935319894557 [NXP]
RISC Microcontroller;型号: | 935319894557 |
厂家: | NXP |
描述: | RISC Microcontroller 微控制器 外围集成电路 |
文件: | 总80页 (文件大小:1239K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Document Number K10P144M120SF3
Rev. 7, 02/2018
NXP Semiconductors
Data Sheet: Technical Data
K10P144M120SF3
K10 Sub-Family
Supports the following:
MK10FX512VLQ12,
MK10FN1M0VLQ12,
MK10FX512VMD12,
MK10FN1M0VMD12
Key features
• Security and integrity modules
– Hardware CRC module to support fast cyclic
redundancy checks
– 128-bit unique identification (ID) number per chip
• Operating Characteristics
– Voltage range: 1.71 to 3.6 V
– Flash write voltage range: 1.71 to 3.6 V
– Temperature range (ambient): -40 to 105°C
• Human-machine interface
– Low-power hardware touch sensor interface (TSI)
– General-purpose input/output
• Performance
– Up to 120 MHz Arm® Cortex®-M4 core with DSP
instructions delivering 1.25 Dhrystone MIPS per
MHz
• Analog modules
– Four 16-bit SAR ADCs
– Programmable gain amplifier (PGA) (up to x64)
integrated into each ADC
– Two 12-bit DACs
– Four analog comparators (CMP) containing a 6-bit
DAC and programmable reference input
– Voltage reference
• Memories and memory interfaces
– Up to 1024 KB program flash memory on non-
FlexMemory devices
– Up to 512 KB program flash memory on
FlexMemory devices
– Up to 512 KB FlexNVM on FlexMemory devices
– 16 KB FlexRAM on FlexMemory devices
– Up to 128 KB RAM
• Timers
– Programmable delay block
– Two 8-channel motor control/general purpose/PWM
timers
– Serial programming interface (EzPort)
– FlexBus external bus interface
– NAND flash controller interface
– Two 2-channel quadrature decoder/general purpose
timers
– Periodic interrupt timers
– 16-bit low-power timer
– Carrier modulator transmitter
– Real-time clock
• Clocks
– 3 to 32 MHz crystal oscillator
– 32 kHz crystal oscillator
– Multi-purpose clock generator
• System peripherals
• Communication interfaces
– Two Controller Area Network (CAN) modules
– Three SPI modules
– Multiple low-power modes to provide power
optimization based on application requirements
– Memory protection unit with multi-master
protection
– 32-channel DMA controller, supporting up to 128
request sources
– Two I2C modules
– Six UART modules
– Secure Digital Host Controller (SDHC)
– Two I2S modules
– External watchdog monitor
– Software watchdog
– Low-leakage wakeup unit
NXP reserves the right to change the production detail specifications as may be
required to permit improvements in the design of its products.
Table of Contents
1 Ordering parts.......................................................................................3
6.1.1 Debug trace timing specifications..................................21
6.1.2 JTAG electricals.............................................................22
6.2 System modules........................................................................... 25
6.3 Clock modules............................................................................. 25
6.3.1 MCG specifications........................................................25
6.3.2 Oscillator electrical specifications................................. 27
6.3.3 32 kHz oscillator electrical characteristics.....................29
6.4 Memories and memory interfaces................................................30
6.4.1 Flash (FTFE) electrical specifications........................... 30
6.4.2 EzPort switching specifications..................................... 34
6.4.3 NAND flash controller specifications............................35
6.4.4 Flexbus switching specifications....................................38
6.5 Security and integrity modules.................................................... 41
6.6 Analog..........................................................................................41
6.6.1 ADC electrical specifications.........................................41
6.6.2 CMP and 6-bit DAC electrical specifications................49
6.6.3 12-bit DAC electrical characteristics............................. 51
6.6.4 Voltage reference electrical specifications.....................54
6.7 Timers.......................................................................................... 55
6.8 Communication interfaces........................................................... 55
6.8.1 CAN switching specifications........................................55
6.8.2 DSPI switching specifications (limited voltage range)..56
6.8.3 DSPI switching specifications (full voltage range)........57
6.8.4 Inter-Integrated Circuit Interface (I2C) timing.............. 59
6.8.5 UART switching specifications..................................... 60
6.8.6 SDHC specifications...................................................... 60
6.8.7 I2S/SAI switching specifications................................... 61
6.9 Human-machine interfaces (HMI)...............................................68
6.9.1 TSI electrical specifications........................................... 68
7 Dimensions...........................................................................................69
7.1 Obtaining package dimensions.................................................... 69
8 Pinout................................................................................................... 69
8.1 Pins with active pull control after reset....................................... 69
8.2 K10 Signal Multiplexing and Pin Assignments...........................70
8.3 K10 pinouts..................................................................................76
9 Revision History...................................................................................78
1.1 Determining valid orderable parts............................................... 3
2 Part identification................................................................................. 3
2.1 Description...................................................................................3
2.2 Format..........................................................................................3
2.3 Fields............................................................................................3
2.4 Example....................................................................................... 4
3 Terminology and guidelines.................................................................4
3.1 Definitions................................................................................... 4
3.2 Examples......................................................................................4
3.3 Typical-value conditions..............................................................5
3.4 Relationship between ratings and operating requirements.......... 5
3.5 Guidelines for ratings and operating requirements......................6
4 Ratings..................................................................................................6
4.1 Thermal handling ratings.............................................................6
4.2 Moisture handling ratings............................................................ 7
4.3 ESD handling ratings...................................................................7
4.4 Voltage and current operating ratings..........................................7
5 General................................................................................................. 7
5.1 AC electrical characteristics........................................................ 8
5.2 Nonswitching electrical specifications........................................ 8
5.2.1 Voltage and current operating requirements..................8
5.2.2 LVD and POR operating requirements..........................9
5.2.3 Voltage and current operating behaviors....................... 10
5.2.4 Power mode transition operating behaviors...................12
5.2.5 Power consumption operating behaviors....................... 13
5.2.6 EMC radiated emissions operating behaviors................16
5.2.7 Designing with radiated emissions in mind................... 17
5.2.8 Capacitance attributes.................................................... 17
5.3 Switching specifications.............................................................. 17
5.3.1 Device clock specifications............................................17
5.3.2 General switching specifications....................................18
5.4 Thermal specifications.................................................................19
5.4.1 Thermal operating requirements.................................... 19
5.4.2 Thermal attributes.......................................................... 20
6 Peripheral operating requirements and behaviors................................ 21
6.1 Core modules............................................................................... 21
K10 Sub-Family, Rev. 7, 02/2018
2
NXP Semiconductors
Ordering parts
1 Ordering parts
1.1 Determining valid orderable parts
Valid orderable part numbers are provided on the web. To determine the orderable part
numbers for this device, go to nxp.com and perform a part number search for the
following device numbers: PK10 and MK10
2 Part identification
2.1 Description
Part numbers for the chip have fields that identify the specific part. You can use the
values of these fields to determine the specific part you have received.
2.2 Format
Part numbers for this device have the following format:
Q K## A M FFF T PP CC N
2.3 Fields
This table lists the possible values for each field in the part number (not all combinations
are valid):
Field
Description
Values
Q
Qualification status
• M = Fully qualified, general market flow
• P = Prequalification
K##
A
Kinetis family
• K10
Key attribute
• F = Cortex-M4 w/ DSP and FPU
M
Flash memory type
• N = Program flash only
• X = Program flash and FlexMemory
FFF
Program flash memory size
• 512 = 512 KB
• 1M0 = 1 MB
Table continues on the next page...
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NXP Semiconductors
3
Terminology and guidelines
Field
Description
Values
T
Temperature range (°C)
• V = –40 to 105
• C = –40 to 85
PP
Package identifier
• LQ = 144 LQFP (20 mm x 20 mm)
• MD = 144 MAPBGA (13 mm x 13 mm)
CC
N
Maximum CPU frequency (MHz)
Packaging type
• 12 = 120 MHz
• R = Tape and reel
• (Blank) = Trays
2.4 Example
This is an example part number:
MK10FN1M0VLQ12
3 Terminology and guidelines
3.1 Definitions
Key terms are defined in the following table:
Term
Definition
Rating
A minimum or maximum value of a technical characteristic that, if exceeded, may cause permanent
chip failure:
• Operating ratings apply during operation of the chip.
• Handling ratings apply when the chip is not powered.
NOTE: The likelihood of permanent chip failure increases rapidly as soon as a characteristic
begins to exceed one of its operating ratings.
Operating requirement A specified value or range of values for a technical characteristic that you must guarantee during
operation to avoid incorrect operation and possibly decreasing the useful life of the chip
Operating behavior
A specified value or range of values for a technical characteristic that are guaranteed during
operation if you meet the operating requirements and any other specified conditions
Typical value
A specified value for a technical characteristic that:
• Lies within the range of values specified by the operating behavior
• Is representative of that characteristic during operation when you meet the typical-value
conditions or other specified conditions
NOTE: Typical values are provided as design guidelines and are neither tested nor guaranteed.
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4
NXP Semiconductors
Terminology and guidelines
3.2 Examples
Operating rating:
EXAMPLE
EXAMPLE
Operating requirement:
Operating behavior that includes a typical value:
3.3 Typical-value conditions
Typical values assume you meet the following conditions (or other conditions as
specified):
Symbol
Description
Ambient temperature
Supply voltage
Value
Unit
TA
25
°C
V
VDD
3.3
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NXP Semiconductors
5
Ratings
3.4 Relationship between ratings and operating requirements
Fatal range
Degraded operating range
Normal operating range
Degraded operating range
Fatal range
Expected permanent failure
- No permanent failure
- No permanent failure
- Correct operation
- No permanent failure
Expected permanent failure
- Possible decreased life
- Possible incorrect operation
- Possible decreased life
- Possible incorrect operation
–∞
∞
Operating (power on)
Fatal range
Handling range
Fatal range
Expected permanent failure
No permanent failure
Expected permanent failure
–∞
∞
Handling (power off)
3.5 Guidelines for ratings and operating requirements
Follow these guidelines for ratings and operating requirements:
• Never exceed any of the chip’s ratings.
• During normal operation, don’t exceed any of the chip’s operating requirements.
• If you must exceed an operating requirement at times other than during normal
operation (for example, during power sequencing), limit the duration as much as
possible.
4 Ratings
4.1 Thermal handling ratings
Symbol
TSTG
Description
Min.
–55
—
Max.
150
Unit
°C
Notes
Storage temperature
Solder temperature, lead-free
1
2
TSDR
260
°C
1. Determined according to JEDEC Standard JESD22-A103, High Temperature Storage Life.
2. Determined according to IPC/JEDEC Standard J-STD-020, Moisture/Reflow Sensitivity Classification for Nonhermetic
Solid State Surface Mount Devices.
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NXP Semiconductors
General
4.2 Moisture handling ratings
Symbol
Description
Min.
Max.
Unit
Notes
MSL
Moisture sensitivity level
—
3
—
1
1. Determined according to IPC/JEDEC Standard J-STD-020, Moisture/Reflow Sensitivity Classification for Nonhermetic
Solid State Surface Mount Devices.
4.3 ESD handling ratings
Symbol
VHBM
VCDM
ILAT
Description
Min.
-2000
-500
Max.
+2000
+500
Unit
V
Notes
Electrostatic discharge voltage, human body model
Electrostatic discharge voltage, charged-device model
Latch-up current at ambient temperature of 105°C
1
2
3
V
-100
+100
mA
1. Determined according to JEDEC Standard JESD22-A114, Electrostatic Discharge (ESD) Sensitivity Testing Human Body
Model (HBM).
2. Determined according to JEDEC Standard JESD22-C101, Field-Induced Charged-Device Model Test Method for
Electrostatic-Discharge-Withstand Thresholds of Microelectronic Components.
3. Determined according to JEDEC Standard JESD78, IC Latch-Up Test.
4.4 Voltage and current operating ratings
Symbol
VDD
Description
Min.
–0.3
—
Max.
3.8
Unit
V
Digital supply voltage1
Digital supply current
IDD
300
5.5
mA
V
VDIO
Digital input voltage (except RESET, EXTAL0/XTAL0, and
EXTAL1/XTAL1) 2
–0.3
VAIO
Analog3, RESET, EXTAL0/XTAL0, and EXTAL1/XTAL1 input
voltage
–0.3
VDD + 0.3
V
ID
Maximum current single pin limit (applies to all digital pins)
Analog supply voltage
–25
VDD – 0.3
–0.3
25
VDD + 0.3
3.8
mA
V
VDDA
VBAT
RTC battery supply voltage
V
1. It applies for all port pins.
2. It covers digital pins.
3. Analog pins are defined as pins that do not have an associated general purpose I/O port function.
5 General
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NXP Semiconductors
7
General
5.1 AC electrical characteristics
Unless otherwise specified, propagation delays are measured from the 50% to the 50%
point, and rise and fall times are measured at the 20% and 80% points, as shown in the
following figure.
High
Low
VIH
80%
50%
20%
Input Signal
Midpoint1
VIL
Fall Time
Rise Time
The midpoint is VIL + (VIH - VIL) / 2
Figure 1. Input signal measurement reference
All digital I/O switching characteristics assume:
1. output pins
• have CL=30pF loads,
• are configured for fast slew rate (PORTx_PCRn[SRE]=0), and
• are configured for high drive strength (PORTx_PCRn[DSE]=1)
2. input pins
• have their passive filter disabled (PORTx_PCRn[PFE]=0)
5.2 Nonswitching electrical specifications
5.2.1 Voltage and current operating requirements
Table 1. Voltage and current operating requirements
Symbol
VDD
Description
Min.
1.71
1.71
–0.1
–0.1
1.71
Max.
3.6
3.6
0.1
0.1
3.6
Unit
V
Notes
Supply voltage
VDDA
Analog supply voltage
V
VDD – VDDA VDD-to-VDDA differential voltage
VSS – VSSA VSS-to-VSSA differential voltage
V
V
VBAT
VIH
RTC battery supply voltage
V
Input high voltage (digital pins)
0.7 × VDD
—
V
Table continues on the next page...
K10 Sub-Family, Rev. 7, 02/2018
8
NXP Semiconductors
General
Notes
Table 1. Voltage and current operating requirements (continued)
Symbol
Description
• 2.7 V ≤ VDD ≤ 3.6 V
Min.
Max.
Unit
0.75 × VDD
—
V
• 1.7 V ≤ VDD ≤ 2.7 V
VIL
Input low voltage (digital pins)
• 2.7 V ≤ VDD ≤ 3.6 V
—
—
0.35 × VDD
0.3 × VDD
V
V
• 1.7 V ≤ VDD ≤ 2.7 V
VHYS
IICDIO
Input hysteresis (digital pins)
0.06 × VDD
-5
—
—
V
Digital pin negative DC injection current —
single pin
1
3
mA
• VIN < VSS-0.3V
IICAIO
Analog2, EXTAL0/XTAL0, and EXTAL1/
XTAL1 pin DC injection current — single pin
mA
• VIN < VSS-0.3V (Negative current
injection)
-5
—
—
+5
• VIN > VDD+0.3V (Positive current
injection)
IICcont
Contiguous pin DC injection current —
regional limit, includes sum of negative
injection currents or sum of positive injection
currents of 16 contiguous pins
-25
—
—
mA
+25
• Negative current injection
• Positive current injection
VODPU
VRAM
Open drain pullup voltage level
VDD
1.2
VDD
—
V
V
V
4
VDD voltage required to retain RAM
VRFVBAT
VBAT voltage required to retain the VBAT
register file
VPOR_VBAT
—
1. All 5 V tolerant digital I/O pins are internally clamped to VSS through an ESD protection diode. There is no diode
connection to VDD. If VIN is less than VDIO_MIN, a current limiting resistor is required. If VIN greater than VDIO_MIN
(=VSS-0.3V) is observed, then there is no need to provide current limiting resistors at the pads. The negative DC injection
current limiting resistor is calculated as R=(VDIO_MIN-VIN)/|IICDIO|.
2. Analog pins are defined as pins that do not have an associated general purpose I/O port function. Additionally, EXTAL and
XTAL are analog pins.
3. All analog pins are internally clamped to VSS and VDD through ESD protection diodes. If VIN is less than VAIO_MIN or greater
than VAIO_MAX, a current limiting resistor is required. The negative DC injection current limiting resistor is calculated as
R=(VAIO_MIN-VIN)/|IICAIO|. The positive injection current limiting resistor is calculated as R=(VIN-VAIO_MAX)/|IICAIO|. Select the
larger of these two calculated resistances if the pin is exposed to positive and negative injection currents.
4. Open drain outputs must be pulled to VDD.
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9
General
5.2.2 LVD and POR operating requirements
Table 2. LVD and POR operating requirements
Symbol Description
Min.
0.8
Typ.
1.1
Max.
1.5
Unit
V
Notes
VPOR
Falling VDD POR detect voltage
VLVDH
Falling low-voltage detect threshold — high
range (LVDV=01)
2.48
2.56
2.64
V
Low-voltage warning thresholds — high range
• Level 1 falling (LVWV=00)
1
VLVW1H
VLVW2H
VLVW3H
VLVW4H
2.62
2.72
2.82
2.92
2.70
2.80
2.90
3.00
2.78
2.88
2.98
3.08
V
V
V
V
• Level 2 falling (LVWV=01)
• Level 3 falling (LVWV=10)
• Level 4 falling (LVWV=11)
VHYSH
VLVDL
Low-voltage inhibit reset/recover hysteresis —
high range
—
80
—
mV
V
Falling low-voltage detect threshold — low range
(LVDV=00)
1.54
1.60
1.66
Low-voltage warning thresholds — low range
• Level 1 falling (LVWV=00)
1
VLVW1L
VLVW2L
VLVW3L
VLVW4L
1.74
1.84
1.94
2.04
1.80
1.90
2.00
2.10
1.86
1.96
2.06
2.16
V
V
V
V
• Level 2 falling (LVWV=01)
• Level 3 falling (LVWV=10)
• Level 4 falling (LVWV=11)
VHYSL
Low-voltage inhibit reset/recover hysteresis —
low range
—
60
—
mV
VBG
tLPO
Bandgap voltage reference
Internal low power oscillator period
factory trimmed
0.97
900
1.00
1.03
V
1000
1100
μs
1. Rising thresholds are falling threshold + hysteresis voltage
Table 3. VBAT power operating requirements
Symbol Description
Min.
Typ.
Max.
Unit
Notes
VPOR_VBAT Falling VBAT supply POR detect voltage
0.8
1.1
1.5
V
5.2.3 Voltage and current operating behaviors
Table 4. Voltage and current operating behaviors
Symbol Description
VOH Output high voltage — high drive strength
Min.
Typ.
Max.
Unit
Notes
—
—
• 2.7 V ≤ VDD ≤ 3.6 V, IOH = -9mA
• 1.71 V ≤ VDD ≤ 2.7 V, IOH = -3mA
VDD – 0.5
VDD – 0.5
—
—
V
V
Table continues on the next page...
K10 Sub-Family, Rev. 7, 02/2018
10
NXP Semiconductors
General
Notes
Table 4. Voltage and current operating behaviors (continued)
Symbol Description
Output high voltage — low drive strength
Min.
Typ.
Max.
Unit
—
—
• 2.7 V ≤ VDD ≤ 3.6 V, IOH = -2mA
• 1.71 V ≤ VDD ≤ 2.7 V, IOH = -0.6mA
VDD – 0.5
VDD – 0.5
—
—
V
V
IOHT
Output high current total for all ports
—
—
—
—
100
100
mA
mA
IOHT_io60 Output high current total for fast digital ports
VOL
Output low voltage — high drive strength
• 2.7 V ≤ VDD ≤ 3.6 V, IOL = 10 mA
• 1.71 V ≤ VDD ≤ 2.7 V, IOL = 5 mA
—
—
—
—
0.5
0.5
V
V
Output low voltage — low drive strength
• 2.7 V ≤ VDD ≤ 3.6 V, IOL = 2 mA
• 1.71 V ≤ VDD ≤ 2.7 V, IOL = 1 mA
—
—
—
—
0.5
0.5
V
V
IOLT
Output low current total for all ports
—
—
—
—
100
100
mA
mA
IOLT_io60 Output low current total for fast digital ports
IINA
Input leakage current, analog pins and digital
pins configured as analog inputs
1, 2
• VSS ≤ VIN ≤ VDD
• All pins except EXTAL32, XTAL32,
EXTAL, XTAL
—
—
—
0.002
0.004
0.075
0.5
1.5
10
μA
μA
μA
• EXTAL (PTA18) and XTAL (PTA19)
• EXTAL32, XTAL32
IIND
Input leakage current, digital pins
• VSS ≤ VIN ≤ VIL
2, 3
• All digital pins
—
0.002
0.5
μA
• VIN = VDD
—
—
0.002
0.004
0.5
1
μA
μA
• All digital pins except PTD7
• PTD7
IIND
Input leakage current, digital pins
• VIL < VIN < VDD
• VDD = 3.6 V
2, 3, 4
—
—
—
—
18
12
8
26
19
13
6
μA
μA
μA
μA
• VDD = 3.0 V
• VDD = 2.5 V
• VDD = 1.7 V
3
IIND
Input leakage current, digital pins
• VDD < VIN < 5.5 V
2, 3
2, 5
—
1
50
48
μA
kΩ
ZIND
Input impedance examples, digital pins
—
—
Table continues on the next page...
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11
General
Table 4. Voltage and current operating behaviors (continued)
Symbol Description
• VDD = 3.6 V
Min.
Typ.
Max.
Unit
Notes
—
—
55
kΩ
• VDD = 3.0 V
• VDD = 2.5 V
• VDD = 1.7 V
—
—
—
—
57
85
kΩ
kΩ
RPU
RPD
Internal pullup resistors
20
20
—
—
50
50
kΩ
kΩ
6
7
Internal pulldown resistors
1. Analog pins are defined as pins that do not have an associated general purpose I/O port function.
2. Digital pins have an associated GPIO port function and have 5V tolerant inputs, except EXTAL and XTAL.
3. Internal pull-up/pull-down resistors disabled.
4. Characterized, not tested in production.
5. Examples calculated using VIL relation, VDD, and max IIND: ZIND=VIL/IIND. This is the impedance needed to pull a high
signal to a level below VIL due to leakage when VIL < VIN < VDD. These examples assume signal source low = 0 V. See
Figure 2.
6. Measured at VDD supply voltage = VDD min and Vinput = VSS
7. Measured at VDD supply voltage = VDD min and Vinput = VDD
Figure 2. 5 V Tolerant Input IIND Parameter
5.2.4 Power mode transition operating behaviors
All specifications except tPOR, and VLLSx→RUN recovery times in the following table
assume this clock configuration:
• CPU and system clocks = 100 MHz
• Bus clock = 50 MHz
• FlexBus clock = 50 MHz
• Flash clock = 25 MHz
• MCG mode: FEI
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General
Table 5. Power mode transition operating behaviors
Symbol
Description
Min.
Max.
Unit
Notes
tPOR
After a POR event, amount of time from the point VDD
reaches 1.71 V to execution of the first instruction
across the operating temperature range of the chip.
1
μs
—
—
300
• VDD slew rate ≥ 5.7 kV/s
• VDD slew rate < 5.7 kV/s
1.7 V / (VDD
slew rate)
—
—
—
—
—
—
160
114
114
5.0
5
μs
μs
μs
μs
μs
μs
• VLLS1 → RUN
• VLLS2 → RUN
• VLLS3 → RUN
• LLS → RUN
• VLPS → RUN
• STOP → RUN
4.8
1. Normal boot (FTFE_FOPT[LPBOOT]=1)
5.2.5 Power consumption operating behaviors
Table 6. Power consumption operating behaviors
Symbol
IDDA
Description
Min.
Typ.
Max.
Unit
Notes
Analog supply current
—
—
See note
mA
1
2
IDD_RUN
Run mode current — all peripheral clocks
disabled, code executing from flash
—
—
49.28
49.08
73.85
73.93
mA
mA
• @ 1.8V
• @ 3.0V
IDD_RUN
Run mode current — all peripheral clocks
enabled, code executing from flash
3
—
—
74.43
74.28
99.97
mA
mA
• @ 1.8V
• @ 3.0V
100.41
IDD_WAIT Wait mode high frequency current at 3.0 V — all
peripheral clocks disabled
—
—
34.67
18.03
58.5
mA
mA
2
4
IDD_WAIT Wait mode reduced frequency current at 3.0 V —
all peripheral clocks disabled
41.91
IDD_STOP Stop mode current at 3.0 V
• @ –40 to 25°C
—
—
1.25
2.93
1.62
4.39
mA
mA
Table continues on the next page...
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13
General
Table 6. Power consumption operating behaviors (continued)
Symbol
Description
Min.
Typ.
Max.
Unit
Notes
• @ 70°C
—
7.08
10.74
mA
• @ 105°C
IDD_VLPR Very-low-power run mode current at 3.0 V — all
peripheral clocks disabled
—
—
—
1.03
1.58
0.64
4.48
4.96
4.29
mA
mA
mA
5
5
5
IDD_VLPR Very-low-power run mode current at 3.0 V — all
peripheral clocks enabled
IDD_VLPW Very-low-power wait mode current at 3.0 V
IDD_VLPS Very-low-power stop mode current at 3.0 V
—
—
—
0.22
0.78
2.18
0.38
1.33
3.56
mA
mA
mA
• @ –40 to 25°C
• @ 70°C
• @ 105°C
IDD_LLS
Low leakage stop mode current at 3.0 V
• @ –40 to 25°C
—
—
—
0.22
0.78
2.16
0.37
1.33
3.52
mA
mA
mA
• @ 70°C
• @ 105°C
IDD_VLLS3 Very low-leakage stop mode 3 current at 3.0 V
—
—
—
4.09
20.98
84.95
5.58
28.93
111.15
μA
μA
μA
• @ –40 to 25°C
• @ 70°C
• @ 105°C
IDD_VLLS2 Very low-leakage stop mode 2 current at 3.0 V
—
—
—
2.68
8.8
4.22
10.74
43.61
μA
μA
μA
• @ –40 to 25°C
• @ 70°C
37.28
• @ 105°C
IDD_VLLS1 Very low-leakage stop mode 1 current at 3.0 V
—
—
—
2.46
7.04
4.02
8.99
μA
μA
μA
• @ –40 to 25°C
• @ 70°C
30.68
37.04
• @ 105°C
IDD_VBAT Average current when CPU is not accessing
RTC registers at 3.0 V
6
—
—
—
0.89
1.28
3.10
1.10
1.85
4.30
μA
μA
μA
• @ –40 to 25°C
• @ 70°C
• @ 105°C
1. The analog supply current is the sum of the active or disabled current for each of the analog modules on the device. See
each module's specification for its supply current.
2. 120 MHz core and system clock, 60 MHz bus, 30 MHz FlexBus clock, and 20 MHz flash clock. MCG configured for PEE
mode. All peripheral clocks disabled.
3. 120 MHz core and system clock, 60 MHz bus, 30 MHz FlexBus clock, and 20 MHz flash clock. MCG configured for PEE
mode. All peripheral clocks enabled, but peripherals are not in active operation.
4. 25 MHz core and system clock, 25 MHz bus clock, and 12.5 MHz FlexBus and flash clock. MCG configured for FEI mode.
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General
5. 4 MHz core, system, 2 MHz FlexBus, and 2 MHz bus clock and 0.5 MHz flash clock. MCG configured for BLPE mode. All
peripheral clocks disabled.
6. Includes 32kHz oscillator current and RTC operation.
5.2.5.1 Diagram: Typical IDD_RUN operating behavior
The following data was measured under these conditions:
• MCG in FBE mode for 50 MHz and lower frequencies. MCG in FEE mode at greater
than 50 MHz frequencies. MCG in PEE mode at greater than 100 MHz frequencies.
• No GPIOs toggled
• Code execution from flash with cache enabled
• For the ALLOFF curve, all peripheral clocks are disabled except FTFE
Figure 3. Run mode supply current vs. core frequency
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General
Figure 4. VLPR mode supply current vs. core frequency
5.2.6 EMC radiated emissions operating behaviors
Table 7. EMC radiated emissions operating behaviors for 256MAPBGA
Symbol
Description
Frequency
band (MHz)
Typ.
Unit
Notes
VRE1
VRE2
VRE3
VRE4
Radiated emissions voltage, band 1
Radiated emissions voltage, band 2
Radiated emissions voltage, band 3
Radiated emissions voltage, band 4
0.15–50
50–150
21
24
29
28
dBμV
dBμV
dBμV
dBμV
1, 2, 3
150–500
500–1000
1. Determined according to IEC Standard 61967-1, Integrated Circuits - Measurement of Electromagnetic Emissions, 150
kHz to 1 GHz Part 1: General Conditions and Definitions and IEC Standard 61967-2, Integrated Circuits - Measurement of
Electromagnetic Emissions, 150 kHz to 1 GHz Part 2: Measurement of Radiated Emissions—TEM Cell and Wideband
TEM Cell Method. Measurements were made while the microcontroller was running basic application code. The reported
emission level is the value of the maximum measured emission, rounded up to the next whole number, from among the
measured orientations in each frequency range.
2. VDD = 3.3 V, TA = 25 °C, fOSC = 12 MHz (crystal), fSYS = 72 MHz, fBUS = 72 MHz
3. Determined according to IEC Standard JESD78, IC Latch-Up Test
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NXP Semiconductors
General
5.2.7 Designing with radiated emissions in mind
To find application notes that provide guidance on designing your system to minimize
interference from radiated emissions:
1. Go to www.nxp.com.
2. Perform a keyword search for “EMC design.”
5.2.8 Capacitance attributes
Table 8. Capacitance attributes
Symbol
CIN_A
Description
Min.
—
Max.
Unit
pF
Input capacitance: analog pins
Input capacitance: digital pins
Input capacitance: fast digital pins
7
7
9
CIN_D
—
pF
CIN_D_io60
—
pF
5.3 Switching specifications
5.3.1 Device clock specifications
Table 9. Device clock specifications
Symbol
Description
Min.
Max.
Unit
Notes
Normal run mode
fSYS
fBUS
System and core clock
Bus clock
—
—
—
—
—
120
60
50
25
25
MHz
MHz
MHz
MHz
MHz
FB_CLK
fFLASH
fLPTMR
FlexBus clock
Flash clock
LPTMR clock
VLPR mode1
fSYS
fBUS
System and core clock
Bus clock
—
—
—
—
—
4
4
MHz
MHz
MHz
MHz
MHz
FB_CLK
fFLASH
fLPTMR
FlexBus clock
Flash clock
4
0.5
4
LPTMR clock
1. The frequency limitations in VLPR mode here override any frequency specification listed in the timing specification for any
other module.
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17
General
5.3.2 General switching specifications
These general purpose specifications apply to all pins configured for:
• GPIO signaling
• Other peripheral module signaling not explicitly stated elsewhere
Table 10. General switching specifications
Symbol
Description
Min.
Max.
Unit
Notes
GPIO pin interrupt pulse width (digital glitch filter
disabled) — Synchronous path
1.5
—
Bus clock
cycles
1, 2
GPIO pin interrupt pulse width (digital glitch filter
disabled, analog filter enabled) — Asynchronous path
100
16
—
—
ns
ns
ns
3
3
3
GPIO pin interrupt pulse width (digital glitch filter
disabled, analog filter disabled) — Asynchronous path
External reset pulse width (digital glitch filter disabled)
100
2
—
—
Mode select (EZP_CS) hold time after reset
deassertion
Bus clock
cycles
Port rise and fall time (high drive strength)
• Slew disabled
4
5
6
• 1.71 ≤ VDD ≤ 2.7V
• 2.7 ≤ VDD ≤ 3.6V
—
—
14
8
ns
ns
• Slew enabled
• 1.71 ≤ VDD ≤ 2.7V
• 2.7 ≤ VDD ≤ 3.6V
—
—
36
24
ns
ns
Port rise and fall time (low drive strength)
• Slew disabled
• 1.71 ≤ VDD ≤ 2.7V
• 2.7 ≤ VDD ≤ 3.6V
—
—
14
8
ns
ns
• Slew enabled
• 1.71 ≤ VDD ≤ 2.7V
• 2.7 ≤ VDD ≤ 3.6V
—
—
36
24
ns
ns
tio50
Port rise and fall time (high drive strength)
• Slew disabled
• 1.71 ≤ VDD ≤ 2.7V
• 2.7 ≤ VDD ≤ 3.6V
—
—
7
3
ns
ns
—
—
• Slew enabled
• 1.71 ≤ VDD ≤ 2.7V
• 2.7 ≤ VDD ≤ 3.6V
—
—
28
14
ns
ns
—
—
tio50
Port rise and fall time (low drive strength)
• Slew disabled
-1
Table continues on the next page...
K10 Sub-Family, Rev. 7, 02/2018
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NXP Semiconductors
General
Table 10. General switching specifications (continued)
Symbol
Description
• 1.71 ≤ VDD ≤ 2.7V
• 2.7 ≤ VDD ≤ 3.6V
• Slew enabled
Min.
Max.
Unit
Notes
—
18
ns
—
—
9
ns
—
• 1.71 ≤ VDD ≤ 2.7V
• 2.7 ≤ VDD ≤ 3.6V
—
—
48
24
ns
ns
—
—
tio60
Port rise and fall time (high drive strength)
• Slew disabled
6
• 1.71 ≤ VDD ≤ 2.7V
• 2.7 ≤ VDD ≤ 3.6V
—
—
6
3
ns
ns
—
—
• Slew enabled
• 1.71 ≤ VDD ≤ 2.7V
• 2.7 ≤ VDD ≤ 3.6V
—
—
28
14
ns
ns
—
—
tio60
Port rise and fall time (low drive strength)
• Slew disabled
-1
• 1.71 ≤ VDD ≤ 2.7V
• 2.7 ≤ VDD ≤ 3.6V
—
—
18
6
ns
ns
—
—
• Slew enabled
• 1.71 ≤ VDD ≤ 2.7V
• 2.7 ≤ VDD ≤ 3.6V
—
—
48
24
ns
ns
—
—
1. This is the minimum pulse width that is guaranteed to pass through the pin synchronization circuitry. Shorter pulses may or
may not be recognized. In Stop, VLPS, LLS, and VLLSx modes, the synchronizer is bypassed so shorter pulses can be
recognized in that case.
2. The greater synchronous and asynchronous timing must be met.
3. This is the minimum pulse width that is guaranteed to be recognized as a pin interrupt request in Stop, VLPS, LLS, and
VLLSx modes.
4. 75 pF load
5. 15 pF load
6. 25 pF load
5.4 Thermal specifications
5.4.1 Thermal operating requirements
Table 11. Thermal operating requirements
Symbol
TJ
Description
Min.
–40
–40
Max.
125
Unit
°C
Die junction temperature
Ambient temperature1
TA
105
°C
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19
General
1. Maximum TA can be exceeded only if the user ensures that TJ does not exceed maximum TJ. The simplest method to
determine TJ is:
TJ = TA + RθJA x chip power dissipation
5.4.2 Thermal attributes
Board type
Symbol
Description
144 LQFP
144 MAPBGA
Unit
Notes
Single-layer
(1s)
RθJA
Thermal
resistance,
junction to
ambient (natural
convection)
45
36
36
30
24
50
°C/W
°C/W
°C/W
°C/W
°C/W
1, 2
Four-layer
(2s2p)
RθJA
Thermal
resistance,
junction to
ambient (natural
convection)
30
41
27
17
1,2, 3
1,3
1,3
4
Single-layer
(1s)
RθJMA
RθJMA
RθJB
Thermal
resistance,
junction to
ambient (200 ft./
min. air speed)
Four-layer
(2s2p)
Thermal
resistance,
junction to
ambient (200 ft./
min. air speed)
—
Thermal
resistance,
junction to
board
—
—
RθJC
Thermal
resistance,
junction to case
9
2
10
2
°C/W
°C/W
5
6
ΨJT
Thermal
characterization
parameter,
junction to
package top
outside center
(natural
convection)
1. Junction temperature is a function of die size, on-chip power dissipation, package thermal resistance, mounting site
(board) temperature, ambient temperature, air flow, power dissipation of other components on the board, and board
thermal resistance.
2. Determined according to JEDEC Standard JESD51-2, Integrated Circuits Thermal Test Method Environmental Conditions
—Natural Convection (Still Air) with the single layer board horizontal. Board meets JESD51-9 specification.
3. Determined according to JEDEC Standard JESD51-6, Integrated Circuits Thermal Test Method Environmental Conditions
—Forced Convection (Moving Air) with the board horizontal.
4. Determined according to JEDEC Standard JESD51-8, Integrated Circuit Thermal Test Method Environmental Conditions
—Junction-to-Board.
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NXP Semiconductors
Peripheral operating requirements and behaviors
5. Determined according to Method 1012.1 of MIL-STD 883, Test Method Standard, Microcircuits, with the cold plate
temperature used for the case temperature. The value includes the thermal resistance of the interface material between
the top of the package and the cold plate.
6. Determined according to JEDEC Standard JESD51-2, Integrated Circuits Thermal Test Method Environmental Conditions
—Natural Convection (Still Air).
6 Peripheral operating requirements and behaviors
6.1 Core modules
6.1.1 Debug trace timing specifications
Table 12. Debug trace operating behaviors
Symbol
Tcyc
Twl
Description
Min.
Max.
Unit
MHz
ns
Clock period
Frequency dependent
Low pulse width
High pulse width
Clock and data rise time
Clock and data fall time
Data setup
2
2
—
—
3
Twh
Tr
ns
—
—
3
ns
Tf
3
ns
Ts
—
—
ns
Th
Data hold
2
ns
TRACECLK
T
r
T
f
T
T
wh
wl
T
cyc
Figure 5. TRACE_CLKOUT specifications
TRACE_CLKOUT
TRACE_D[3:0]
Ts
Th
Ts
Th
Figure 6. Trace data specifications
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Peripheral operating requirements and behaviors
6.1.2 JTAG electricals
Table 13. JTAG limited voltage range electricals
Symbol
Description
Min.
Max.
Unit
V
Operating voltage
2.7
3.6
J1
TCLK frequency of operation
• Boundary Scan
MHz
0
0
0
10
25
50
• JTAG and CJTAG
• Serial Wire Debug
J2
J3
TCLK cycle period
TCLK clock pulse width
• Boundary Scan
1/J1
—
ns
50
20
10
—
—
—
ns
ns
ns
• JTAG and CJTAG
• Serial Wire Debug
J4
J5
TCLK rise and fall times
—
20
2.4
—
—
8
3
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Boundary scan input data setup time to TCLK rise
Boundary scan input data hold time after TCLK rise
TCLK low to boundary scan output data valid
TCLK low to boundary scan output high-Z
TMS, TDI input data setup time to TCLK rise
TMS, TDI input data hold time after TCLK rise
TCLK low to TDO data valid
—
—
25
25
—
—
17
17
—
—
J6
J7
J8
J9
J10
J11
J12
J13
J14
1
—
—
100
8
TCLK low to TDO high-Z
TRST assert time
TRST setup time (negation) to TCLK high
Table 14. JTAG full voltage range electricals
Symbol
Description
Min.
Max.
Unit
V
Operating voltage
1.71
3.6
J1
TCLK frequency of operation
• Boundary Scan
MHz
0
0
0
10
20
40
• JTAG and CJTAG
• Serial Wire Debug
J2
J3
TCLK cycle period
TCLK clock pulse width
• Boundary Scan
1/J1
—
ns
50
25
—
—
ns
ns
Table continues on the next page...
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Peripheral operating requirements and behaviors
Table 14. JTAG full voltage range electricals (continued)
Symbol
Description
• JTAG and CJTAG
Min.
12.5
Max.
Unit
—
ns
• Serial Wire Debug
J4
J5
TCLK rise and fall times
—
20
2.4
—
—
8
3
—
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Boundary scan input data setup time to TCLK rise
Boundary scan input data hold time after TCLK rise
TCLK low to boundary scan output data valid
TCLK low to boundary scan output high-Z
TMS, TDI input data setup time to TCLK rise
TMS, TDI input data hold time after TCLK rise
TCLK low to TDO data valid
J6
—
J7
25
25
—
J8
J9
J10
J11
J12
J13
J14
1.4
—
—
100
8
—
22.1
22.1
—
TCLK low to TDO high-Z
TRST assert time
TRST setup time (negation) to TCLK high
—
J2
J4
J3
J3
TCLK (input)
J4
Figure 7. Test clock input timing
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Peripheral operating requirements and behaviors
TCLK
J5
J6
Input data valid
Data inputs
Data outputs
Data outputs
Data outputs
J7
Output data valid
J8
J7
Output data valid
Figure 8. Boundary scan (JTAG) timing
TCLK
TDI/TMS
TDO
J9
J10
Input data valid
J11
Output data valid
J12
J11
TDO
Output data valid
TDO
Figure 9. Test Access Port timing
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NXP Semiconductors
Peripheral operating requirements and behaviors
TCLK
TRST
J14
J13
Figure 10. TRST timing
6.2 System modules
There are no specifications necessary for the device's system modules.
6.3 Clock modules
6.3.1 MCG specifications
Table 15. MCG specifications
Symbol Description
Min.
Typ.
Max.
Unit
Notes
fints_ft Internal reference frequency (slow clock) —
—
32.768
—
kHz
factory trimmed at nominal VDD and 25 °C
fints_t
Internal reference frequency (slow clock) — user
trimmed
31.25
—
—
39.0625
0.6
kHz
Δfdco_res_t Resolution of trimmed average DCO output
frequency at fixed voltage and temperature —
using SCTRIM and SCFTRIM
0.3
%fdco
1
1
1
Δfdco_res_t Resolution of trimmed average DCO output
frequency at fixed voltage and temperature —
using SCTRIM only
—
—
0.2
4.5
0.5
—
%fdco
%fdco
Δfdco_t
Total deviation of trimmed average DCO output
frequency over fixed voltage and temperature
range of 0–70°C
fintf_ft
fintf_t
floc_low
floc_high
Internal reference frequency (fast clock) —
factory trimmed at nominal VDD and 25°C
—
3
4
—
5
MHz
MHz
kHz
kHz
Internal reference frequency (fast clock) — user
trimmed at nominal VDD and 25 °C
—
—
—
Loss of external clock minimum frequency —
RANGE = 00
(3/5) x
fints_t
—
—
Loss of external clock minimum frequency —
RANGE = 01, 10, or 11
(16/5) x
fints_t
FLL
ffll_ref
FLL reference frequency range
31.25
—
39.0625
kHz
Table continues on the next page...
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Peripheral operating requirements and behaviors
Table 15. MCG specifications (continued)
Symbol Description
Min.
Typ.
Max.
Unit
Notes
fdco
DCO output
frequency range
Low range (DRS=00)
640 × ffll_ref
20
20.97
25
MHz
2, 3
Mid range (DRS=01)
1280 × ffll_ref
40
60
80
—
—
—
—
41.94
62.91
83.89
23.99
47.97
71.99
95.98
50
75
100
—
MHz
MHz
MHz
MHz
MHz
MHz
MHz
ps
Mid-high range (DRS=10)
1920 × ffll_ref
High range (DRS=11)
2560 × ffll_ref
fdco_t_DMX32 DCO output
frequency
Low range (DRS=00)
732 × ffll_ref
4, 5
Mid range (DRS=01)
1464 × ffll_ref
—
Mid-high range (DRS=10)
2197 × ffll_ref
—
High range (DRS=11)
2929 × ffll_ref
—
Jcyc_fll
FLL period jitter
—
—
180
150
—
—
• fVCO = 48 MHz
• fVCO = 98 MHz
tfll_acquire FLL target frequency acquisition time
—
—
1
ms
6
PLL0,1
fpll_ref
PLL reference frequency range
8
180
90
90
—
—
—
16
360
180
180
—
MHz
MHz
fvcoclk_2x VCO output frequency
fvcoclk
fvcoclk_90 PLL quadrature output frequency
Ipll PLL0 operating current
PLL output frequency
—
—
MHz
MHz
2.8
4.7
2.3
mA
mA
mA
• VCO @ 184 MHz (fosc_hi_1 = 32 MHz, fpll_ref
= 8 MHz, VDIV multiplier = 23)
Ipll
PLL0 operating current
7
7
7
8
9
—
—
—
—
—
• VCO @ 360 MHz (fosc_hi_1 = 32 MHz, fpll_ref
= 8 MHz, VDIV multiplier = 45)
Ipll
PLL1 operating current
• VCO @ 184 MHz (fosc_hi_1 = 32 MHz, fpll_ref
= 8 MHz, VDIV multiplier = 23)
Ipll
PLL1 operating current
—
—
3.6
—
mA
s
• VCO @ 360 MHz (fosc_hi_1 = 32 MHz, fpll_ref
= 8 MHz, VDIV multiplier = 45)
tpll_lock
Lock detector detection time
PLL period jitter (RMS)
100 × 10-6
+ 1075(1/
fpll_ref
)
Jcyc_pll
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Table 15. MCG specifications (continued)
Symbol Description
• fvco = 180 MHz
Min.
Typ.
Max.
Unit
Notes
—
100
—
ps
• fvco = 360 MHz
—
75
—
ps
Jacc_pll
PLL accumulated jitter over 1µs (RMS)
• fvco = 180 MHz
10
—
—
600
300
—
—
ps
ps
• fvco = 360 MHz
1. This parameter is measured with the internal reference (slow clock) being used as a reference to the FLL (FEI clock
mode).
2. These typical values listed are with the slow internal reference clock (FEI) using factory trim and DMX32=0.
3. The resulting system clock frequencies should not exceed their maximum specified values. The DCO frequency deviation
(Δfdco_t) over voltage and temperature should be considered.
4. These typical values listed are with the slow internal reference clock (FEI) using factory trim and DMX32=1.
5. The resulting clock frequency must not exceed the maximum specified clock frequency of the device.
6. This specification applies to any time the FLL reference source or reference divider is changed, trim value is changed,
DMX32 bit is changed, DRS bits are changed, or changing from FLL disabled (BLPE, BLPI) to FLL enabled (FEI, FEE,
FBE, FBI). If a crystal/resonator is being used as the reference, this specification assumes it is already running.
7. Excludes any oscillator currents that are also consuming power while PLL is in operation.
8. This specification applies to any time the PLL VCO divider or reference divider is changed, or changing from PLL disabled
(BLPE, BLPI) to PLL enabled (PBE, PEE). If a crystal/resonator is being used as the reference, this specification assumes
it is already running.
9. This specification was obtained using a Freescale developed PCB. PLL jitter is dependent on the noise characteristics of
each PCB and results will vary.
10. Accumulated jitter depends on VCO frequency and VDIV.
6.3.2 Oscillator electrical specifications
6.3.2.1 Oscillator DC electrical specifications
Table 16. Oscillator DC electrical specifications
Symbol Description
Min.
Typ.
Max.
Unit
Notes
VDD
Supply voltage
1.71
—
3.6
V
IDDOSC
Supply current — low-power mode (HGO=0)
1
• 32 kHz
—
—
—
—
—
—
500
200
300
950
1.2
—
—
—
—
—
—
nA
μA
μA
μA
mA
mA
• 4 MHz
• 8 MHz (RANGE=01)
• 16 MHz
• 24 MHz
• 32 MHz
1.5
IDDOSC
Supply current — high-gain mode (HGO=1)
• 32 kHz
1
—
—
25
—
—
μA
μA
400
Table continues on the next page...
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Peripheral operating requirements and behaviors
Table 16. Oscillator DC electrical specifications (continued)
Symbol Description
Min.
Typ.
Max.
Unit
Notes
• 4 MHz
—
500
—
μA
• 8 MHz (RANGE=01)
—
—
—
2.5
3
—
—
—
mA
mA
mA
• 16 MHz
• 24 MHz
• 32 MHz
4
Cx
Cy
RF
EXTAL load capacitance
XTAL load capacitance
—
—
—
—
—
—
—
—
—
2, 3
2, 3
2, 4
Feedback resistor — low-frequency, low-power
mode (HGO=0)
MΩ
MΩ
MΩ
MΩ
kΩ
Feedback resistor — low-frequency, high-gain
mode (HGO=1)
—
—
—
—
—
—
10
—
—
—
—
—
—
—
Feedback resistor — high-frequency, low-power
mode (HGO=0)
Feedback resistor — high-frequency, high-gain
mode (HGO=1)
1
RS
Series resistor — low-frequency, low-power
mode (HGO=0)
—
Series resistor — low-frequency, high-gain mode
(HGO=1)
200
—
kΩ
Series resistor — high-frequency, low-power
mode (HGO=0)
kΩ
Series resistor — high-frequency, high-gain
mode (HGO=1)
—
—
0
—
—
kΩ
V
5
Vpp
Peak-to-peak amplitude of oscillation (oscillator
mode) — low-frequency, low-power mode
(HGO=0)
0.6
Peak-to-peak amplitude of oscillation (oscillator
mode) — low-frequency, high-gain mode
(HGO=1)
—
—
—
VDD
0.6
—
—
—
V
V
V
Peak-to-peak amplitude of oscillation (oscillator
mode) — high-frequency, low-power mode
(HGO=0)
Peak-to-peak amplitude of oscillation (oscillator
mode) — high-frequency, high-gain mode
(HGO=1)
VDD
1. VDD=3.3 V, Temperature =25 °C
2. See crystal or resonator manufacturer's recommendation
3. Cx and Cy can be provided by using either integrated capacitors or external components.
4. When low-power mode is selected, RF is integrated and must not be attached externally.
5. The EXTAL and XTAL pins should only be connected to required oscillator components and must not be connected to any
other device.
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6.3.2.2 Oscillator frequency specifications
Table 17. Oscillator frequency specifications
Symbol Description
fosc_lo Oscillator crystal or resonator frequency — low-
frequency mode (MCG_C2[RANGE]=00)
Min.
32
Typ.
Max.
40
Unit
Notes
—
kHz
fosc_hi_1 Oscillator crystal or resonator frequency — high-
frequency mode (low range)
3
8
—
—
8
MHz
MHz
1
(MCG_C2[RANGE]=01)
fosc_hi_2 Oscillator crystal or resonator frequency — high
frequency mode (high range)
32
(MCG_C2[RANGE]=1x)
fec_extal
tdc_extal
tcst
Input clock frequency (external clock mode)
Input clock duty cycle (external clock mode)
—
40
—
—
50
60
60
—
MHz
%
2, 3
4, 5
Crystal startup time — 32 kHz low-frequency,
low-power mode (HGO=0)
1000
ms
Crystal startup time — 32 kHz low-frequency,
high-gain mode (HGO=1)
—
—
500
0.6
—
—
ms
ms
Crystal startup time — 8 MHz high-frequency
(MCG_C2[RANGE]=01), low-power mode
(HGO=0)
Crystal startup time — 8 MHz high-frequency
(MCG_C2[RANGE]=01), high-gain mode
(HGO=1)
—
1
—
ms
1. Frequencies less than 8 MHz are not in the PLL range.
2. Other frequency limits may apply when external clock is being used as a reference for the FLL
3. When transitioning from FEI or FBI to FBE mode, restrict the frequency of the input clock so that, when it is divided by
FRDIV, it remains within the limits of the DCO input clock frequency.
4. Proper PC board layout procedures must be followed to achieve specifications.
5. Crystal startup time is defined as the time between the oscillator being enabled and the OSCINIT bit in the MCG_S register
being set.
NOTE
The 32 kHz oscillator works in low power mode by default and
cannot be moved into high power/gain mode.
6.3.3 32 kHz oscillator electrical characteristics
6.3.3.1 32 kHz oscillator DC electrical specifications
Table 18. 32kHz oscillator DC electrical specifications
Symbol
VBAT
RF
Description
Min.
1.71
—
Typ.
—
Max.
3.6
—
Unit
V
Supply voltage
Internal feedback resistor
Parasitical capacitance of EXTAL32 and XTAL32
Peak-to-peak amplitude of oscillation
100
5
MΩ
pF
V
Cpara
—
7
1
Vpp
—
0.6
—
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Peripheral operating requirements and behaviors
1. When a crystal is being used with the 32 kHz oscillator, the EXTAL32 and XTAL32 pins should only be connected to
required oscillator components and must not be connected to any other devices.
6.3.3.2 32 kHz oscillator frequency specifications
Table 19. 32 kHz oscillator frequency specifications
Symbol Description
Min.
—
Typ.
32.768
1000
—
Max.
—
Unit
kHz
ms
Notes
fosc_lo
tstart
Oscillator crystal
Crystal start-up time
—
—
1
vec_extal32 Externally provided input clock amplitude
700
VBAT
mV
2, 3
1. Proper PC board layout procedures must be followed to achieve specifications.
2. This specification is for an externally supplied clock driven to EXTAL32 and does not apply to any other clock input. The
oscillator remains enabled and XTAL32 must be left unconnected.
3. The parameter specified is a peak-to-peak value and VIH and VIL specifications do not apply. The voltage of the applied
clock must be within the range of VSS to VBAT
.
6.4 Memories and memory interfaces
6.4.1 Flash (FTFE) electrical specifications
This section describes the electrical characteristics of the FTFE module.
6.4.1.1 Flash timing specifications — program and erase
The following specifications represent the amount of time the internal charge pumps are
active and do not include command overhead.
Table 20. NVM program/erase timing specifications
Symbol Description
Min.
—
Typ.
7.5
Max.
18
Unit
μs
Notes
thvpgm8
Program Phrase high-voltage time
thversscr Erase Flash Sector high-voltage time
thversblk128k Erase Flash Block high-voltage time for 128 KB
thversblk256k Erase Flash Block high-voltage time for 256 KB
—
13
113
ms
ms
ms
1
1
1
—
104
208
1808
3616
—
1. Maximum time based on expectations at cycling end-of-life.
6.4.1.2 Flash timing specifications — commands
Table 21. Flash command timing specifications
Symbol Description
Read 1s Block execution time
Min.
Typ.
Max.
Unit
Notes
Table continues on the next page...
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Peripheral operating requirements and behaviors
Table 21. Flash command timing specifications (continued)
Symbol Description
trd1blk128k • 128 KB data flash
trd1blk256k
Min.
Typ.
Max.
Unit
Notes
—
—
0.5
ms
• 256 KB program flash
256 KB data flash
—
—
1.0
ms
trd1sec4k Read 1s Section execution time (4 KB flash)
—
—
—
—
—
—
—
70
100
80
μs
μs
μs
μs
1
1
1
tpgmchk
trdrsrc
Program Check execution time
Read Resource execution time
Program Phrase execution time
Erase Flash Block execution time
• 128 KB data flash
40
tpgm8
150
2
tersblk128k
tersblk256k
—
—
110
220
925
ms
ms
• 256 KB program flash
1850
256 KB data flash
tersscr
Erase Flash Sector execution time
—
—
15
20
115
—
ms
ms
2
tpgmsec4k Program Section execution time (4KB flash)
Read 1s All Blocks execution time
trd1allx
trd1alln
• FlexNVM devices
—
—
—
—
3.4
3.4
ms
ms
• Program flash only devices
trdonce
Read Once execution time
—
—
—
—
—
70
30
—
μs
μs
ms
μs
1
tpgmonce Program Once execution time
tersall
Erase All Blocks execution time
Verify Backdoor Access Key execution time
Swap Control execution time
• control code 0x01
650
—
5600
30
2
1
tvfykey
tswapx01
tswapx02
tswapx04
tswapx08
—
—
—
—
200
70
70
—
—
150
150
30
μs
μs
μs
μs
• control code 0x02
• control code 0x04
• control code 0x08
Program Partition for EEPROM execution time
• 64 KB EEPROM backup
tpgmpart64k
tpgmpart256k
—
—
235
240
—
—
ms
ms
• 256 KB EEPROM backup
Set FlexRAM Function execution time:
• Control Code 0xFF
tsetramff
tsetram64k
tsetram128k
tsetram256k
—
—
—
—
205
1.6
2.7
4.8
—
μs
ms
ms
ms
• 64 KB EEPROM backup
• 128 KB EEPROM backup
• 256 KB EEPROM backup
2.5
3.8
6.2
t eewr8bers Byte-write to erased FlexRAM location execution
time
—
140
225
μs
3
Byte-write to FlexRAM execution time:
teewr8b64k
—
400
1700
μs
Table continues on the next page...
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Peripheral operating requirements and behaviors
Table 21. Flash command timing specifications (continued)
Symbol Description
teewr8b128k • 64 KB EEPROM backup
teewr8b256k
Min.
Typ.
Max.
Unit
Notes
—
450
1800
μs
• 128 KB EEPROM backup
• 256 KB EEPROM backup
—
525
2000
μs
t eewr16bers 16-bit write to erased FlexRAM location
execution time
—
140
225
μs
16-bit write to FlexRAM execution time:
teewr16b64k
teewr16b128k
teewr16b256k
• 64 KB EEPROM backup
• 128 KB EEPROM backup
• 256 KB EEPROM backup
—
—
—
400
450
525
1700
1800
2000
μs
μs
μs
teewr32bers 32-bit write to erased FlexRAM location
execution time
—
180
275
μs
32-bit write to FlexRAM execution time:
teewr32b64k
teewr32b128k
teewr32b256k
• 64 KB EEPROM backup
• 128 KB EEPROM backup
• 256 KB EEPROM backup
—
—
—
475
525
600
1850
2000
2200
μs
μs
μs
1. Assumes 25MHz or greater flash clock frequency.
2. Maximum times for erase parameters based on expectations at cycling end-of-life.
3. For byte-writes to an erased FlexRAM location, the aligned word containing the byte must be erased.
6.4.1.3 Flash high voltage current behaviors
Table 22. Flash high voltage current behaviors
Symbol
Description
Min.
Typ.
Max.
Unit
IDD_PGM
Average current adder during high voltage flash
programming operation
—
3.5
7.5
mA
IDD_ERS
Average current adder during high voltage flash
erase operation
—
1.5
4.0
mA
6.4.1.4 Reliability specifications
Table 23. NVM reliability specifications
Symbol Description
Min.
Typ.1
Max.
Unit
Notes
Program Flash
tnvmretp10k Data retention after up to 10 K cycles
tnvmretp1k Data retention after up to 1 K cycles
nnvmcycp Cycling endurance
5
50
—
—
—
years
years
cycles
20
100
50 K
10 K
2
Data Flash
tnvmretd10k Data retention after up to 10 K cycles
5
50
—
years
Table continues on the next page...
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Peripheral operating requirements and behaviors
Table 23. NVM reliability specifications (continued)
Symbol Description
Min.
Typ.1
Max.
—
Unit
years
cycles
Notes
tnvmretd1k Data retention after up to 1 K cycles
nnvmcycd Cycling endurance
20
10 K
100
50 K
—
2
FlexRAM as EEPROM
tnvmretee100 Data retention up to 100% of write endurance
tnvmretee10 Data retention up to 10% of write endurance
nnvmcycee Cycling endurance for EEPROM backup
Write endurance
5
50
—
—
—
years
years
cycles
20
100
50 K
20 K
2
3
nnvmwree16
nnvmwree128
nnvmwree512
nnvmwree2k
• EEPROM backup to FlexRAM ratio = 16
• EEPROM backup to FlexRAM ratio = 128
• EEPROM backup to FlexRAM ratio = 512
• EEPROM backup to FlexRAM ratio = 2,048
70 K
630 K
2.5 M
10 M
175 K
1.6 M
6.4 M
25 M
—
—
—
—
writes
writes
writes
writes
1. Typical data retention values are based on measured response accelerated at high temperature and derated to a constant
25°C use profile. Engineering Bulletin EB618 does not apply to this technology. Typical endurance defined in Engineering
Bulletin EB619.
2. Cycling endurance represents number of program/erase cycles at -40°C ≤ Tj ≤ 125°C.
3. Write endurance represents the number of writes to each FlexRAM location at -40°C ≤Tj ≤ 125°C influenced by the cycling
endurance of the FlexNVM and the allocated EEPROM backup per subsystem. Minimum and typical values assume all 16-
bit or 32-bit writes to FlexRAM; all 8-bit writes result in 50% less endurance.
6.4.1.5 Write endurance to FlexRAM for EEPROM
When the FlexNVM partition code is not set to full data flash, the EEPROM data set size
can be set to any of several non-zero values.
The bytes not assigned to data flash via the FlexNVM partition code are used by the
FTFE to obtain an effective endurance increase for the EEPROM data. The built-in
EEPROM record management system raises the number of program/erase cycles that can
be attained prior to device wear-out by cycling the EEPROM data through a larger
EEPROM NVM storage space.
While different partitions of the FlexNVM are available, the intention is that a single
choice for the FlexNVM partition code and EEPROM data set size is used throughout the
entire lifetime of a given application. The EEPROM endurance equation and graph
shown below assume that only one configuration is ever used.
EEPROM – 2 × EEESPLIT × EEESIZE
Writes_subsystem =
× Write_efficiency × nnvmcycee
EEESPLIT × EEESIZE
where
• Writes_subsystem — minimum number of writes to each FlexRAM location for
subsystem (each subsystem can have different endurance)
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Peripheral operating requirements and behaviors
• EEPROM — allocated FlexNVM for each EEPROM subsystem based on DEPART;
entered with the Program Partition command
• EEESPLIT — FlexRAM split factor for subsystem; entered with the Program
Partition command
• EEESIZE — allocated FlexRAM based on DEPART; entered with the Program
Partition command
• Write_efficiency —
• 0.25 for 8-bit writes to FlexRAM
• 0.50 for 16-bit or 32-bit writes to FlexRAM
• nnvmcycee — EEPROM-backup cycling endurance
Figure 11. EEPROM backup writes to FlexRAM
6.4.2 EzPort switching specifications
Table 24. EzPort switching specifications
Num
Description
Min.
Max.
Unit
Operating voltage
1.71
3.6
V
Table continues on the next page...
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NXP Semiconductors
Peripheral operating requirements and behaviors
Table 24. EzPort switching specifications (continued)
Num
Description
Min.
Max.
Unit
EP1
EZP_CK frequency of operation (all commands except
—
fSYS/2
MHz
READ)
EP1a
EP2
EP3
EP4
EP5
EP6
EP7
EP8
EP9
EZP_CK frequency of operation (READ command)
EZP_CS negation to next EZP_CS assertion
EZP_CS input valid to EZP_CK high (setup)
EZP_CK high to EZP_CS input invalid (hold)
EZP_D input valid to EZP_CK high (setup)
EZP_CK high to EZP_D input invalid (hold)
EZP_CK low to EZP_Q output valid
—
fSYS/8
—
MHz
ns
2 x tEZP_CK
5
5
—
ns
—
ns
2
—
ns
5
—
ns
—
0
16
—
ns
EZP_CK low to EZP_Q output invalid (hold)
EZP_CS negation to EZP_Q tri-state
ns
—
12
ns
EZP_CK
EP2
EP3
EP4
EZP_CS
EP9
EP8
EP7
EZP_Q (output)
EZP_D (input)
EP5
EP6
Figure 12. EzPort Timing Diagram
6.4.3 NAND flash controller specifications
The NAND flash controller (NFC) implements the interface to standard NAND flash
memory devices. This section describes the timing parameters of the NFC.
In the following table:
• TH is the flash clock high time and
• TL is flash clock low time,
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35
Peripheral operating requirements and behaviors
which are defined as:
Tinput clock
SCALER
TNFC = TL + TH
=
The SCALER value is derived from the fractional divider specified in the SIM's
CLKDIV4 register:
SIM_CLKDIV4[NFCFRAC] + 1
SIM_CLKDIV4[NFCDIV] + 1
=
SCALER
In case the reciprocal of SCALER is an integer, the duty cycle of NFC clock is 50%,
means TH = TL. In case the reciprocal of SCALER is not an integer:
TNFC
TL = (1 + SCALER / 2) x
2
TNFC
TH = (1 – SCALER / 2) x
2
For example, if SCALER is 0.2, then TH = TL = TNFC/2.
TNFC
TH TL
However, if SCALER is 0.667, then TL = 2/3 x TNFC and TH = 1/3 x TNFC
.
TNFC
TH TL
NOTE
The reciprocal of SCALER must be a multiple of 0.5. For
example, 1, 1.5, 2, 2.5, etc.
Table 25. NFC specifications
Num
tCLS
tCLH
tCS
Description
Min.
2TH + TL – 1
TH + TL – 1
2TH + TL – 1
TH + TL
Max.
—
Unit
ns
NFC_CLE setup time
NFC_CLE hold time
NFC_CEn setup time
NFC_CEn hold time
NFC_WP pulse width
NFC_ALE setup time
—
ns
—
ns
tCH
—
ns
tWP
TL – 1
—
ns
tALS
2TH + TL
—
ns
Table continues on the next page...
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Peripheral operating requirements and behaviors
Table 25. NFC specifications (continued)
Num
tALH
tDS
Description
NFC_ALE hold time
Data setup time
Min.
TH + TL
TL – 1
Max.
—
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
—
tDH
Data hold time
TH – 1
—
tWC
tWH
tRR
Write cycle time
TH + TL – 1
TH – 1
—
NFC_WE hold time
Ready to NFC_RE low
NFC_RE pulse width
Read cycle time
—
4TH + 3TL + 90
TL + 1
—
tRP
—
tRC
TL + TH – 1
TH – 1
—
tREH
tIS
NFC_RE high hold time
Data input setup time
—
11
—
NFC_CLE
tCLS
tCS
tCLH
tCH
NFC_CEn
NFC_WE
NFC_IOn
tWP
tDS
tDH
Figure 13. Command latch cycle timing
NFC_ALE
NFC_CEn
NFC_WE
NFC_IOn
tALS
tCS
tALH
tCH
tWP
tDS
tDH
address
Figure 14. Address latch cycle timing
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Peripheral operating requirements and behaviors
tCS
tCH
tWC
NFC_CEn
NFC_WE
NFC_IOn
tWP
tDS
tWH
tDH
data
data
data
Figure 15. Write data latch cycle timing
tCH
tRC
tRP
NFC_CEn
NFC_RE
NFC_IOn
NFC_RB
tREH
tIS
data
data
data
tRR
Figure 16. Read data latch cycle timing in Slow mode
tCH
tRC
tRP
NFC_CEn
NFC_RE
NFC_IOn
NFC_RB
tREH
tIS
data
data
data
tRR
Figure 17. Read data latch cycle timing in Fast mode and EDO mode
6.4.4 Flexbus switching specifications
All processor bus timings are synchronous; input setup/hold and output delay are given in
respect to the rising edge of a reference clock, FB_CLK. The FB_CLK frequency may be
the same as the internal system bus frequency or an integer divider of that frequency.
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NXP Semiconductors
Peripheral operating requirements and behaviors
The following timing numbers indicate when data is latched or driven onto the external
bus, relative to the Flexbus output clock (FB_CLK). All other timing relationships can be
derived from these values.
Table 26. Flexbus limited voltage range switching specifications
Num
Description
Min.
2.7
—
Max.
3.6
Unit
V
Notes
Operating voltage
Frequency of operation
Clock period
FB_CLK
—
MHz
ns
FB1
FB2
FB3
FB4
FB5
20
Address, data, and control output valid
Address, data, and control output hold
Data and FB_TA input setup
Data and FB_TA input hold
—
11.5
—
ns
1
1
2
2
0.5
8.5
0.5
ns
—
ns
—
ns
1. Specification is valid for all FB_AD[31:0], FB_BE/BWEn, FB_CSn, FB_OE, FB_R/W,FB_TBST, FB_TSIZ[1:0], FB_ALE,
and FB_TS.
2. Specification is valid for all FB_AD[31:0] and FB_TA.
Table 27. Flexbus full voltage range switching specifications
Num
Description
Min.
1.71
—
Max.
3.6
Unit
V
Notes
Operating voltage
Frequency of operation
Clock period
FB_CLK
—
MHz
ns
FB1
FB2
FB3
FB4
FB5
1/FB_CLK
—
Address, data, and control output valid
Address, data, and control output hold
Data and FB_TA input setup
Data and FB_TA input hold
13.5
—
ns
1
1
2
2
0
ns
13.7
0.5
—
ns
—
ns
1. Specification is valid for all FB_AD[31:0], FB_BE/BWEn, FB_CSn, FB_OE, FB_R/W,FB_TBST, FB_TSIZ[1:0], FB_ALE,
and FB_TS.
2. Specification is valid for all FB_AD[31:0] and FB_TA.
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Peripheral operating requirements and behaviors
Read Timing Parameters
S0
S1
S2
S3
S0
FB1
FB_CLK
FB_A[Y]
FB_D[X]
FB_RW
FB5
FB3
Address
FB4
FB2
Address
Data
FB_TS
FB_ALE
FB_CSn
FB_OEn
FB_BEn
FB_TA
AA=1
AA=0
FB4
FB5
AA=1
AA=0
FB_TSIZ[1:0]
TSIZ
S1
S0
S2
S3
S0
Figure 18. FlexBus read timing diagram
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NXP Semiconductors
Peripheral operating requirements and behaviors
Write Timing Parameters
FB1
FB_CLK
FB_A[Y]
FB_D[X]
FB_RW
FB2
FB3
Address
Address
Data
FB_TS
FB_ALE
FB_CSn
FB_OEn
FB_BEn
FB_TA
AA=1
AA=0
FB4
FB5
AA=1
AA=0
FB_TSIZ[1:0]
TSIZ
Figure 19. FlexBus write timing diagram
6.5 Security and integrity modules
There are no specifications necessary for the device's security and integrity modules.
6.6 Analog
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Peripheral operating requirements and behaviors
6.6.1 ADC electrical specifications
The 16-bit accuracy specifications listed in Table 28 and Table 29 are achievable on the
differential pins ADCx_DP0, ADCx_DM0.
The ADCx_DP2 and ADCx_DM2 ADC inputs are connected to the PGA outputs and are
not direct device pins. Accuracy specifications for these pins are defined in Table 30 and
Table 31.
All other ADC channels meet the 13-bit differential/12-bit single-ended accuracy
specifications.
6.6.1.1 16-bit ADC operating conditions
Table 28. 16-bit ADC operating conditions
Symbol Description
Conditions
Min.
1.71
-100
-100
1.13
Typ.1
Max.
3.6
Unit
V
Notes
VDDA
ΔVDDA
ΔVSSA
VREFH
Supply voltage
Supply voltage
Ground voltage
Absolute
—
Delta to VDD (VDD – VDDA
)
0
+100
+100
VDDA
mV
mV
V
2
2
Delta to VSS (VSS – VSSA
)
0
ADC reference
voltage high
VDDA
VREFL
VADIN
ADC reference
voltage low
VSSA
VSSA
VSSA
V
V
Input voltage
• 16-bit differential mode
• All other modes
• 16-bit mode
VREFL
VREFL
—
—
31/32 ×
VREFH
VREFH
CADIN
Input capacitance
—
—
8
4
10
5
pF
• 8-bit / 10-bit / 12-bit
modes
RADIN
RAS
Input series
resistance
—
—
2
5
5
kΩ
kΩ
Analog source
resistance
(external)
13-bit / 12-bit modes
fADCK < 4 MHz
3
—
fADCK
fADCK
Crate
ADC conversion ≤ 13-bit mode
clock frequency
1.0
2.0
—
—
18.0
12.0
MHz
MHz
4
4
5
ADC conversion 16-bit mode
clock frequency
ADC conversion ≤ 13-bit modes
rate
No ADC hardware averaging
20.000
37.037
—
—
818.330
461.467
kS/s
kS/s
Continuous conversions
enabled, subsequent
conversion time
Crate
ADC conversion 16-bit mode
rate
5
No ADC hardware averaging
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Peripheral operating requirements and behaviors
Table 28. 16-bit ADC operating conditions
Symbol Description
Conditions
Min.
Typ.1
Max.
Unit
Notes
Continuous conversions
enabled, subsequent
conversion time
1. Typical values assume VDDA = 3.0 V, Temp = 25 °C, fADCK = 1.0 MHz, unless otherwise stated. Typical values are for
reference only, and are not tested in production.
2. DC potential difference.
3. This resistance is external to MCU. To achieve the best results, the analog source resistance must be kept as low as
possible. The results in this data sheet were derived from a system that had < 8 Ω analog source resistance. The RAS/CAS
time constant should be kept to < 1 ns.
4. To use the maximum ADC conversion clock frequency, CFG2[ADHSC] must be set and CFG1[ADLPC] must be clear.
5. For guidelines and examples of conversion rate calculation, download the ADC calculator tool.
SIMPLIFIED
INPUT PIN EQUIVALENT
ZADIN
CIRCUIT
SIMPLIFIED
CHANNEL SELECT
CIRCUIT
Pad
leakage
ZAS
ADC SAR
ENGINE
RAS
RADIN
VADIN
CAS
VAS
RADIN
RADIN
RADIN
INPUT PIN
INPUT PIN
INPUT PIN
CADIN
Figure 20. ADC input impedance equivalency diagram
6.6.1.2 16-bit ADC electrical characteristics
Table 29. 16-bit ADC characteristics (VREFH = VDDA, VREFL = VSSA
)
Symbol Description
Conditions1
Min.
0.215
1.2
Typ.2
Max.
1.7
Unit
mA
Notes
IDDA_ADC Supply current
—
3
ADC asynchronous
fADACK clock source
• ADLPC = 1, ADHSC = 0
• ADLPC = 1, ADHSC = 1
2.4
3.9
MHz
MHz
tADACK = 1/
fADACK
2.4
4.0
6.1
Table continues on the next page...
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Peripheral operating requirements and behaviors
Table 29. 16-bit ADC characteristics (VREFH = VDDA, VREFL = VSSA) (continued)
Symbol Description
Conditions1
Min.
Typ.2
Max.
Unit
Notes
• ADLPC = 0, ADHSC = 0
3.0
5.2
7.3
MHz
• ADLPC = 0, ADHSC = 1
4.4
6.2
9.5
MHz
LSB4
LSB4
Sample Time
See Reference Manual chapter for sample times
TUE
DNL
Total unadjusted
error
• 12-bit modes
• <12-bit modes
—
—
4
6.8
2.1
5
5
1.4
Differential non-
linearity
• 12-bit modes
• <12-bit modes
—
—
0.7
0.2
–1.1 to
+1.9
–0.3 to
0.5
INL
Integral non-linearity
• 12-bit modes
• <12-bit modes
—
—
1.0
0.5
–2.7 to
+1.9
LSB4
5
–0.7 to
+0.5
5
EFS
EQ
Full-scale error
• 12-bit modes
• <12-bit modes
• 16-bit modes
• ≤13-bit modes
—
—
—
—
–4
–1.4
–1 to 0
—
–5.4
–1.8
—
LSB4
LSB4
VADIN = VDDA
Quantization error
0.5
ENOB Effective number of 16-bit differential mode
6
bits
12.8
11.9
14.5
13.8
—
—
bits
bits
• Avg = 32
• Avg = 4
16-bit single-ended mode
• Avg = 32
12.2
11.4
13.9
13.1
—
—
bits
bits
dB
• Avg = 4
Signal-to-noise plus See ENOB
SINAD
6.02 × ENOB + 1.76
distortion
THD
Total harmonic
distortion
16-bit differential mode
• Avg = 32
7
7
dB
dB
—
-94
-85
—
16-bit single-ended mode
• Avg = 32
—
—
SFDR Spurious free
dynamic range
16-bit differential mode
• Avg = 32
—
—
dB
dB
82
78
95
90
16-bit single-ended mode
• Avg = 32
EIL
Input leakage error
IIn × RAS
mV
IIn = leakage
current
Table continues on the next page...
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Peripheral operating requirements and behaviors
Table 29. 16-bit ADC characteristics (VREFH = VDDA, VREFL = VSSA) (continued)
Symbol Description
Conditions1
Min.
Typ.2
Max.
Unit
Notes
(refer to the
MCU's voltage
and current
operating
ratings)
Temp sensor slope
Across the full temperature
range of the device
1.55
706
1.62
716
1.69
726
mV/°C
mV
8
VTEMP25 Temp sensor voltage 25 °C
8
1. All accuracy numbers assume the ADC is calibrated with VREFH = VDDA
2. Typical values assume VDDA = 3.0 V, Temp = 25 °C, fADCK = 2.0 MHz unless otherwise stated. Typical values are for
reference only and are not tested in production.
3. The ADC supply current depends on the ADC conversion clock speed, conversion rate and ADC_CFG1[ADLPC] (low
power). For lowest power operation, ADC_CFG1[ADLPC] must be set, the ADC_CFG2[ADHSC] bit must be clear with 1
MHz ADC conversion clock speed.
4. 1 LSB = (VREFH - VREFL)/2N
5. ADC conversion clock < 16 MHz, Max hardware averaging (AVGE = %1, AVGS = %11)
6. Input data is 100 Hz sine wave. ADC conversion clock < 12 MHz.
7. Input data is 1 kHz sine wave. ADC conversion clock < 12 MHz.
8. ADC conversion clock < 3 MHz
Typical ADC 16-bit Differential ENOB vs ADC Clock
100Hz, 90% FS Sine Input
15.00
14.70
14.40
14.10
13.80
13.50
13.20
12.90
12.60
Hardware Averaging Disabled
Averaging of 4 samples
12.30
12.00
Averaging of 8 samples
Averaging of 32 samples
1
2
3
4
5
6
7
8
9
10
11
12
ADC Clock Frequency (MHz)
Figure 21. Typical ENOB vs. ADC_CLK for 16-bit differential mode
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Peripheral operating requirements and behaviors
Typical ADC 16-bit Single-Ended ENOB vs ADC Clock
100Hz, 90% FS Sine Input
14.00
13.75
13.50
13.25
13.00
12.75
12.50
12.25
12.00
11.75
11.50
11.25
11.00
Averaging of 4 samples
Averaging of 32 samples
1
2
3
4
5
6
7
8
9
10
11
12
ADC Clock Frequency (MHz)
Figure 22. Typical ENOB vs. ADC_CLK for 16-bit single-ended mode
6.6.1.3 16-bit ADC with PGA operating conditions
Table 30. 16-bit ADC with PGA operating conditions
Symbol Description
VDDA Supply voltage
VREFPGA PGA ref voltage
Conditions
Min.
Typ.1
Max.
Unit
V
Notes
Absolute
1.71
—
3.6
VREF_OU VREF_OU VREF_OU
V
2, 3
T
T
T
VADIN
VCM
Input voltage
VSSA
VSSA
—
—
VDDA
VDDA
V
V
Input Common
Mode range
RPGAD
Differential input Gain = 1, 2, 4, 8
—
—
—
—
128
64
—
—
—
—
kΩ
IN+ to IN-4
impedance
Gain = 16, 32
Gain = 64
32
RAS
TS
Analog source
resistance
100
Ω
µs
5
6
7
ADC sampling
time
1.25
—
—
—
Crate
ADC conversion ≤ 13 bit modes
18.484
450
Ksps
rate
No ADC hardware
averaging
Continuous conversions
enabled
Peripheral clock = 50
MHz
16 bit modes
37.037
—
250
Ksps
8
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Peripheral operating requirements and behaviors
Table 30. 16-bit ADC with PGA operating conditions
Symbol Description
Conditions
Min.
Typ.1
Max.
Unit
Notes
No ADC hardware
averaging
Continuous conversions
enabled
Peripheral clock = 50
MHz
1. Typical values assume VDDA = 3.0 V, Temp = 25°C, fADCK = 6 MHz unless otherwise stated. Typical values are for
reference only and are not tested in production.
2. ADC must be configured to use the internal voltage reference (VREF_OUT)
3. PGA reference is internally connected to the VREF_OUT pin. If the user wishes to drive VREF_OUT with a voltage other
than the output of the VREF module, the VREF module must be disabled.
4. For single ended configurations the input impedance of the driven input is RPGAD/2
5. The analog source resistance (RAS), external to MCU, should be kept as minimum as possible. Increased RAS causes drop
in PGA gain without affecting other performances. This is not dependent on ADC clock frequency.
6. The minimum sampling time is dependent on input signal frequency and ADC mode of operation. A minimum of 1.25µs
time should be allowed for Fin=4 kHz at 16-bit differential mode. Recommended ADC setting is: ADLSMP=1, ADLSTS=2 at
8 MHz ADC clock.
7. ADC clock = 18 MHz, ADLSMP = 1, ADLST = 00, ADHSC = 1
8. ADC clock = 12 MHz, ADLSMP = 1, ADLST = 01, ADHSC = 1
6.6.1.4 16-bit ADC with PGA characteristics
Table 31. 16-bit ADC with PGA characteristics
Symbol
Description
Conditions
Min.
Typ.1
Max.
Unit
Notes
IDDA_PGA Supply current
Low power
—
420
644
μA
2
(ADC_PGA[PGALPb]=0)
IDC_PGA
Input DC current
A
3
Gain =1, VREFPGA=1.2V,
VCM=0.5V
—
—
1.54
0.57
—
—
μA
μA
Gain =64, VREFPGA=1.2V,
VCM=0.1V
G
Gain4
• PGAG=0
• PGAG=1
• PGAG=2
• PGAG=3
• PGAG=4
• PGAG=5
• PGAG=6
0.95
1.9
1
2
1.05
2.1
RAS < 100Ω
3.8
4
4.2
7.6
8
8.4
15.2
30.0
58.8
16
31.6
63.3
16.6
33.2
67.8
BW
Input signal
bandwidth
• 16-bit modes
• < 16-bit modes
—
—
—
—
—
4
kHz
kHz
dB
40
—
PSRR
Power supply
rejection ratio
Gain=1
-84
VDDA= 3V
100mV,
Table continues on the next page...
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Peripheral operating requirements and behaviors
Table 31. 16-bit ADC with PGA characteristics (continued)
Symbol
Description
Conditions
Min.
Typ.1
Max.
Unit
Notes
fVDDA= 50Hz,
60Hz
CMRR
Common mode
rejection ratio
• Gain=1
—
—
-84
-85
—
—
dB
dB
VCM=
500mVpp,
fVCM= 50Hz,
100Hz
• Gain=64
VOFS
Input offset
voltage
• Chopping disabled
(ADC_PGA[PGACHPb]
=1)
—
—
2.4
0.2
—
—
mV
mV
Output offset =
VOFS*(Gain+1)
• Chopping enabled
(ADC_PGA[PGACHPb]
=0)
TGSW
Gain switching
settling time
—
—
10
µs
5
dG/dT
Gain drift over full
temperature range
• Gain=1
• Gain=64
—
—
—
—
6
31
10
42
ppm/°C
ppm/°C
%/V
dG/dVDDA Gain drift over
supply voltage
• Gain=1
• Gain=64
0.07
0.21
0.31
VDDA from 1.71
to 3.6V
0.14
%/V
EIL
Input leakage
error
All modes
IIn × RAS
mV
IIn = leakage
current
(refer to the
MCU's voltage
and current
operating
ratings)
VPP,DIFF Maximum
differential input
V
6
signal swing
where VX = VREFPGA × 0.583
SNR
THD
Signal-to-noise
ratio
• Gain=1
80
52
90
66
—
—
dB
dB
16-bit
differential
mode,
• Gain=64
Average=32
Total harmonic
distortion
• Gain=1
85
49
100
95
—
—
dB
dB
16-bit
differential
mode,
• Gain=64
Average=32,
fin=100Hz
SFDR
ENOB
Spurious free
dynamic range
• Gain=1
85
53
105
88
—
—
dB
dB
16-bit
differential
mode,
Average=32,
fin=100Hz
• Gain=64
Effective number
of bits
• Gain=1, Average=4
• Gain=1, Average=8
• Gain=64, Average=4
• Gain=64, Average=8
11.6
8.0
13.4
13.6
9.6
—
—
—
—
—
bits
bits
bits
bits
bits
16-bit
differential
mode,fin=100Hz
7.2
6.3
9.6
12.8
14.5
Table continues on the next page...
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Peripheral operating requirements and behaviors
Table 31. 16-bit ADC with PGA characteristics (continued)
Symbol
Description
Conditions
• Gain=1, Average=32
Min.
Typ.1
Max.
Unit
Notes
11.0
14.3
—
bits
• Gain=2, Average=32
• Gain=4, Average=32
• Gain=8, Average=32
• Gain=16, Average=32
• Gain=32, Average=32
• Gain=64, Average=32
7.9
7.3
6.8
6.8
7.5
13.8
13.1
12.5
11.5
10.6
—
—
—
—
—
bits
bits
bits
bits
bits
SINAD
Signal-to-noise
plus distortion
ratio
See ENOB
6.02 × ENOB + 1.76
dB
1. Typical values assume VDDA =3.0V, Temp=25°C, fADCK=6MHz unless otherwise stated.
2. This current is a PGA module adder, in addition to ADC conversion currents.
3. Between IN+ and IN-. The PGA draws a DC current from the input terminals. The magnitude of the DC current is a strong
function of input common mode voltage (VCM) and the PGA gain.
4. Gain = 2PGAG
5. After changing the PGA gain setting, a minimum of 2 ADC+PGA conversions should be ignored.
6. Limit the input signal swing so that the PGA does not saturate during operation. Input signal swing is dependent on the
PGA reference voltage and gain setting.
6.6.2 CMP and 6-bit DAC electrical specifications
Table 32. Comparator and 6-bit DAC electrical specifications
Symbol
VDD
Description
Min.
1.71
—
Typ.
—
Max.
3.6
Unit
V
Supply voltage
IDDHS
IDDLS
VAIN
Supply current, High-speed mode (EN=1, PMODE=1)
Supply current, low-speed mode (EN=1, PMODE=0)
Analog input voltage
—
200
20
μA
μA
V
—
—
VSS – 0.3
—
—
VDD
20
VAIO
Analog input offset voltage
Analog comparator hysteresis1
• CR0[HYSTCTR] = 00
—
mV
VH
—
—
—
—
5
—
—
—
—
mV
mV
mV
mV
10
20
30
• CR0[HYSTCTR] = 01
• CR0[HYSTCTR] = 10
• CR0[HYSTCTR] = 11
VCMPOh
VCMPOl
tDHS
Output high
VDD – 0.5
—
—
—
0.5
200
600
40
V
V
Output low
—
20
80
—
—
Propagation delay, high-speed mode (EN=1, PMODE=1)
Propagation delay, low-speed mode (EN=1, PMODE=0)
Analog comparator initialization delay2
6-bit DAC current adder (enabled)
50
250
—
ns
ns
μs
μA
tDLS
IDAC6b
7
—
Table continues on the next page...
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49
Peripheral operating requirements and behaviors
Table 32. Comparator and 6-bit DAC electrical specifications (continued)
Symbol
INL
Description
Min.
–0.5
–0.3
Typ.
—
Max.
0.5
Unit
LSB3
LSB
6-bit DAC integral non-linearity
6-bit DAC differential non-linearity
DNL
—
0.3
1. Typical hysteresis is measured with input voltage range limited to 0.6 to VDD–0.6 V.
2. Comparator initialization delay is defined as the time between software writes to change control inputs (Writes to
CMP_DACCR[DACEN], CMP_DACCR[VRSEL], CMP_DACCR[VOSEL], CMP_MUXCR[PSEL], and
CMP_MUXCR[MSEL]) and the comparator output settling to a stable level.
3. 1 LSB = Vreference/64
0.08
0.07
0.06
0.05
0.04
0.03
HYSTCTR
Setting
00
01
10
11
0.02
0.01
0
0.1
0.4
0.7
1
1.3
1.6
1.9
2.2
2.5
2.8
3.1
Vin level (V)
Figure 23. Typical hysteresis vs. Vin level (VDD = 3.3 V, PMODE = 0)
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Peripheral operating requirements and behaviors
0.18
0.16
0.14
0.12
HYSTCTR
Setting
0.1
00
01
10
11
0.08
0.06
0.04
0.02
0
0.1
0.4
0.7
1
1.3
1.6
1.9
2.2
2.5
2.8
3.1
Vin level (V)
Figure 24. Typical hysteresis vs. Vin level (VDD = 3.3 V, PMODE = 1)
6.6.3 12-bit DAC electrical characteristics
6.6.3.1 12-bit DAC operating requirements
Table 33. 12-bit DAC operating requirements
Symbol
VDDA
VDACR
CL
Desciption
Min.
1.71
1.13
—
Max.
3.6
3.6
100
1
Unit
V
Notes
Supply voltage
Reference voltage
Output load capacitance
Output load current
V
1
2
pF
mA
IL
—
1. The DAC reference can be selected to be VDDA or VREF_OUT
.
2. A small load capacitance (47 pF) can improve the bandwidth performance of the DAC.
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Peripheral operating requirements and behaviors
6.6.3.2 12-bit DAC operating behaviors
Table 34. 12-bit DAC operating behaviors
Symbol Description
Min.
Typ.
Max.
Unit
Notes
IDDA_DACL Supply current — low-power mode
—
—
150
μA
P
IDDA_DACH Supply current — high-speed mode
—
—
—
—
—
—
100
15
0.7
—
700
200
30
μA
μs
P
tDACLP Full-scale settling time (0x080 to 0xF7F) —
low-power mode
1
1
1
tDACHP Full-scale settling time (0x080 to 0xF7F) —
high-power mode
μs
tCCDACLP Code-to-code settling time (0xBF8 to 0xC08)
— low-power mode and high-speed mode
1
μs
Vdacoutl DAC output voltage range low — high-speed
mode, no load, DAC set to 0x000
100
VDACR
8
mV
mV
LSB
LSB
LSB
Vdacouth DAC output voltage range high — high-
speed mode, no load, DAC set to 0xFFF
VDACR
−100
—
INL
DNL
DNL
Integral non-linearity error — high speed
mode
—
—
—
—
2
3
4
Differential non-linearity error — VDACR > 2
V
—
1
Differential non-linearity error — VDACR
VREF_OUT
=
—
1
VOFFSET Offset error
EG Gain error
PSRR Power supply rejection ratio, VDDA ≥ 2.4 V
—
—
60
—
—
—
0.4
0.1
0.8
0.6
90
%FSR
%FSR
dB
5
5
—
TCO
TGE
Rop
SR
Temperature coefficient offset voltage
Temperature coefficient gain error
Output resistance (load = 3 kΩ)
Slew rate -80h→ F7Fh→ 80h
3.7
—
μV/C
%FSR/C
Ω
6
0.000421
—
—
250
V/μs
• High power (SPHP
• Low power (SPLP
)
1.2
1.7
—
—
)
0.05
0.12
CT
Channel to channel cross talk
3dB bandwidth
—
—
-80
dB
BW
kHz
• High power (SPHP
• Low power (SPLP
)
550
40
—
—
—
—
)
1. Settling within 1 LSB
2. The INL is measured for 0 + 100 mV to VDACR −100 mV
3. The DNL is measured for 0 + 100 mV to VDACR −100 mV
4. The DNL is measured for 0 + 100 mV to VDACR −100 mV with VDDA > 2.4 V
5. Calculated by a best fit curve from VSS + 100 mV to VDACR − 100 mV
6. VDDA = 3.0 V, reference select set for VDDA (DACx_CO:DACRFS = 1), high power mode (DACx_C0:LPEN = 0), DAC set to
0x800, temperature range is across the full range of the device
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8
6
4
2
0
-2
-4
-6
-8
0
500
1000
1500
2000
2500
3000
3500
4000
Digital Code
Figure 25. Typical INL error vs. digital code
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Peripheral operating requirements and behaviors
1.499
1.4985
1.498
1.4975
1.497
1.4965
1.496
55
85
25
105
125
-40
Temperature °C
Figure 26. Offset at half scale vs. temperature
6.6.4 Voltage reference electrical specifications
Table 35. VREF full-range operating requirements
Symbol
VDDA
TA
Description
Supply voltage
Temperature
Min.
Max.
Unit
Notes
1.71
3.6
V
Operating temperature
range of the device
°C
CL
Output load capacitance
100
nF
1, 2
1. CL must be connected to VREF_OUT if the VREF_OUT functionality is being used for either an internal or external
reference.
2. The load capacitance should not exceed +/-25% of the nominal specified CL value over the operating temperature range of
the device.
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Table 36. VREF full-range operating behaviors
Symbol Description
Min.
Typ.
Max.
Unit
Notes
Vout
Voltage reference output with factory trim at
1.1915
1.195
1.1977
V
1
nominal VDDA and temperature=25C
Voltage reference output — factory trim
Voltage reference output — user trim
Voltage reference trim step
Vout
Vout
1.1584
1.193
—
—
—
1.2376
1.197
—
V
V
1
1
1
1
Vstep
Vtdrift
0.5
—
mV
mV
Temperature drift (Vmax -Vmin across the full
temperature range)
—
80
Ibg
Ihp
Bandgap only current
—
—
—
—
80
1
µA
mA
mV
1
1
High-power buffer current
ΔVLOAD Load regulation
• current = + 1.0 mA
1, 2
—
—
2
5
—
—
• current = - 1.0 mA
Tstup
Buffer startup time
—
—
—
2
100
—
µs
Vvdrift
Voltage drift (Vmax -Vmin across the full voltage
range)
mV
1
1. See the chip's Reference Manual for the appropriate settings of the VREF Status and Control register.
2. Load regulation voltage is the difference between the VREF_OUT voltage with no load vs. voltage with defined load
Table 37. VREF limited-range operating requirements
Symbol
Description
Min.
Max.
Unit
Notes
TA
Temperature
0
50
°C
Table 38. VREF limited-range operating behaviors
Symbol
Description
Min.
Max.
Unit
Notes
Vout
Voltage reference output with factory trim
1.173
1.225
V
6.7 Timers
See General switching specifications.
6.8 Communication interfaces
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Peripheral operating requirements and behaviors
6.8.1 CAN switching specifications
See General switching specifications.
6.8.2 DSPI switching specifications (limited voltage range)
The DMA Serial Peripheral Interface DSPI provides a synchronous serial bus with master
and slave operations. Many of the transfer attributes are programmable. The tables below
provide DSPI timing characteristics for classic DSPI timing modes. Refer to the DSPI
chapter of the Reference Manual for information on the modified transfer formats used
for communicating with slower peripheral devices.
Table 39. Master mode DSPI timing (limited voltage range)
Num
Description
Min.
2.7
Max.
3.6
30
Unit
V
Notes
Operating voltage
Frequency of operation
—
MHz
ns
DS1
DS2
DS3
DSPI_SCK output cycle time
DSPI_SCK output high/low time
DSPI_PCSn valid to DSPI_SCK delay
2 x tBUS
—
(tSCK/2) − 2 (tSCK/2) + 2
ns
(tBUS x 2) −
2
—
ns
1
2
DS4
DSPI_SCK to DSPI_PCSn invalid delay
(tBUS x 2) −
2
—
ns
DS5
DS6
DS7
DS8
DSPI_SCK to DSPI_SOUT valid
DSPI_SCK to DSPI_SOUT invalid
DSPI_SIN to DSPI_SCK input setup
DSPI_SCK to DSPI_SIN input hold
—
−2
15
0
8.5
—
—
—
ns
ns
ns
ns
1. The delay is programmable in DSPIx_CTARn[PSSCK] and DSPIx_CTARn[CSSCK].
2. The delay is programmable in DSPIx_CTARn[PASC] and DSPIx_CTARn[ASC].
SPI_PCSn
DS1
DS3
DS2
DS4
SPI_SCK
(CPOL=0)
DS8
DS7
Data
Last data
First data
SPI_SIN
DS5
DS6
First data
Data
Last data
SPI_SOUT
Figure 27. DSPI classic DSPI timing — master mode
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Peripheral operating requirements and behaviors
Table 40. Slave mode DSPI timing (limited voltage range)
Num
Description
Min.
Max.
Unit
V
Operating voltage
2.7
3.6
Frequency of operation
15
MHz
ns
DS9
DSPI_SCK input cycle time
4 x tBUS
—
DS10
DS11
DS12
DS13
DS14
DS15
DS16
DSPI_SCK input high/low time
(tSCK/2) − 2
(tSCK/2) + 2
ns
DSPI_SCK to DSPI_SOUT valid
DSPI_SCK to DSPI_SOUT invalid
DSPI_SIN to DSPI_SCK input setup
DSPI_SCK to DSPI_SIN input hold
DSPI_SS active to DSPI_SOUT driven
DSPI_SS inactive to DSPI_SOUT not driven
—
0
10
—
—
—
14
14
ns
ns
2
ns
7
ns
—
—
ns
ns
SPI_SS
DS10
DS9
SPI_SCK
(POL=0)
DS15
DS12
DS16
DS11
First data
DS14
Last data
SPI_SOUT
Data
Data
DS13
First data
Last data
SPI_SIN
Figure 28. DSPI classic DSPI timing — slave mode
6.8.3 DSPI switching specifications (full voltage range)
The DMA Serial Peripheral Interface DSPI provides a synchronous serial bus with master
and slave operations. Many of the transfer attributes are programmable. The tables below
provides DSPI timing characteristics for classic SPI timing modes. Refer to the DSPI
chapter of the Reference Manual for information on the modified transfer formats used
for communicating with slower peripheral devices.
Table 41. Master mode DSPItiming (full voltage range)
Num
Description
Min.
1.71
Max.
3.6
15
Unit
V
Notes
Operating voltage
1
Frequency of operation
—
MHz
ns
DS1
DSPI_SCK output cycle time
4 x tBUS
—
Table continues on the next page...
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Peripheral operating requirements and behaviors
Table 41. Master mode DSPItiming (full voltage range) (continued)
Num
DS2
DS3
Description
DSPI_SCK output high/low time
DSPI_PCSn valid to DSPI_SCK delay
Min.
Max.
Unit
ns
Notes
(tSCK/2) - 4 (tSCK/2) + 4
(tBUS x 2) −
4
—
—
ns
2
3
DS4
DSPI_SCK to DSPI_PCSn invalid delay
(tBUS x 2) −
4
ns
DS5
DS6
DS7
DS8
DSPI_SCK to DSPI_SOUT valid
DSPI_SCK to DSPI_SOUT invalid
DSPI_SIN to DSPI_SCK input setup
DSPI_SCK to DSPI_SIN input hold
—
-4.5
20.5
0
10
—
—
—
ns
ns
ns
ns
1. The DSPI module can operate across the entire operating voltage for the processor, but to run across the full voltage
range the maximum frequency of operation is reduced.
2. The delay is programmable in SPIx_CTARn[PSSCK] and SPIx_CTARn[CSSCK].
3. The delay is programmable in SPIx_CTARn[PASC] and SPIx_CTARn[ASC].
SPI_PCSn
DS1
DS3
DS2
DS4
SPI_SCK
(CPOL=0)
DS8
DS7
Data
Last data
First data
SPI_SIN
DS5
DS6
First data
Data
Last data
SPI_SOUT
Figure 29. DSPI classic SPI timing — master mode
Table 42. Slave mode DSPI timing (full voltage range)
Num
Description
Min.
Max.
Unit
V
Operating voltage
1.71
3.6
Frequency of operation
—
7.5
MHz
ns
DS9
DSPI_SCK input cycle time
8 x tBUS
—
DS10
DS11
DS12
DS13
DS14
DS15
DS16
DSPI_SCK input high/low time
(tSCK/2) - 4
(tSCK/2) + 4
ns
DSPI_SCK to DSPI_SOUT valid
DSPI_SCK to DSPI_SOUT invalid
DSPI_SIN to DSPI_SCK input setup
DSPI_SCK to DSPI_SIN input hold
DSPI_SS active to DSPI_SOUT driven
DSPI_SS inactive to DSPI_SOUT not driven
—
0
20
—
—
—
19
19
ns
ns
2
ns
7
ns
—
—
ns
ns
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SPI_SS
DS10
DS9
SPI_SCK
(POL=0)
DS15
DS12
DS16
DS11
First data
DS14
Last data
Last data
SPI_SOUT
Data
Data
DS13
First data
SPI_SIN
Figure 30. DSPI classic SPI timing — slave mode
6.8.4 Inter-Integrated Circuit Interface (I2C) timing
Table 43. I 2C timing
Characteristic
Symbol
Standard Mode
Minimum Maximum
100
Fast Mode
Unit
Minimum
Maximum
400 1
SCL Clock Frequency
fSCL
0
0
kHz
µs
Hold time (repeated) START condition.
After this period, the first clock pulse is
generated.
tHD; STA
4
—
0.6
—
LOW period of the SCL clock
HIGH period of the SCL clock
tLOW
tHIGH
4.7
4
—
—
—
1.25
0.6
—
—
—
µs
µs
µs
Set-up time for a repeated START
condition
tSU; STA
4.7
0.6
Data hold time for I2C bus devices
tHD; DAT
tSU; DAT
tr
02
2505
—
3.453
—
04
1003,6
20 +0.1Cb
20 +0.1Cb
0.6
0.92
—
µs
ns
ns
ns
µs
µs
Data set-up time
7
6
Rise time of SDA and SCL signals
Fall time of SDA and SCL signals
Set-up time for STOP condition
1000
300
—
300
300
—
tf
—
tSU; STO
tBUF
4
Bus free time between STOP and
START condition
4.7
—
1.3
—
Pulse width of spikes that must be
suppressed by the input filter
tSP
N/A
N/A
0
50
ns
1. The maximum SCL Clock Frequency in Fast mode with maximum bus loading can only be achieved when using a pin
configured for high drive across the full voltage range and when using the a pin configured for low drive with VDD ≥ 2.7 V.
2. The master mode I2C deasserts ACK of an address byte simultaneously with the falling edge of SCL. If no slaves
acknowledge this address byte, then a negative hold time can result, depending on the edge rates of the SDA and SCL
lines.
3. The maximum tHD; DAT must be met only if the device does not stretch the LOW period (tLOW) of the SCL signal.
4. Input signal Slew = 10 ns and Output Load = 50 pF
5. Set-up time in slave-transmitter mode is 1 IPBus clock period, if the TX FIFO is empty.
6. A Fast mode I2C bus device can be used in a Standard mode I2C bus system, but the requirement tSU; DAT ≥ 250 ns must
then be met. This is automatically the case if the device does not stretch the LOW period of the SCL signal. If such a
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Peripheral operating requirements and behaviors
device does stretch the LOW period of the SCL signal, then it must output the next data bit to the SDA line trmax + tSU; DAT
= 1000 + 250 = 1250 ns (according to the Standard mode I2C bus specification) before the SCL line is released.
7. Cb = total capacitance of the one bus line in pF.
SDA
tSU; DAT
tf
tr
tBUF
tf
tr
tHD; STA
tSP
tLOW
SCL
tSU; STA
tSU; STO
HD; STA
S
SR
P
S
tHD; DAT
tHIGH
Figure 31. Timing definition for fast and standard mode devices on the I2C bus
6.8.5 UART switching specifications
See General switching specifications.
6.8.6 SDHC specifications
The following timing specs are defined at the chip I/O pin and must be translated
appropriately to arrive at timing specs/constraints for the physical interface.
Table 44. SDHC switching specifications over a limited operating voltage range
Num
Symbol
Description
Min.
Max.
Unit
Operating voltage
2.7
3.6
V
Card input clock
SD1
fpp
fpp
fpp
fOD
tWL
tWH
tTLH
tTHL
Clock frequency (low speed)
0
0
400
25\40
25\50
400
—
kHz
MHz
MHz
kHz
ns
Clock frequency (SD\SDIO full speed\high speed)
Clock frequency (MMC full speed\high speed)
Clock frequency (identification mode)
Clock low time
0
0
SD2
SD3
SD4
SD5
7
Clock high time
7
—
ns
Clock rise time
—
—
3
ns
Clock fall time
3
ns
SDHC output / card inputs SDHC_CMD, SDHC_DAT (reference to SDHC_CLK)
SDHC output delay (output valid) -5 6.5
SDHC input / card inputs SDHC_CMD, SDHC_DAT (reference to SDHC_CLK)
SD6
tOD
ns
SD7
SD8
tISU
tIH
SDHC input setup time
SDHC input hold time
5
0
—
—
ns
ns
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Table 45. SDHC switching specifications over the full operating voltage range
Num
Symbol
Description
Min.
Max.
Unit
Operating voltage
1.71
3.6
V
Card input clock
SD1
fpp
fpp
fpp
fOD
tWL
tWH
tTLH
tTHL
Clock frequency (low speed)
0
0
400
25\40
25\50
400
—
kHz
MHz
MHz
kHz
ns
Clock frequency (SD\SDIO full speed\high speed)
Clock frequency (MMC full speed\high speed)
Clock frequency (identification mode)
Clock low time
0
0
SD2
SD3
SD4
SD5
7
Clock high time
7
—
ns
Clock rise time
—
—
3
ns
Clock fall time
3
ns
SDHC output / card inputs SDHC_CMD, SDHC_DAT (reference to SDHC_CLK)
SDHC output delay (output valid) -5 6.5
SDHC input / card inputs SDHC_CMD, SDHC_DAT (reference to SDHC_CLK)
SD6
tOD
ns
SD7
SD8
tISU
tIH
SDHC input setup time
SDHC input hold time
5
—
—
ns
ns
1.3
SD3
SD6
SD2
SD1
SDHC_CLK
Output SDHC_CMD
Output SDHC_DAT[3:0]
Input SDHC_CMD
SD7
SD8
Input SDHC_DAT[3:0]
Figure 32. SDHC timing
6.8.7 I2S/SAI switching specifications
This section provides the AC timing for the I2S/SAI module in master mode (clocks are
driven) and slave mode (clocks are input). All timing is given for noninverted serial clock
polarity (TCR2[BCP] is 0, RCR2[BCP] is 0) and a noninverted frame sync (TCR4[FSP]
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Peripheral operating requirements and behaviors
is 0, RCR4[FSP] is 0). If the polarity of the clock and/or the frame sync have been
inverted, all the timing remains valid by inverting the bit clock signal (BCLK) and/or the
frame sync (FS) signal shown in the following figures.
6.8.7.1 Normal Run, Wait and Stop mode performance over a limited
operating voltage range
This section provides the operating performance over a limited operating voltage for the
device in Normal Run, Wait and Stop modes.
Table 46. I2S/SAI master mode timing in Normal Run, Wait and Stop modes (limited voltage
range)
Num.
Characteristic
Min.
Max.
Unit
Operating voltage
2.7
40
3.6
—
V
S1
S2
S3
S4
S5
I2S_MCLK cycle time
ns
I2S_MCLK pulse width high/low
45%
80
55%
—
MCLK period
I2S_TX_BCLK/I2S_RX_BCLK cycle time (output)
I2S_TX_BCLK/I2S_RX_BCLK pulse width high/low
ns
45%
—
55%
15
BCLK period
ns
I2S_TX_BCLK/I2S_RX_BCLK to I2S_TX_FS/
I2S_RX_FS output valid
S6
I2S_TX_BCLK/I2S_RX_BCLK to I2S_TX_FS/
I2S_RX_FS output invalid
0
—
ns
S7
S8
S9
I2S_TX_BCLK to I2S_TXD valid
I2S_TX_BCLK to I2S_TXD invalid
—
0
15
—
—
ns
ns
ns
I2S_RXD/I2S_RX_FS input setup before
I2S_RX_BCLK
15
S10
I2S_RXD/I2S_RX_FS input hold after I2S_RX_BCLK
0
—
ns
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S1
S2
S2
I2S_MCLK (output)
S3
S4
I2S_TX_BCLK/
I2S_RX_BCLK (output)
S4
S5
S7
S6
I2S_TX_FS/
I2S_RX_FS (output)
S10
S9
I2S_TX_FS/
I2S_RX_FS (input)
S7
S8
S8
I2S_TXD
I2S_RXD
S9
S10
Figure 33. I2S/SAI timing — master modes
Table 47. I2S/SAI slave mode timing in Normal Run, Wait and Stop modes (limited voltage
range)
Num.
Characteristic
Min.
Max.
Unit
Operating voltage
2.7
80
3.6
—
V
S11
S12
I2S_TX_BCLK/I2S_RX_BCLK cycle time (input)
ns
I2S_TX_BCLK/I2S_RX_BCLK pulse width high/low
(input)
45%
55%
MCLK period
S13
S14
S15
I2S_TX_FS/I2S_RX_FS input setup before
I2S_TX_BCLK/I2S_RX_BCLK
4.5
2
—
ns
ns
ns
I2S_TX_FS/I2S_RX_FS input hold after
I2S_TX_BCLK/I2S_RX_BCLK
—
I2S_TX_BCLK to I2S_TXD/I2S_TX_FS output valid
• Multiple SAI Synchronous mode
• All other modes
—
—
21
15
S16
S17
S18
S19
I2S_TX_BCLK to I2S_TXD/I2S_TX_FS output invalid
I2S_RXD setup before I2S_RX_BCLK
0
—
—
—
25
ns
ns
ns
ns
4.5
2
I2S_RXD hold after I2S_RX_BCLK
I2S_TX_FS input assertion to I2S_TXD output valid1
—
1. Applies to first bit in each frame and only if the TCR4[FSE] bit is clear
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S11
S12
I2S_TX_BCLK/
I2S_RX_BCLK (input)
S12
S15
S15
S16
I2S_TX_FS/
I2S_RX_FS (output)
S13
S14
I2S_TX_FS/
I2S_RX_FS (input)
S15
S19
S16
S16
I2S_TXD
I2S_RXD
S17
S18
Figure 34. I2S/SAI timing — slave modes
6.8.7.2 Normal Run, Wait and Stop mode performance over the full
operating voltage range
This section provides the operating performance over the full operating voltage for the
device in Normal Run, Wait and Stop modes.
Table 48. I2S/SAI master mode timing in Normal Run, Wait and Stop modes (full voltage
range)
Num.
Characteristic
Min.
Max.
Unit
Operating voltage
1.71
40
3.6
—
V
S1
S2
S3
S4
S5
I2S_MCLK cycle time
ns
I2S_MCLK pulse width high/low
45%
80
55%
—
MCLK period
I2S_TX_BCLK/I2S_RX_BCLK cycle time (output)
I2S_TX_BCLK/I2S_RX_BCLK pulse width high/low
ns
45%
—
55%
15
BCLK period
ns
I2S_TX_BCLK/I2S_RX_BCLK to I2S_TX_FS/
I2S_RX_FS output valid
S6
I2S_TX_BCLK/I2S_RX_BCLK to I2S_TX_FS/
I2S_RX_FS output invalid
-1.0
—
ns
S7
S8
S9
I2S_TX_BCLK to I2S_TXD valid
I2S_TX_BCLK to I2S_TXD invalid
—
15
—
—
ns
ns
ns
0
I2S_RXD/I2S_RX_FS input setup before
I2S_RX_BCLK
20.5
S10
I2S_RXD/I2S_RX_FS input hold after I2S_RX_BCLK
0
—
ns
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S1
S2
S2
I2S_MCLK (output)
S3
S4
I2S_TX_BCLK/
I2S_RX_BCLK (output)
S4
S5
S7
S6
I2S_TX_FS/
I2S_RX_FS (output)
S10
S9
I2S_TX_FS/
I2S_RX_FS (input)
S7
S8
S8
I2S_TXD
I2S_RXD
S9
S10
Figure 35. I2S/SAI timing — master modes
Table 49. I2S/SAI slave mode timing in Normal Run, Wait and Stop modes (full voltage
range)
Num.
Characteristic
Min.
Max.
Unit
Operating voltage
1.71
80
3.6
—
V
S11
S12
I2S_TX_BCLK/I2S_RX_BCLK cycle time (input)
ns
I2S_TX_BCLK/I2S_RX_BCLK pulse width high/low
(input)
45%
55%
MCLK period
S13
S14
S15
I2S_TX_FS/I2S_RX_FS input setup before
I2S_TX_BCLK/I2S_RX_BCLK
5.8
2
—
ns
ns
ns
I2S_TX_FS/I2S_RX_FS input hold after
I2S_TX_BCLK/I2S_RX_BCLK
—
I2S_TX_BCLK to I2S_TXD/I2S_TX_FS output valid
• Multiple SAI Synchronous mode
• All other modes
—
—
24
20.6
S16
S17
S18
S19
I2S_TX_BCLK to I2S_TXD/I2S_TX_FS output invalid
I2S_RXD setup before I2S_RX_BCLK
0
—
—
—
25
ns
ns
ns
ns
5.8
2
I2S_RXD hold after I2S_RX_BCLK
I2S_TX_FS input assertion to I2S_TXD output valid1
—
1. Applies to first bit in each frame and only if the TCR4[FSE] bit is clear
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S11
S12
I2S_TX_BCLK/
I2S_RX_BCLK (input)
S12
S15
S15
S16
I2S_TX_FS/
I2S_RX_FS (output)
S13
S14
I2S_TX_FS/
I2S_RX_FS (input)
S15
S19
S16
S16
I2S_TXD
I2S_RXD
S17
S18
Figure 36. I2S/SAI timing — slave modes
6.8.7.3 VLPR, VLPW, and VLPS mode performance over the full operating
voltage range
This section provides the operating performance over the full operating voltage for the
device in VLPR, VLPW, and VLPS modes.
Table 50. I2S/SAI master mode timing in VLPR, VLPW, and VLPS modes (full voltage range)
Num.
Characteristic
Min.
Max.
Unit
Operating voltage
1.71
62.5
45%
250
45%
—
3.6
—
V
S1
S2
S3
S4
S5
I2S_MCLK cycle time
ns
I2S_MCLK pulse width high/low
55%
—
MCLK period
I2S_TX_BCLK/I2S_RX_BCLK cycle time (output)
I2S_TX_BCLK/I2S_RX_BCLK pulse width high/low
ns
55%
45
BCLK period
ns
I2S_TX_BCLK/I2S_RX_BCLK to I2S_TX_FS/
I2S_RX_FS output valid
S6
I2S_TX_BCLK/I2S_RX_BCLK to I2S_TX_FS/
I2S_RX_FS output invalid
0
—
ns
S7
S8
S9
I2S_TX_BCLK to I2S_TXD valid
I2S_TX_BCLK to I2S_TXD invalid
—
45
—
—
ns
ns
ns
-1.6
45
I2S_RXD/I2S_RX_FS input setup before
I2S_RX_BCLK
S10
I2S_RXD/I2S_RX_FS input hold after I2S_RX_BCLK
0
—
ns
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S1
S2
S2
I2S_MCLK (output)
S3
S4
I2S_TX_BCLK/
I2S_RX_BCLK (output)
S4
S5
S7
S6
I2S_TX_FS/
I2S_RX_FS (output)
S10
S9
I2S_TX_FS/
I2S_RX_FS (input)
S7
S8
S8
I2S_TXD
I2S_RXD
S9
S10
Figure 37. I2S/SAI timing — master modes
Table 51. I2S/SAI slave mode timing in VLPR, VLPW, and VLPS modes (full voltage range)
Num.
Characteristic
Min.
Max.
Unit
Operating voltage
1.71
250
3.6
—
V
S11
S12
I2S_TX_BCLK/I2S_RX_BCLK cycle time (input)
ns
I2S_TX_BCLK/I2S_RX_BCLK pulse width high/low
(input)
45%
55%
MCLK period
S13
S14
I2S_TX_FS/I2S_RX_FS input setup before
I2S_TX_BCLK/I2S_RX_BCLK
30
3
—
ns
ns
I2S_TX_FS/I2S_RX_FS input hold after
I2S_TX_BCLK/I2S_RX_BCLK
—
S15
S16
S17
S18
S19
I2S_TX_BCLK to I2S_TXD/I2S_TX_FS output valid
I2S_TX_BCLK to I2S_TXD/I2S_TX_FS output invalid
I2S_RXD setup before I2S_RX_BCLK
—
0
63
—
—
—
72
ns
ns
ns
ns
ns
30
2
I2S_RXD hold after I2S_RX_BCLK
I2S_TX_FS input assertion to I2S_TXD output valid1
—
1. Applies to first bit in each frame and only if the TCR4[FSE] bit is clear
K10 Sub-Family, Rev. 7, 02/2018
NXP Semiconductors
67
Peripheral operating requirements and behaviors
S11
S12
I2S_TX_BCLK/
I2S_RX_BCLK (input)
S12
S15
S15
S16
I2S_TX_FS/
I2S_RX_FS (output)
S13
S14
I2S_TX_FS/
I2S_RX_FS (input)
S15
S19
S16
S16
I2S_TXD
I2S_RXD
S17
S18
Figure 38. I2S/SAI timing — slave modes
6.9 Human-machine interfaces (HMI)
6.9.1 TSI electrical specifications
Table 52. TSI electrical specifications
Symbol Description
VDDTSI Operating voltage
CELE Target electrode capacitance range
Min.
1.71
1
Typ.
—
20
8
Max.
3.6
500
15
Unit
V
Notes
pF
1
fREFmax Reference oscillator frequency
fELEmax Electrode oscillator frequency
—
MHz
MHz
pF
2, 3
2, 4
—
1
1.8
—
CREF
VDELTA
IREF
Internal reference capacitor
Oscillator delta voltage
—
1
—
600
—
mV
μA
2, 5
2, 6
Reference oscillator current source base current
• 2 μA setting (REFCHRG = 0)
—
—
2
3
36
50
• 32 μA setting (REFCHRG = 15)
IELE
Electrode oscillator current source base current
• 2 μA setting (EXTCHRG = 0)
μA
2, 7
—
—
2
36
3
50
• 32 μA setting (EXTCHRG = 15)
Pres5
Electrode capacitance measurement precision
—
8.3333
8.3333
8.3333
1.46
—
38400
38400
38400
—
fF/count
fF/count
fF/count
fF/count
bits
8
9
Pres20 Electrode capacitance measurement precision
Pres100 Electrode capacitance measurement precision
MaxSens Maximum sensitivity
—
—
10
11
0.008
—
Res
Resolution
16
TCon20
Response time @ 20 pF
8
15
25
μs
12
13
ITSI_RUN Current added in run mode
ITSI_LP Low power mode current adder
—
55
—
μA
—
1.3
2.5
μA
K10 Sub-Family, Rev. 7, 02/2018
68
NXP Semiconductors
Dimensions
1. The TSI module is functional with capacitance values outside this range. However, optimal performance is not guaranteed.
2. Fixed external capacitance of 20 pF.
3. REFCHRG = 2, EXTCHRG=0.
4. REFCHRG = 0, EXTCHRG = 10.
5. VDD = 3.0 V.
6. The programmable current source value is generated by multiplying the SCANC[REFCHRG] value and the base current.
7. The programmable current source value is generated by multiplying the SCANC[EXTCHRG] value and the base current.
8. Measured with a 5 pF electrode, reference oscillator frequency of 10 MHz, PS = 128, NSCN = 8; Iext = 16.
9. Measured with a 20 pF electrode, reference oscillator frequency of 10 MHz, PS = 128, NSCN = 2; Iext = 16.
10. Measured with a 20 pF electrode, reference oscillator frequency of 10 MHz, PS = 16, NSCN = 3; Iext = 16.
11. Sensitivity defines the minimum capacitance change when a single count from the TSI module changes. Sensitivity
depends on the configuration used. The documented values are provided as examples calculated for a specific
configuration of operating conditions using the following equation: (Cref * Iext)/( Iref * PS * NSCN)
The typical value is calculated with the following configuration:
Iext = 6 μA (EXTCHRG = 2), PS = 128, NSCN = 2, Iref = 16 μA (REFCHRG = 7), Cref = 1.0 pF
The minimum value is calculated with the following configuration:
Iext = 2 μA (EXTCHRG = 0), PS = 128, NSCN = 32, Iref = 32 μA (REFCHRG = 15), Cref = 0.5 pF
The highest possible sensitivity is the minimum value because it represents the smallest possible capacitance that can be
measured by a single count.
12. Time to do one complete measurement of the electrode. Sensitivity resolution of 0.0133 pF, PS = 0, NSCN = 0, 1
electrode, EXTCHRG = 7.
13. REFCHRG=0, EXTCHRG=4, PS=7, NSCN=0F, LPSCNITV=F, LPO is selected (1 kHz), and fixed external capacitance of
20 pF. Data is captured with an average of 7 periods window.
7 Dimensions
7.1 Obtaining package dimensions
Package dimensions are provided in package drawings.
To find a package drawing, go to nxp.com and perform a keyword search for the
drawing’s document number:
If you want the drawing for this package
144-pin LQFP
Then use this document number
98ASS23177W
98ASA00222D
144-pin MAPBGA
8 Pinout
8.1 Pins with active pull control after reset
The following pins are actively pulled up or down after reset:
K10 Sub-Family, Rev. 7, 02/2018
NXP Semiconductors
69
Pinout
Table 53. Pins with active pull control after reset
Pin
Active pull direction after reset
PTA0
pulldown
pullup
pullup
pullup
pullup
PTA1
PTA3
PTA4
RESET_b
8.2 K10 Signal Multiplexing and Pin Assignments
The following table shows the signals available on each pin and the locations of these
pins on the devices supported by this document. The Port Control Module is responsible
for selecting which ALT functionality is available on each pin.
144
144
Pin Name
Default
ALT0
ALT1
ALT2
ALT3
ALT4
ALT5
ALT6
ALT7
EzPort
LQFP MAP
BGA
—
L5
RTC_
RTC_
RTC_
WAKEUP_B
WAKEUP_B
WAKEUP_B
—
—
—
—
1
M5
A10
B10
C10
D3
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
PTE0
ADC1_SE4a
ADC1_SE4a
PTE0
SPI1_PCS1
SPI1_SOUT
SPI1_SCK
SPI1_SIN
UART1_TX
UART1_RX
SDHC0_D1
SDHC0_D0
I2C1_SDA
I2C1_SCL
RTC_
CLKOUT
2
3
4
D2
D1
E4
PTE1/
LLWU_P0
ADC1_SE5a
ADC1_SE6a
ADC1_SE7a
ADC1_SE5a
ADC1_SE6a
ADC1_SE7a
PTE1/
LLWU_P0
SPI1_SIN
PTE2/
LLWU_P1
PTE2/
LLWU_P1
UART1_
CTS_b
SDHC0_
DCLK
PTE3
PTE3
UART1_
RTS_b
SDHC0_CMD
SPI1_SOUT
5
6
7
E5
F6
E3
VDD
VSS
VDD
VDD
VSS
VSS
PTE4/
LLWU_P2
DISABLED
PTE4/
LLWU_P2
SPI1_PCS0
UART3_TX
UART3_RX
SDHC0_D3
8
9
E2
E1
PTE5
PTE6
DISABLED
DISABLED
PTE5
PTE6
SPI1_PCS2
SPI1_PCS3
SDHC0_D2
I2S0_MCLK
FTM3_CH0
FTM3_CH1
UART3_
CTS_b
10
F4
PTE7
DISABLED
PTE7
UART3_
RTS_b
I2S0_RXD0
FTM3_CH2
11
12
F3
F2
PTE8
PTE9
ADC2_SE16
ADC2_SE17
ADC2_SE16
ADC2_SE17
PTE8
PTE9
I2S0_RXD1
I2S0_TXD1
UART5_TX
UART5_RX
I2S0_RX_FS
FTM3_CH3
FTM3_CH4
I2S0_RX_
BCLK
K10 Sub-Family, Rev. 7, 02/2018
70
NXP Semiconductors
Pinout
144
144
Pin Name
Default
ALT0
ALT1
ALT2
ALT3
ALT4
ALT5
ALT6
ALT7
EzPort
LQFP MAP
BGA
13
14
15
F1
G4
G3
PTE10
DISABLED
ADC3_SE16
ADC3_SE17
PTE10
UART5_
CTS_b
I2S0_TXD0
FTM3_CH5
FTM3_CH6
FTM3_CH7
PTE11
PTE12
ADC3_SE16
ADC3_SE17
PTE11
PTE12
UART5_
RTS_b
I2S0_TX_FS
I2S0_TX_
BCLK
16
17
18
19
E6
F7
H1
H2
VDD
VDD
VDD
VSS
VSS
VSS
PTE16
PTE17
ADC0_SE4a
ADC0_SE5a
ADC0_SE4a
ADC0_SE5a
PTE16
PTE17
SPI0_PCS0
SPI0_SCK
UART2_TX
UART2_RX
FTM_CLKIN0
FTM_CLKIN1
FTM0_FLT3
LPTMR0_
ALT3
20
21
G1
G2
PTE18
PTE19
VSS
ADC0_SE6a
ADC0_SE7a
VSS
ADC0_SE6a
ADC0_SE7a
VSS
PTE18
PTE19
SPI0_SOUT
SPI0_SIN
UART2_
CTS_b
I2C0_SDA
I2C0_SCL
UART2_
RTS_b
CMP3_OUT
22
23
H3
J1
PGA2_DP/
ADC2_DP0/
ADC3_DP3/
ADC0_DP1
PGA2_DP/
ADC2_DP0/
ADC3_DP3/
ADC0_DP1
PGA2_DP/
ADC2_DP0/
ADC3_DP3/
ADC0_DP1
24
25
26
J2
K1
K2
PGA2_DM/
ADC2_DM0/
ADC3_DM3/
ADC0_DM1
PGA2_DM/
ADC2_DM0/
ADC3_DM3/
ADC0_DM1
PGA2_DM/
ADC2_DM0/
ADC3_DM3/
ADC0_DM1
PGA3_DP/
ADC3_DP0/
ADC2_DP3/
ADC1_DP1
PGA3_DP/
ADC3_DP0/
ADC2_DP3/
ADC1_DP1
PGA3_DP/
ADC3_DP0/
ADC2_DP3/
ADC1_DP1
PGA3_DM/
ADC3_DM0/
ADC2_DM3/
ADC1_DM1
PGA3_DM/
ADC3_DM0/
ADC2_DM3/
ADC1_DM1
PGA3_DM/
ADC3_DM0/
ADC2_DM3/
ADC1_DM1
27
28
29
30
L1
L2
PGA0_DP/
ADC0_DP0/
ADC1_DP3
PGA0_DP/
ADC0_DP0/
ADC1_DP3
PGA0_DP/
ADC0_DP0/
ADC1_DP3
PGA0_DM/
ADC0_DM0/
ADC1_DM3
PGA0_DM/
ADC0_DM0/
ADC1_DM3
PGA0_DM/
ADC0_DM0/
ADC1_DM3
M1
M2
PGA1_DP/
ADC1_DP0/
ADC0_DP3
PGA1_DP/
ADC1_DP0/
ADC0_DP3
PGA1_DP/
ADC1_DP0/
ADC0_DP3
PGA1_DM/
ADC1_DM0/
ADC0_DM3
PGA1_DM/
ADC1_DM0/
ADC0_DM3
PGA1_DM/
ADC1_DM0/
ADC0_DM3
31
32
33
34
H5
G5
G6
H6
VDDA
VREFH
VREFL
VSSA
VDDA
VREFH
VREFL
VSSA
VDDA
VREFH
VREFL
VSSA
K10 Sub-Family, Rev. 7, 02/2018
NXP Semiconductors
71
Pinout
144
144
Pin Name
Default
ALT0
ALT1
ALT2
ALT3
ALT4
ALT5
ALT6
ALT7
EzPort
LQFP MAP
BGA
35
36
37
K3
J3
ADC1_SE16/
CMP2_IN2/
ADC0_SE22
ADC1_SE16/
CMP2_IN2/
ADC0_SE22
ADC1_SE16/
CMP2_IN2/
ADC0_SE22
ADC0_SE16/
CMP1_IN2/
ADC0_SE21
ADC0_SE16/
CMP1_IN2/
ADC0_SE21
ADC0_SE16/
CMP1_IN2/
ADC0_SE21
M3
VREF_OUT/
CMP1_IN5/
CMP0_IN5/
ADC1_SE18
VREF_OUT/
CMP1_IN5/
CMP0_IN5/
ADC1_SE18
VREF_OUT/
CMP1_IN5/
CMP0_IN5/
ADC1_SE18
38
39
L3
L4
DAC0_OUT/
CMP1_IN3/
ADC0_SE23
DAC0_OUT/
CMP1_IN3/
ADC0_SE23
DAC0_OUT/
CMP1_IN3/
ADC0_SE23
DAC1_OUT/
CMP0_IN4/
CMP2_IN3/
ADC1_SE23
DAC1_OUT/
CMP0_IN4/
CMP2_IN3/
ADC1_SE23
DAC1_OUT/
CMP0_IN4/
CMP2_IN3/
ADC1_SE23
40
41
42
43
44
45
M7
M6
L6
—
XTAL32
EXTAL32
VBAT
XTAL32
EXTAL32
VBAT
XTAL32
EXTAL32
VBAT
VDD
VDD
VDD
—
VSS
VSS
VSS
M4
PTE24
ADC0_SE17/
EXTAL1
ADC0_SE17/
EXTAL1
PTE24
CAN1_TX
CAN1_RX
UART4_TX
UART4_RX
I2S1_TX_FS
EWM_OUT_b I2S1_RXD1
46
47
48
K5
K4
J4
PTE25
PTE26
PTE27
ADC0_SE18/
XTAL1
ADC0_SE18/
XTAL1
PTE25
PTE26
PTE27
I2S1_TX_
BCLK
EWM_IN
I2S1_TXD1
ADC3_SE5b
ADC3_SE4b
ADC3_SE7a
ADC3_SE5b
UART4_
CTS_b
I2S1_TXD0
RTC_
CLKOUT
ADC3_SE4b
UART4_
RTS_b
I2S1_MCLK
49
50
H4
J5
PTE28
PTA0
ADC3_SE7a
TSI0_CH1
PTE28
PTA0
JTAG_TCLK/
SWD_CLK/
EZP_CLK
UART0_
CTS_b/
UART0_
COL_b
FTM0_CH5
JTAG_TCLK/
SWD_CLK
EZP_CLK
51
52
J6
PTA1
PTA2
JTAG_TDI/
EZP_DI
TSI0_CH2
TSI0_CH3
PTA1
PTA2
UART0_RX
FTM0_CH6
FTM0_CH7
JTAG_TDI
EZP_DI
K6
JTAG_TDO/
TRACE_
SWO/
UART0_TX
JTAG_TDO/
TRACE_
SWO
EZP_DO
EZP_DO
53
54
55
56
K7
L7
PTA3
JTAG_TMS/
SWD_DIO
TSI0_CH4
TSI0_CH5
PTA3
UART0_
RTS_b
FTM0_CH0
FTM0_CH1
FTM0_CH2
JTAG_TMS/
SWD_DIO
PTA4/
LLWU_P3
NMI_b/
EZP_CS_b
PTA4/
LLWU_P3
NMI_b
EZP_CS_b
M8
E7
PTA5
VDD
DISABLED
VDD
PTA5
CMP2_OUT
I2S0_TX_
BCLK
JTAG_TRST_
b
VDD
K10 Sub-Family, Rev. 7, 02/2018
72
NXP Semiconductors
Pinout
144
144
Pin Name
Default
ALT0
ALT1
ALT2
ALT3
ALT4
ALT5
ALT6
ALT7
EzPort
LQFP MAP
BGA
57
58
G7
J7
VSS
VSS
VSS
PTA6
PTA7
PTA8
PTA9
PTA10
PTA11
PTA12
ADC3_SE6a
ADC0_SE10
ADC0_SE11
ADC3_SE5a
ADC3_SE4a
ADC3_SE15
CMP2_IN0
ADC3_SE6a
ADC0_SE10
ADC0_SE11
ADC3_SE5a
ADC3_SE4a
ADC3_SE15
CMP2_IN0
PTA6
FTM0_CH3
FTM0_CH4
FTM1_CH0
FTM1_CH1
FTM2_CH0
FTM2_CH1
FTM1_CH0
FTM1_CH1
UART0_TX
UART0_RX
I2S1_RXD0
CLKOUT
TRACE_
CLKOUT
59
60
61
62
63
64
65
66
J8
K8
L8
PTA7
I2S1_RX_
BCLK
TRACE_D3
TRACE_D2
TRACE_D1
TRACE_D0
PTA8
I2S1_RX_FS
FTM1_QD_
PHA
PTA9
FTM1_QD_
PHB
M9
L9
PTA10
PTA11
PTA12
FTM2_QD_
PHA
FTM2_QD_
PHB
K9
J9
CAN0_TX
CAN0_RX
SPI0_PCS0
I2S0_TXD0
FTM1_QD_
PHA
PTA13/
LLWU_P4
CMP2_IN1
CMP2_IN1
PTA13/
LLWU_P4
I2S0_TX_FS
FTM1_QD_
PHB
L10
PTA14
CMP3_IN0
CMP3_IN0
PTA14
I2S0_RX_
BCLK
I2S0_TXD1
I2S0_RXD1
67
68
L11
K10
PTA15
PTA16
CMP3_IN1
CMP3_IN2
CMP3_IN1
CMP3_IN2
PTA15
PTA16
SPI0_SCK
I2S0_RXD0
SPI0_SOUT
UART0_
CTS_b/
UART0_
COL_b
I2S0_RX_FS
69
K11
PTA17
ADC1_SE17
ADC1_SE17
PTA17
SPI0_SIN
UART0_
RTS_b
I2S0_MCLK
70
71
72
73
E8
G8
VDD
VDD
VDD
VSS
VSS
VSS
M12
M11
PTA18
PTA19
EXTAL0
XTAL0
EXTAL0
XTAL0
PTA18
PTA19
FTM0_FLT2
FTM1_FLT0
FTM_CLKIN0
FTM_CLKIN1
LPTMR0_
ALT1
74
75
76
77
78
79
80
81
L12
K12
J12
J11
J10
H12
H11
H10
RESET_b
PTA24
PTA25
PTA26
PTA27
PTA28
PTA29
RESET_b
RESET_b
CMP3_IN4
CMP3_IN5
ADC2_SE15
ADC2_SE14
ADC2_SE13
ADC2_SE12
CMP3_IN4
CMP3_IN5
ADC2_SE15
ADC2_SE14
ADC2_SE13
ADC2_SE12
PTA24
PTA25
PTA26
PTA27
PTA28
PTA29
FB_A29
FB_A28
FB_A27
FB_A26
FB_A25
FB_A24
PTB0/
LLWU_P5
ADC0_SE8/
ADC1_SE8/
ADC2_SE8/
ADC3_SE8/
TSI0_CH0
ADC0_SE8/
ADC1_SE8/
ADC2_SE8/
ADC3_SE8/
TSI0_CH0
PTB0/
LLWU_P5
I2C0_SCL
I2C0_SDA
FTM1_CH0
FTM1_CH1
FTM1_QD_
PHA
82
H9
PTB1
ADC0_SE9/
ADC1_SE9/
ADC2_SE9/
ADC0_SE9/
ADC1_SE9/
ADC2_SE9/
PTB1
FTM1_QD_
PHB
K10 Sub-Family, Rev. 7, 02/2018
NXP Semiconductors
73
Pinout
144
144
Pin Name
Default
ALT0
ALT1
ALT2
ALT3
ALT4
ALT5
ALT6
ALT7
EzPort
LQFP MAP
BGA
ADC3_SE9/
TSI0_CH6
ADC3_SE9/
TSI0_CH6
83
84
G12
G11
PTB2
ADC0_SE12/
TSI0_CH7
ADC0_SE12/
TSI0_CH7
PTB2
I2C0_SCL
I2C0_SDA
UART0_
RTS_b
FTM0_FLT3
FTM0_FLT0
PTB3
ADC0_SE13/
TSI0_CH8
ADC0_SE13/
TSI0_CH8
PTB3
UART0_
CTS_b/
UART0_
COL_b
85
86
87
88
89
G10
G9
PTB4
PTB5
PTB6
PTB7
PTB8
ADC1_SE10
ADC1_SE11
ADC1_SE12
ADC1_SE13
DISABLED
ADC1_SE10
ADC1_SE11
ADC1_SE12
ADC1_SE13
PTB4
PTB5
PTB6
PTB7
PTB8
FTM1_FLT0
FTM2_FLT0
F12
F11
F10
FB_AD23
FB_AD22
FB_AD21
UART3_
RTS_b
90
91
F9
PTB9
DISABLED
PTB9
SPI1_PCS1
SPI1_PCS0
SPI1_SCK
UART3_
CTS_b
FB_AD20
FB_AD19
FB_AD18
E12
PTB10
ADC1_SE14
ADC1_SE14
PTB10
PTB11
UART3_RX
I2S1_TX_
BCLK
FTM0_FLT1
FTM0_FLT2
92
93
94
95
96
97
E11
H7
PTB11
VSS
ADC1_SE15
VSS
ADC1_SE15
VSS
UART3_TX
I2S1_TX_FS
F5
VDD
VDD
VDD
E10
E9
PTB16
PTB17
PTB18
TSI0_CH9
TSI0_CH10
TSI0_CH11
TSI0_CH9
TSI0_CH10
TSI0_CH11
PTB16
PTB17
PTB18
SPI1_SOUT
SPI1_SIN
CAN0_TX
UART0_RX
UART0_TX
FTM2_CH0
I2S1_TXD0
I2S1_TXD1
FB_AD17
FB_AD16
FB_AD15
EWM_IN
EWM_OUT_b
D12
I2S0_TX_
BCLK
FTM2_QD_
PHA
98
99
D11
D10
PTB19
PTB20
TSI0_CH12
ADC2_SE4a
TSI0_CH12
ADC2_SE4a
PTB19
PTB20
CAN0_RX
FTM2_CH1
I2S0_TX_FS
FB_OE_b
FTM2_QD_
PHB
SPI2_PCS0
FB_AD31/
NFC_
DATA15
CMP0_OUT
CMP1_OUT
CMP2_OUT
CMP3_OUT
I2S0_TXD1
I2S0_TXD0
100
101
102
103
104
D9
PTB21
PTB22
PTB23
PTC0
ADC2_SE5a
DISABLED
DISABLED
ADC2_SE5a
PTB21
PTB22
PTB23
PTC0
SPI2_SCK
SPI2_SOUT
SPI2_SIN
FB_AD30/
NFC_
DATA14
C12
C11
B12
B11
FB_AD29/
NFC_
DATA13
SPI0_PCS5
FB_AD28/
NFC_
DATA12
ADC0_SE14/
TSI0_CH13
ADC0_SE14/
TSI0_CH13
SPI0_PCS4
SPI0_PCS3
PDB0_
EXTRG
FB_AD14/
NFC_
DATA11
PTC1/
LLWU_P6
ADC0_SE15/
TSI0_CH14
ADC0_SE15/
TSI0_CH14
PTC1/
LLWU_P6
UART1_
RTS_b
FTM0_CH0
FB_AD13/
NFC_
DATA10
K10 Sub-Family, Rev. 7, 02/2018
74
NXP Semiconductors
Pinout
144
144
Pin Name
Default
ALT0
ALT1
ALT2
ALT3
ALT4
ALT5
ALT6
ALT7
EzPort
LQFP MAP
BGA
105
106
A12
A11
PTC2
ADC0_SE4b/
CMP1_IN0/
TSI0_CH15
ADC0_SE4b/
CMP1_IN0/
TSI0_CH15
PTC2
SPI0_PCS2
SPI0_PCS1
UART1_
CTS_b
FTM0_CH1
FTM0_CH2
FB_AD12/
NFC_DATA9
I2S0_TX_FS
PTC3/
LLWU_P7
CMP1_IN1
CMP1_IN1
PTC3/
LLWU_P7
UART1_RX
CLKOUT
I2S0_TX_
BCLK
107
108
109
H8
—
VSS
VDD
VSS
VSS
VDD
VDD
A9
PTC4/
LLWU_P8
DISABLED
PTC4/
LLWU_P8
SPI0_PCS0
SPI0_SCK
SPI0_SOUT
SPI0_SIN
UART1_TX
FTM0_CH3
I2S0_RXD0
FB_AD11/
NFC_DATA8
CMP1_OUT
CMP0_OUT
I2S0_MCLK
I2S1_TX_
BCLK
110
111
112
113
114
115
116
117
118
D8
C8
B8
A8
D7
C7
B7
A7
D6
PTC5/
LLWU_P9
DISABLED
CMP0_IN0
CMP0_IN1
PTC5/
LLWU_P9
LPTMR0_
ALT2
FB_AD10/
NFC_DATA7
I2S1_TX_FS
PTC6/
LLWU_P10
CMP0_IN0
CMP0_IN1
PTC6/
LLWU_P10
PDB0_
EXTRG
I2S0_RX_
BCLK
FB_AD9/
NFC_DATA6
PTC7
PTC8
PTC9
PTC10
PTC7
PTC8
PTC9
PTC10
I2S0_RX_FS
FB_AD8/
NFC_DATA5
ADC1_SE4b/
CMP0_IN2
ADC1_SE4b/
CMP0_IN2
FTM3_CH4
FTM3_CH5
FTM3_CH6
FTM3_CH7
I2S0_MCLK
FB_AD7/
NFC_DATA4
ADC1_SE5b/
CMP0_IN3
ADC1_SE5b/
CMP0_IN3
I2S0_RX_
BCLK
FB_AD6/
NFC_DATA3
FTM2_FLT0
I2S1_MCLK
ADC1_SE6b
ADC1_SE7b
DISABLED
DISABLED
ADC1_SE6b
I2C1_SCL
I2C1_SDA
I2S0_RX_FS
FB_AD5/
NFC_DATA2
PTC11/
LLWU_P11
ADC1_SE7b
PTC11/
LLWU_P11
I2S0_RXD1
FB_RW_b/
NFC_WE
PTC12
PTC13
PTC12
PTC13
UART4_
RTS_b
FB_AD27
FTM3_FLT0
UART4_
CTS_b
FB_AD26
119
120
121
122
123
C6
B6
—
PTC14
PTC15
VSS
DISABLED
DISABLED
VSS
PTC14
PTC15
UART4_RX
UART4_TX
FB_AD25
FB_AD24
VSS
VDD
—
VDD
VDD
A6
PTC16
DISABLED
PTC16
PTC17
PTC18
PTC19
CAN1_RX
CAN1_TX
UART3_RX
UART3_TX
FB_CS5_b/
FB_TSIZ1/
FB_BE23_
16_b
NFC_RB
124
125
D5
C5
PTC17
PTC18
PTC19
DISABLED
DISABLED
FB_CS4_b/
FB_TSIZ0/
FB_BE31_
24_b
NFC_CE0_b
NFC_CE1_b
UART3_
RTS_b
FB_TBST_b/
FB_CS2_b/
FB_BE15_8_
b
126
127
B5
A5
DISABLED
DISABLED
UART3_
CTS_b
FB_CS3_b/
FB_BE7_0_b
FB_TA_b
PTD0/
LLWU_P12
PTD0/
LLWU_P12
SPI0_PCS0
UART2_
RTS_b
FTM3_CH0
FB_ALE/
FB_CS1_b/
FB_TS_b
I2S1_RXD1
K10 Sub-Family, Rev. 7, 02/2018
NXP Semiconductors
75
Pinout
144
144
Pin Name
Default
ALT0
ALT1
ALT2
ALT3
ALT4
ALT5
ALT6
ALT7
EzPort
LQFP MAP
BGA
128
129
130
131
132
D4
C4
B4
A4
A3
PTD1
ADC0_SE5b
DISABLED
DISABLED
DISABLED
ADC0_SE6b
ADC0_SE5b
PTD1
SPI0_SCK
SPI0_SOUT
SPI0_SIN
UART2_
CTS_b
FTM3_CH1
FTM3_CH2
FTM3_CH3
FTM0_CH4
FTM0_CH5
FB_CS0_b
FB_AD4
FB_AD3
I2S1_RXD0
PTD2/
LLWU_P13
PTD2/
LLWU_P13
UART2_RX
I2S1_RX_FS
PTD3
PTD3
UART2_TX
I2S1_RX_
BCLK
PTD4/
LLWU_P14
PTD4/
LLWU_P14
SPI0_PCS1
SPI0_PCS2
UART0_
RTS_b
FB_AD2/
NFC_DATA1
EWM_IN
PTD5
ADC0_SE6b
ADC0_SE7b
PTD5
UART0_
CTS_b/
UART0_
COL_b
FB_AD1/
NFC_DATA0
EWM_OUT_b
133
A2
PTD6/
LLWU_P15
ADC0_SE7b
PTD6/
LLWU_P15
SPI0_PCS3
UART0_RX
FTM0_CH6
FTM0_CH7
FB_AD0
FTM0_FLT0
FTM0_FLT1
134
135
136
137
M10
F8
VSS
VSS
VSS
VDD
VDD
PTD7
PTD8
VDD
A1
DISABLED
DISABLED
PTD7
PTD8
CMT_IRO
I2C0_SCL
UART0_TX
UART5_RX
C9
FB_A16/
NFC_CLE
138
139
140
B9
B3
B2
PTD9
DISABLED
DISABLED
DISABLED
PTD9
I2C0_SDA
UART5_TX
FB_A17/
NFC_ALE
PTD10
PTD11
PTD10
PTD11
UART5_
RTS_b
FB_A18/
NFC_RE
SPI2_PCS0
UART5_
CTS_b
SDHC0_
CLKIN
FB_A19
141
142
143
144
B1
C3
C2
C1
PTD12
PTD13
PTD14
PTD15
DISABLED
DISABLED
DISABLED
DISABLED
PTD12
PTD13
PTD14
PTD15
SPI2_SCK
SPI2_SOUT
SPI2_SIN
FTM3_FLT0
SDHC0_D4
SDHC0_D5
SDHC0_D6
SDHC0_D7
FB_A20
FB_A21
FB_A22
FB_A23
SPI2_PCS1
8.3 K10 pinouts
The figure below shows the pinout diagram for the devices supported by this document.
Many signals may be multiplexed onto a single pin. To determine what signals can be
used on which pin, see the previous section.
K10 Sub-Family, Rev. 7, 02/2018
76
NXP Semiconductors
Pinout
PTE0
1
108
107
106
105
104
103
102
101
100
99
VDD
VSS
PTE1/LLWU_P0
2
PTE2/LLWU_P1
3
PTC3/LLWU_P7
PTC2
PTE3
4
VDD
5
PTC1/LLWU_P6
PTC0
VSS
6
PTE4/LLWU_P2
7
PTB23
PTB22
PTB21
PTB20
PTB19
PTB18
PTB17
PTB16
VDD
PTE5
8
PTE6
9
PTE7
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
PTE8
98
PTE9
97
PTE10
96
PTE11
95
PTE12
94
VDD
VSS
93
VSS
PTB11
PTB10
PTB9
92
PTE16
91
PTE17
PTE18
90
PTB8
89
PTE19
PTB7
88
VSS
PTB6
87
PGA2_DP/ADC2_DP0/ADC3_DP3/ADC0_DP1
PGA2_DM/ADC2_DM0/ADC3_DM3/ADC0_DM1
PGA3_DP/ADC3_DP0/ADC2_DP3/ADC1_DP1
PGA3_DM/ADC3_DM0/ADC2_DM3/ADC1_DM1
PGA0_DP/ADC0_DP0/ADC1_DP3
PGA0_DM/ADC0_DM0/ADC1_DM3
PGA1_DP/ADC1_DP0/ADC0_DP3
PGA1_DM/ADC1_DM0/ADC0_DM3
VDDA
PTB5
86
PTB4
85
PTB3
84
PTB2
83
PTB1
82
PTB0/LLWU_P5
PTA29
PTA28
PTA27
PTA26
PTA25
PTA24
RESET_b
PTA19
81
80
79
78
VREFH
77
VREFL
76
VSSA
75
ADC1_SE16/CMP2_IN2/ADC0_SE22
ADC0_SE16/CMP1_IN2/ADC0_SE21
74
73
Figure 39. K10 144 LQFP Pinout Diagram
K10 Sub-Family, Rev. 7, 02/2018
NXP Semiconductors
77
Revision History
1
2
3
4
5
6
7
8
9
10
11
12
PTC4/
LLWU_P8
PTC3/
LLWU_P7
PTD6/
LLWU_P15
PTD4/
LLWU_P14
PTD0/
LLWU_P12
A
B
C
D
E
F
PTC8
NC
PTC2
A
B
C
D
E
F
PTD7
PTD12
PTD15
PTD5
PTC16
PTC12
PTC11/
LLWU_P11
PTC1/
LLWU_P6
PTD11
PTD14
PTD10
PTD13
PTE0
PTD3
PTC19
PTC18
PTC17
VDD
PTC15
PTC14
PTC13
VDD
PTC7
PTD9
PTD8
PTB21
PTB17
PTB9
PTB5
PTB1
NC
NC
PTC0
PTB22
PTB18
PTB10
PTB6
PTD2/
LLWU_P13
PTC6/
LLWU_P10
PTC10
PTC9
VDD
VSS
PTB23
PTB19
PTB11
PTB7
PTE2/
LLWU_P1
PTE1/
LLWU_P0
PTC5/
LLWU_P9
PTD1
PTE3
PTB20
PTB16
PTB8
PTB4
PTE4/
LLWU_P2
PTE6
PTE10
PTE18
PTE5
PTE9
VDD
VDD
VSS
PTE8
PTE12
VSS
PTE7
VDD
VSS
G
H
J
G
H
J
PTE19
PTE11
PTE28
PTE27
PTE26
VREFH
VDDA
PTA0
VREFL
VSSA
PTA1
VSS
PTB3
PTB2
PTB0/
LLWU_P5
PTE16
PTE17
VSS
VSS
PTA29
PTA26
PTA17
PTA15
PTA28
PTA25
PTA24
RESET_b
PGA2_DP/
PGA2_DM/
ADC2_DP0/ ADC2_DM0/
ADC3_DP3/ ADC3_DM3/
ADC0_SE16/
CMP1_IN2/
ADC0_SE21
PTA13/
LLWU_P4
PTA6
PTA3
PTA7
PTA8
PTA9
PTA27
PTA16
PTA14
ADC0_DP1
ADC0_DM1
PGA3_DP/
PGA3_DM/
ADC3_DP0/ ADC3_DM0/
ADC2_DP3/ ADC2_DM3/
ADC1_SE16/
CMP2_IN2/
ADC0_SE22
K
L
K
L
PTE25
PTA2
PTA12
PTA11
ADC1_DP1
ADC1_DM1
DAC1_OUT/
CMP0_IN4/
CMP2_IN3/
ADC1_SE23
PGA0_DP/
PGA0_DM/ DAC0_OUT/
ADC0_DP0/ ADC0_DM0/ CMP1_IN3/
RTC_
WAKEUP_B
PTA4/
LLWU_P3
VBAT
ADC1_DP3
ADC1_DM3 ADC0_SE23
VREF_OUT/
PGA1_DM/
PGA1_DP/
CMP1_IN5/
M
M
ADC1_DP0/ ADC1_DM0/
PTE24
NC
EXTAL32
XTAL32
PTA5
PTA10
VSS
PTA19
PTA18
CMP0_IN5/
ADC1_SE18
ADC0_DP3
ADC0_DM3
1
2
3
4
5
6
7
8
9
10
11
12
Figure 40. K10 144 MAPBGA Pinout Diagram
9 Revision History
The following table provides a revision history for this document.
Table 54. Revision History
Rev. No.
Date
Substantial Changes
3
3/2012
Initial public release
Table continues on the next page...
K10 Sub-Family, Rev. 7, 02/2018
78
NXP Semiconductors
Revision History
Table 54. Revision History (continued)
Rev. No.
Date
Substantial Changes
4
5
10/2012
10/2013
Replaced TBDs throughout.
Changes for 4N96B mask set:
• Min VDD operating requirement specification updated to support operation down to
1.71V.
New specifications:
• Updated Vdd_ddr min specification.
• Added Vodpu specification.
• Removed Ioz, Ioz_ddr, and Ioz_tamper Hi-Z leakage specfications. They have been
replaced by new Iina, Iind, and Zind specifications.
• Fpll_ref_acc specification has been added.
• I2C module was previously covered by the general switching specifications. To provide
more detail on I2C operation a dedicated Inter-Integrated Circuit Interface (I2C) timing
section has been added.
Modified specifications:
• Vref_ddr max spec has been updated.
• Tpor spec has been split into two specifications based on VDD slew rate.
• Trd1allx and Trd1alln max have been updated.
• 16-bit ADC Temp sensor slope and Temp sensor voltage (Vtemp25) have been
modified. The typical values that were listed previously have been updated, and min
and max specifications have been added.
Corrections:
• Some versions of the datasheets listed incorrect clock mode information in the
"Diagram: Typical IDD_RUN operating behavior section." These errors have been
corrected.
• Fintf_ft specification was previously shown as a max value. It has been corrected to be
shown as a typical value as originally intended.
• Corrected DDR write and read timing diagrams to show the correct location of the Tcmv
specification.
• SDHC peripheral 50MHz high speed mode options were left out of the last datasheet.
These have been added to the SDHC specifications section.
6
7
09/2015
02/2018
• Updated the footnotes of Thermal Attributes table
• Removed Power Sequencing section
• Added footnote to ambient temperature specification of Thermal Operating
requirements
• Updated Terminology and guidelines section
• Updated the footnotes and the values of Power consumption operating behaviors table
• Updated I2C timing table
• Updated maximum SDHC frequency in SDHC specifications
K10 Sub-Family, Rev. 7, 02/2018
NXP Semiconductors
79
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Document Number K10P144M120SF3
Revision 7, 02/2018
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