated if Stall

(bit 5 of 0x10) is 0 and either EnableOuts or StatusOuts (bits

3 and 4 of 0x13) are 1. The DATA following an OUT is written

into the FIFO if EnableOuts is set to 1 and Stall and StatusOuts

are 0.

Bit 0 is set to 1 when a SETUP token for Endpoint 0 is received.

Once set to a 1, this bit remains HIGH until it is cleared by an

I/O write or a reset. While the data following a SETUP is being

received by the USB engine, this bit is not cleared by an I/O

write. User firmware writes to the USB FIFOs are disabled

when bit 0 is set. This prevents SETUP data from being

overwritten.

A maximum of eight bytes are written into the Endpoint 0 FIFO.

If there are less than eight bytes of data the CRC is written into

the FIFO.

Bits 1 and 2 are updated whenever a valid token is received

on Endpoint 0. Bit 1 is set to 1 if an OUT token is received and

cleared to 0 if any other token is received. Bit 2 is set to 1 if an

IN token is received and cleared to 0 if any other token is

received.

Due to register space limitations, the Receive Data Invalid bit

is located in the USB Endpoint 0 TX Configuration Register.

Refer to the Endpoint 0 Transmit section for details. This bit is

set by the SIE if an error is detected in a received DATA packet.

Table 6-4 summarizes the USB Engine response to SETUP

and OUT transactions on Endpoint 0. In the Data Packet

column ‘Error’ represents a packet with a CRC, PID or bit-

stuffing error, or a packet with more than eight bytes of data.

‘Valid’ is a packet without an Error. ‘Status’ is a packet that is

a valid control read Status stage, while ‘N/Status’ is not a

correct Status stage (see section 6.9.4). The ‘Stall’ bit is

described in Section 6.9.2.2. The ‘StatusOuts’ and

‘EnableOuts’ bits are described in section 6.9.4.

Bit 3 shows the Data Toggle status of DATA packets received

on Endpoint 0. This bit is updated for DATA following SETUP

tokens and for DATA following OUT tokens if Stall (bit 5 of

0x10) is not set and either EnableOuts or StatusOuts (bits 3

and 4 of 0x13) are set.

Bits 4 to 7 are the count of the number of bytes received in a

DATA packet. The two CRC bytes are included in the count,

so the count value is two greater than the number of data bytes

Table 6-4. USB Engine Response to SETUP and OUT Transactions on Endpoint 0

Control Bit Settings Received Packets USB Engine Response

Token

Type

Data

Toggle

Count

Stall

Status Out EnableOut

Packet FIFO Write Update

Update

Interrupt

Yes

No

Reply

ACK

–

0

1

0

–

0

1

–

1

0

SETUP

OUT

Valid

Error

Yes

No

Yes

No

Yes

No

None

ACK

Valid

OUT

Error

None

NAK

OUT

Valid

OUT

Error

No

None

STALL

None

ACK

OUT

Valid

No

OUT

Error

No

OUT

Status

N/Status

Error

Yes

No

Yes

No

OUT

STALL

None

OUT

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CY7C63001A

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6.9.2.2 Endpoint 0 Transmit

The USB Endpoint 0 TX Register located at I/O address 0x10

controls data transmission from Endpoint 0 (see Figure 6-22).

This is a read/write register. All bits are cleared during reset.

b7

INEN

R/W

0

b6

DATA1/0

R/W

b5

STALL

R/W

0

b4

ERR

R/W

0

b3

COUNT3

R/W

b2

COUNT2

R/W

b1

b0

COUNT1

COUNT0

R/W

0

R/W

0

Figure 6-22. USB Endpoint 0 TX Configuration Register (Address 0x10)

Bits 0 to 3 indicate the numbers of data bytes to be transmitted

during an IN packet, valid values are 0 to 8 inclusive. Bit 4

indicates that a received DATA packet error (CRC, PID, or

bitstuffing error) occurred during a SETUP or OUT data phase.

Setting the Stall bit (bit 5) stalls IN and OUT packets. This bit

is cleared whenever a SETUP packet is received by

Endpoint 0. Bit 6 (Data 1/0) must be set to 0 or 1 to select the

DATA packet’s toggle state (0 for DATA0, 1 for DATA1).

received. The Interrupt Service Routine can check bit 7 to

confirm that the data transfer was successful.

6.9.3

Endpoint 1

Endpoint 1 is capable of transmit only. The data to be trans-

mitted is stored in the 8-byte Endpoint 1 FIFO located at data

memory space 0x78 to 0x7F.

After the transmit data has been loaded into the FIFO, bit 6

should be set according to the data toggle state and bit 7 set

to “1”. This enables the USB Controller to respond to an IN

packet. Bit 7 is cleared and an Endpoint 0 interrupt is

generated by the SIE once the host acknowledges the data

transmission. Bit 7 is also cleared when a SETUP token is

6.9.3.1 Endpoint 1 Transmit

Transmission is controlled by the USB Endpoint 1 TX Register

located at I/O address 0x11 (see Figure 6-23). This is a

read/write register. All bits are cleared during reset.

b7

INEN

R/W

0

b6

DATA1/0

R/W

b5

STALL

R/W

0

b4

EP1EN

R/W

0

b3

COUNT3

R/W

b2

COUNT2

R/W

b1

COUNT1

R/W

b0

COUNT0

R/W

0

Figure 6-23. USB Endpoint 1 TX Configuration Register (Address 0x11)

Bits 0 to 3 indicate the numbers of data bytes to be transmitted

during an IN packet, valid values are 0 to 8 inclusive.

to “1”. This enables the USB Controller to respond to an IN

packet. Bit 7 is cleared and an Endpoint 1 interrupt is

generated by the SIE once the host acknowledges the data

transmission.

Bit 4 must be set before Endpoint 1 can be used. If this bit is

cleared, the USB Controller ignores all traffic to Endpoint 1.

Setting the Stall bit (bit 5) stalls IN and OUT packets until this

bit is cleared.

6.9.4

USB Status and Control

USB status and control is regulated by USB Status and Control

Register located at I/O address 0x13 as shown in Figure 6-24.

This is a read/write register. All reserved bits must be written

to zero. All bits in the register are cleared during reset.

Bit 6 (Data 1/0) must be set to either 0 or 1 depending on the

data packet’s toggle state, 0 for DATA0, 1 for DATA1.

After the transmit data has been loaded into the FIFO, bit 6

should be set according to the data toggle state and bit 7 set

b7

b6

b5

b4

ENOUTS

R/W

b3

STATOUTS

R/W

b2

b1

FORCEK

R/W

b0

BUSACT

R/W

Reserved

FORCEJ

0

Figure 6-24. USB Status and Control Register (USB SCR – Address 0x13)

Bit 0 is set by the SIE if any USB activity except idle (D+ LOW,

D– HIGH) is detected. The user program should check and

clear this bit periodically to detect any loss of bus activity.

Writing a 0 to this bit clears it. Writing a 1 does not change its

value.

zero. However, for resume signaling, force a J state for one

instruction before forcing resume.

Bit 3 is used to automatically respond to the Status stage OUT

of a control read transfer on Endpoint 0. A valid Status stage

OUT contains a DATA1 packet with 0 bytes of data. If the Statu-

sOuts bit is set, the USB engine responds to a valid Status

stage OUT with an ACK, and any other OUT with a STALL.

Bit 1 is used to force the on-chip USB transmitter to the K state

which sends a Resume signal to the host. Bit 2 is used to force

the transmitter to the J state. This bit should normally be set to

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CY7C63001A

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The data is not written into the FIFO when this bit is set. This

bit is cleared when a SETUP token is received by Endpoint 0.

6.10.1 Low-Speed Driver Characteristics

The CY7C630/101A devices use a differential output driver to

drive the Low-speed USB data signal onto the USB cable, as

shown in Figure 6-25. The output swings between the differ-

ential HIGH and LOW state are well balanced to minimize

signal skew. Slew rate control on the driver minimizes the

radiated noise and cross talk on the USB cable. The driver’s

outputs support three-state operation to achieve bidirectional

half duplex operation. The CY7C630/101A driver tolerates a

voltage on the signal pins of –0.5V to 3.8V with respect to local

ground reference without damage. The driver tolerates this

voltage for 10.0 µs while the driver is active and driving, and

tolerates this condition indefinitely when the driver is in its high-

impedance state.

Bit 4 is used to enable the receiving of Endpoint 0 OUT

packets. When this bit is set to 1, the data from an OUT trans-

action is written into the Endpoint 0 FIFO. If this bit is 0, data

is not written to the FIFO and the SIE responds with a NAK.

This bit is cleared following a SETUP or ACKed OUT trans-

action. Note. After firmware decodes a SETUP packet and

prepares for a subsequent OUT transaction by setting bit 4, bit

4 is not cleared until the hand-shake phase of an ACKed OUT

transaction (a NAKed OUT transaction does not clear this bit).

6.10

USB Physical Layer Characteristics

The following section describes the CY7C630/101A

compliance to the Chapter 7 Electrical section of the USB

Specification, Revision 1.1. The section contains all signaling,

power distribution, and physical layer specifications necessary

to describe a low- speed USB function.

A low-speed USB connection is made through an unshielded,

untwisted wire cable a maximum of three meters in length. The

rise and fall time of the signals on this cable are well controlled

to reduce RFI emissions while limiting delays, signaling skews

and distortions. The CY7C630/101A driver reaches the

specified static signal levels with smooth rise and fall times,

resulting in minimal reflections and ringing when driving the

USB cable. This cable and driver are intended to be used only

on network segments between low-speed devices and the

ports to which they are connected.

One Bit

Time

(1.5Mb/s)

Signal pins

pass output

spec levels

with minimal

reflections and

ringing

V_SE(max)

Driver

Signal Pins

V_SE(min)

VSS

Figure 6-25. Low-speed Driver Signal Waveforms

6.10.2 Receiver Characteristics

the differential data lines are outside the common mode range,

as shown in Figure 6-26. The receiver tolerates static input

voltages between –0.5V and 3.8V with respect to its local

ground reference without damage. In addition to the differ-

ential receiver, there is a single-ended receiver for each of the

two data lines. The single-ended receivers have a switching

threshold between 0.8V and 2.0V (TTL inputs).

The CY7C630/101A has a differential input receiver which is

able to accept the USB data signal. The receiver features an

input sensitivity of at least 200 mV when both differential data

inputs are in the range of at least 0.8V to 2.5V with respect to

its local ground reference. This is the common mode input

voltage range. Proper data reception is also guaranteed when

Document #: 38-08026 Rev. *A

Page 16 of 25

CY7C63001A

CY7C63101A

1.0

0.8

0.6

0.4

0.2

0.0

0.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2

Common Mode Input Voltage (volts)

Figure 6-26. Differential Input Sensitivity Over Entire Common Mode Range

trace capacitance + integrated cable capacitance) must be

less than 250 pF. As Cypress D+/D– transceiver input capac-

itance is 20pF max, up to 230 pF of capacitance is allowed for

in the low speed device’s integrated cable and PCB. If the

cable + PCB capacitance on the D+/D– lines will be greater

than approximately 230 pF, an external 3.3V regulator must be

used as shown in Figure 6-28.

6.11

External USB Pull-Up Resistor

The USB system specifies that a pull-up resistor be connected

on the D– pin of low-speed peripherals as shown in Figure 6-

27. To meet the USB 1.1 spec (section 7.1.6), which states that

the termination must charge the D– line from 0 to 2.0 V in

2.5 µs, the total load capacitance on the D+/D– lines of the

low-speed USB device (Cypress device capacitance + PCB

Port0

Switches,

Devices, Etc.

Switches,

Devices, Etc.

Port1

D+

Port1

VSS

VPP

D–

VCC

XTALOUT

CEXT

XTALIN

7.5kW±1%

+4.35V (min)

For Cext

Wake-up Mode

0.1µF

6-MHz

Resonator

4.7 µF

Figure 6-27. Application Showing 7.5kW ±1% Pull-Up Resistor

+3.3V

3.3V

Reg

Port0

Switches,

Devices, Etc.

Switches,

Devices, Etc.

0.1 µF

Port1

D+

D–

Port1

1.5±kW

V

SS

PP

V

CEXT

CC

XTALIN

XTALOUT

+4.35V (min.)

For Cext

Wake-up Mode

0.1µF

6-MHz

Resonator

4.7 µF

Figure 6-28. Application Showing 1.5-kW ±5% Pull-Up Resistor

Document #: 38-08026 Rev. *A

Page 17 of 25

CY7C63001A

CY7C63101A

6.12

Table 6-5. Instruction Set Map

MNEMONIC operand

Instruction Set Summary

opcode

00

cycles

MNEMONIC

operand

opcode

20

cycles

HALT

7

NOP

4

7

8

4

7

8

5

4

5

6

7

8

7

8

7

8

6

4

8

ADD A,expr

data

direct

index

data

01

02

03

04

05

06

07

08

09

0A

0B

0C

0D

OE

0F

10

11

4

INC A

acc

21

22

23

24

25

26

27

28

29

2A

2B

2C

2D

2E

2F

30

31

32

33

34

35

36

37

38

39

3A

3B

3C

3D

3E

3F

ADD A,[expr]

ADD A,[X+expr]

ADC A,expr

6

7

4

6

7

4

6

7

4

6

7

4

6

7

4

6

7

4

6

7

5

7

8

4

5

6

4

5

INC X

x

INC [expr]

INC [X+expr]

DEC A

direct

index

acc

ADC A,[expr]

ADC A,[X+expr]

SUB A,expr

direct

index

data

DEC X

x

DEC [expr]

DEC [X+expr]

IORD expr

IOWR expr

POP A

direct

index

address

SUB A,[expr]

SUB A,[X+expr]

SBB A,expr

direct

index

data

SBB A,[expr]

SBB A,[X+expr]

OR A,expr

direct

index

data

POP X

PUSH A

OR A,[expr]

direct

index

data

PUSH X

OR A,[X+expr]

AND A,expr

SWAP A,X

SWAP A,DSP

MOV [expr],A

MOV [X+expr],A

OR [expr],A

OR [X+expr],A

AND [expr],A

AND [X+expr],A

XOR [expr],A

XOR [X+expr],A

IOWX [X+expr]

CPL

AND A,[expr]

AND A,[X+expr]

XOR A,expr

XOR A,[expr]

XOR A,[X+expr]

CMP A,expr

CMP A,[expr]

CMP A,[X+expr]

MOV A,expr

MOV A,[expr]

MOV A,[X+expr]

MOV X,expr

MOV X,[expr]

IPRET

direct

index

data

direct

index

direct

index

direct

index

direct

index

12

13

14

15

16

17

18

19

1A

1B

1C

1D

1E

1F

direct

index

data

direct

index

data

direct

index

data

ASL

ASR

direct

addr

RLC

13

4

RRC

XPAGE

RET

JMP

CALL

JZ

addr

8x

9x

Ax

Bx

5

JC

addr

Cx

Dx

Ex

Fx

5

7

10

5

JNC

JACC

INDEX

JNZ

5

14

Document #: 38-08026 Rev. *A

Page 18 of 25

CY7C63001A

CY7C63101A

DC Voltage Applied to Outputs in

7.0

Absolute Maximum Ratings

High-Z state ......................................... –0.5V to +V_CC+0.5V

Max. Output Current into Port 1 Pins .......................... 60 mA

Max. Output Current into Non-Port 1 Pins.................. 10 mA

Power Dissipation..................................................... 300 mW

Static Discharge Voltage .......................................... >2000V

Latch-up Current^[1]................................................ > 200 mA

Storage Temperature .................................–65°C to +150°C

Ambient Temperature with Power Applied......–0°C to +70°C

Supply Voltage on V_CCRelative to V_SS......... –0.5V to +7.0V

DC Input Voltage................................... –0.5V to +V_CC+0.5V

8.0

Electrical Characteristics f_OSC= 6 MHz; Operating Temperature = 0 to 70°C, V_CC= 4.0 to 5.25V

Parameter

Description

General

Conditions

Resonator off, D– > Voh min^[2]

Ceramic resonator

Min.

Max.

Unit

I_CC

V_CCOperating Supply Current

Supply Current—Suspend Mode

Supply Current—Start-up Mode

Programming Voltage (disabled)

Resonator Start-up Interval

Watchdog Timer Period

25

20

mA

µA

mA

V

I_SB1

I_SB2

4

V_PP

t_start

t_watch

–0.4

0.4

256

µs

7.168 8.192

ms

Power On Reset

[3, 4]

t_VCCS

V_CCSlew

Linear ramp on V_CCpin to V_CC

0.010

2.8

1000

ms

USB Interface

V_oh

V_ol

Static Output High

15kΩ ± 5% to Gnd^[5,6]

See Notes 5 and 6

|(D+)–(D–)|, and Figure 6-26

Figure 6-26

3.6

0.3

V

Static Output Low

V_di

Differential Input Sensitivity

Differential Input Common Mode Range

Single Ended Receiver Threshold

Transceiver Input Capacitance

Data Line (D+, D–) Leakage

External Bus Pull-up Resistance, D– pin

External Bus Pull-down Resistance

General Purpose I/O Interface

Pull-up Resistance

0.2

0.8

V

V_cm

V_se

C_in

2.5

2.0

20

V

D+ to Vss; D- to Vss

pF

µA

kΩ

I_lo

0 V <(D+, D–)<3.3 V, Hi-Z State

1.5 kΩ ± 5% to 3.3V supply

7.5 kΩ ± 1% to Vcc^[7]

15 kΩ ± 5%

–10

10

R_pu1

R_pu2

R_pd

1.425 1.575

7.425 7.575

14.25 15.75

R_up

8

24

0.3

1.5

4.8

24

kΩ

mA

I_sink0(0)

I_sink0(F)

I_sink1(0)

I_sink1(F)

Port 0 Sink Current (0), lowest current

Port 0 Sink Current (F), highest current

Port 1 Sink Current (0), lowest current

Port 1 Sink Current (F), highest current

Vout = 2.0V DC, Port 0 only^[5]

Vout = 2.0V DC, Port 1 only^[5]

0.1

0.5

1.6

Vout = 2.0V DC, Port 1 only^[5]

8

5

mA

Vout = 0.4V DC, Port 1 only^[5]

I_range

I_lin

T_ratio

t_sink

Sink Current max./min.

Vout = 2.0V DC, Port 0 or 1^{[5, 8]}

Port 0 or Port 1^[11]

Vout = 2.0V^[12]

4.5

5.5

0.5

19.6

0.8

60

Differential Nonlinearity

l_SB

Tracking Ratio Port1 to Port0

Current Sink Response Time

Port 1 Max Sink Current

14.4

Full scale transition

µs

I_max

Summed over all Port 1 bits

mA

Notes:

1. All pins specified for >200 mA positive and negative injection, except P1.0 is specified for >50 mA negative injection.

2. Cext at V_CCor Gnd, Port 0 and Port1 at V_CC

.

3. Part powers up in suspend mode, able to be reset by USB Bus Reset.

4. POR may re-occur whenever V_CCdrops to approximately 2.5V.

5. Level guaranteed for range of V_CC= 4.35V to 5.25V.

6. With R_pu1of 1.5 KW±5% on D– to 3.3V regulator.

7. Maximum matched capacitive loading allowed on D+ and D– (including USB cable and host/hub) is approximately 230 pF.

8. I_range= I_sink(F)/I_{sink(0 )}for each port 0 or 1 output.

Document #: 38-08026 Rev. *A

Page 19 of 25

CY7C63001A

CY7C63101A

8.0

Electrical Characteristics f_OSC= 6 MHz; Operating Temperature = 0 to 70°C, V_CC= 4.0 to 5.25V (continued)

Parameter

Description

Port 1 & Cext Sink Mode Dissipation

Input Threshold Voltage

Conditions

Min.

Max.

25

Unit

mW

V_CC

µA

P_max

V_ith

Per pin

All ports and Cext^[13]

Port 0 and Port 1^[14]

Cext Pin Only^[14]

45%

6%

65%

12%

30%

1

V_H

Input Hysteresis Voltage

V_HCext

Iin

Input Hysteresis Voltage, Cext

Input Leakage Current, GPIO Pins

Input Leakage Current, Cext Pin

Sink Current, Cext Pin

12%

–1

[15]

Port 0 and Port 1, Vout = 0 or V_CC

V_Cext= 0 or V_CC

I_inCx

I_Cext

V_ol1

V_ol2

50

nA

V_Cext= V_CC

6

18

mA

V

Output LOW Voltage, Cext Pin

V_CC= Min., I_ol= 2 mA

V_CC= Min., I_ol= 5 mA

0.4

2.0

V

9.0

Switching Characteristics

Parameter

Description

Clock

Conditions

Min.

Max.

Unit

t_CYC

t_CH

t_CL

Input Clock Cycle Time

Clock HIGH Time

166.67

ns

0.45 t_CYC

Clock LOW Time

USB Driver Characteristics

USB Data Transition Rise Time

USB Data Transition Fall Time

Rise/Fall Time Matching

Output Signal Crossover Voltage

USB Data Timing

t_r

See Notes 5, 6, and 9

75

300

125

2.0

ns

%

V

t_f

See Notes 5, 6, and 9

t_rfm

V_crs

t_r/t_f

80

See Note 5

1.3

t_drate

t_djr1

t_djr2

t_deop

t_eopr

t_lst

Low Speed Data Rate

Receiver Data Jitter Tolerance

Ave. Bit Rate (1.5 Mb/s ± 1.5%)

To Next Transition, Figure 9-3^[10]

For Paired Transitions, Figure 9-3^[10]

1.4775

–75

1.5225 Mb/s

75

45

ns

–45

Differential to EOP Transition Skew Figure 9-4^[10]

–40

100

EOP Width at Receiver

Accepts as EOP^[10]

670

Width of SE0 Interval During

Differential Transition

210

t_eopt

t_udj1

t_udj2

Source EOP Width

1.25

–95

1.50

95

µs

ns

Differential Driver Jitter

To next transition, Figure 9-5

To paired transition, Figure 9-5

–150

150

Notes:

9. C_loadof 200 (75 ns) to 600 pF (300 ns).

10. Measured at crossover point of differential data signals.

11. Measured as largest step size vs. nominal according to measured full scale and zero programmed values

12. T_ratio= I_sink1(n)/I_sink0(n)for the same n.

13. Low to High transition.

14. This parameter is guaranteed, but not tested.

15. With Ports configured in Hi-Z mode.

Document #: 38-08026 Rev. *A

Page 20 of 25

CY7C63001A

CY7C63101A

t_CYC

t_CH

CLOCK

t_CL

Figure 9-1. Clock Timing

t_f

t_r

D+

D−

V_oh

90%

V_crs

V_ol

10%

Figure 9-2. USB Data Signal Timing and Voltage Levels

T_PERIOD

Differential

Data Lines

T_JR

T_JR1

T_JR2

Consecutive

Transitions

N * T_PERIOD+ T_JR1

Paired

Transitions

N * T_PERIOD+ T_JR2

Figure 9-3. Receiver Jitter Tolerance

T_PERIOD

Crossover

Point Extended

Crossover

Point

Differential

Data Lines

Diff. Data to

SE0 Skew

N * T_PERIOD+ T_DEOP

Source EOP Width: T_EOPT

Receiver EOP Width: T_EOPR1, T_EOPR2

Figure 9-4. Differential to EOP Transition Skew and EOP Width

Document #: 38-08026 Rev. *A

Page 21 of 25

CY7C63001A

CY7C63101A

T_PERIOD

Differential

Crossover

Points

Data Lines

Consecutive

Transitions

N * T_PERIOD+ T_xJR1

Paired

Transitions

N * T_PERIOD+ T_xJR2

Figure 9-5. Differential Data Jitter

10.0

Ordering Information

EPROM

Number of

Package

Name

Operating

Range

Ordering Code

Size

4KB

GPIO

Package Type

20-Pin (300-Mil) PDIP

CY7C63001A-PC

CY7C63001A-PXC

CY7C63001A-SC

CY7C63001A-SXC

CY7C63101A-QC

CY7C63101A-QXC

CY7C63001A-XC

CY7C63001A-XWC

12

P5

S5

Q13

–

Commercial

12

20-Pin (300-Mil) PDIP Lead-free

20-Pin (300-Mil) SOIC

12

20-Pin (300-Mil) SOIC Lead-free

24-Pin (150-Mil) QSOP

24-Pin (150-Mil) QSOP Lead-free

DIE Form

16

–

DIE Form Lead-free

11.0

Package Diagrams

20-Lead (300-Mil) Molded DIP P5

51-85011-*A

Document #: 38-08026 Rev. *A

Page 22 of 25

CY7C63001A

CY7C63101A

11.0

Package Diagrams (continued)

24-Lead Quarter Size Outline Q13

51-85055-*B

20-Lead (300-Mil) Molded SOIC S5

51-85024-*B

Document #: 38-08026 Rev. *A

Page 23 of 25

CY7C63001A

CY7C63101A

11.0

Package Diagrams (continued)

51-85025-*B

DIE FORM

4

3

2

1

24 23 22 21

5

20

19

18

17

6

7

8

Y

9

10 11 12 13 14 15 16

(0,0)

X

Table 11-1 below shows the die pad coordinates for the

CY7C63001A-XC and CY7C63001A-XWC. The center

location of each bond pad is relative to the bottom left corner

of the die which has coordinate (0,0).

Table 11-1. CY7C63001A-XC Probe Pad Coordinates in Microns ((0,0) to Bond Pad Centers)

X

Y

X

Y

Pad #

Name

(microns)

Pad #

13

Name

(microns)

1

2

Port00

Port01

Port02

Port03

Port10

Port12

Port14

Port16

Vss

676.00

507.35

338.70

170.05

120.10

148.50

278.30

414.25

653.45

2325.40

2132.30

1962.90

1765.20

1595.80

121.80

Xtlout

Vcc

794.85

1033.55

1129.75

1451.70

1446.10

1395.65

1227.00

1058.35

889.7

121.80

14

3

15

D-

121.80

4

16

D+

121.80

5

17

Port17

Port15

Port13

Port11

Port07

Port06

Port05

Port04

1595.80

1765.20

1962.90

2132.30

2325.40

6

18

7

19

8

20

9

21

10

11

12

Vpp

121.80

22

Cext

121.80

23

Xtalin

121.80

24

All product and company names mentioned in this document are the trademarks of their respective holders.

Document #: 38-08026 Rev. *A

Page 24 of 25

of any circuitry other than circuitry embodied in a Cypress product. Nor does it convey or imply any license under patent or other rights. Cypress products are not warranted nor intended to be

used for medical, life support, life saving, critical control or safety applications, unless pursuant to an express written agreement with Cypress. Furthermore, Cypress does not authorize its

products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress

CY7C63001A

CY7C63101A

Document History Page

Document Title: CY7C63001A, CY7C63101A Universal Serial Bus Microcontroller

Document Number: 38-08026

Orig. of

REV.

**

ECN NO. Issue Date Change

Description of Change

116223

276070

06/12/02

See ECN

DSG

BON

Change from Spec number: 38-00662 to 38-08026

*A

Added die form and bond pad information. Added lead-free packages.

Removed obsolete packages and their references.

Document #: 38-08026 Rev. *A

Page 25 of 25


型号：	CY7C63101A-QXC
厂家：	CYPRESS
描述：	Universal Serial Bus Microcontroller 通用串行总线的微控制器微控制器和处理器外围集成电路光电二极管可编程只读存储器时钟
文件：	总25页 (文件大小：500K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

CY7C63101A-QXC [CYPRESS]

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