PIC32MX795F512L-80I/BG - Microchip Technology

PIC32MX575/675/695/775/795

The PIC32MX575/675/695/775/795 family devices that

you have received conform functionally to the current

Device Data Sheet (DS61156G), except for the

anomalies described in this document.

The silicon issues discussed in the following pages are

for silicon revisions with the Device and Revision IDs

listed in Table 1. The silicon issues are summarized in

Table 2.

The errata described in this document will be addressed

in future revisions of the PIC32MX575/675/695/775/795

silicon.

Data Sheet clarifications and corrections start on page

13, following the discussion of silicon issues.

The silicon revision level can be identified using the

current version of MPLAB® IDE and Microchip’s pro-

grammers, debuggers and emulation tools, which are

available at the Microchip corporate web site

(www.microchip.com).

For example, to identify the silicon revision level

using MPLAB IDE in conjunction with the REAL

ICE™ In-Circuit Emulator:

1. Using the appropriate interface, connect the

device to the REAL ICE In-Circuit Emulator.

2. From the main menu in MPLAB IDE, select

Configure>Select Device, and then select the

target part number in the dialog box.

3. Select the MPLAB hardware tool

(Debugger>Select Tool).

4. Perform a “Connect” operation to the device

(Debugger>Connect). Depending on the devel-

opment tool used, the part number and Device

Revision ID value appear in the Output window.

The Device and Revision ID values for the various

PIC32MX575/675/695/775/795 silicon revisions are

shown in Table 1.

Note: This document summarizes all silicon

errata issues from all revisions of silicon,

previous as well as current. Only the

issues indicated in the last column of

Table 2 apply to the current silicon

revision (A3).

Note: If you are unable to extract the silicon

revision level, please contact your local

Microchip sales office for assistance.

TABLE 1: SILICON DEVREV VALUES

Part Number Device ID(1) Revision ID for Silicon Revision(2)

A0 A1 A3

PIC32MX575F256H 0x4317053

0x0 0x1 0x3

PIC32MX675F256H 0x430B053

PIC32MX775F256H 0x4303053

PIC32MX575F512H 0x4309053

PIC32MX675F512H 0x430C053

PIC32MX695F512H 0x4325053

PIC32MX775F512H 0x430D053

PIC32MX795F512H 0x430E053

PIC32MX575F256L 0x4333053

PIC32MX675F256L 0x4305053

Note 1: The Device and Revision IDs (DEVID and DEVREV) are located at the last two implemented addresses in

program memory.

2: Refer to the “PIC32MX Flash Programming Specification” (DS61145) for detailed information on Device

and Revision IDs for your specific device.

PIC32MX575/675/695/775/795 Family

Silicon Errata and Data Sheet Clarification

PIC32MX575/675/695/775/795

PIC32MX775F256L 0x4312053

0x0 0x1 0x3

PIC32MX575F512L 0x430F053

PIC32MX675F512L 0x4311053

PIC32MX695F512L 0x4341053

PIC32MX775F512L 0x4307053

PIC32MX795F512L 0x4307053

TABLE 1: SILICON DEVREV VALUES (CONTINUED)

Part Number Device ID(1) Revision ID for Silicon Revision(2)

A0 A1 A3

Note 1: The Device and Revision IDs (DEVID and DEVREV) are located at the last two implemented addresses in

program memory.

2: Refer to the “PIC32MX Flash Programming Specification” (DS61145) for detailed information on Device

and Revision IDs for your specific device.

TABLE 2: SILICON ISSUE SUMMARY

Module Feature Item

Number Issue Summary

Affected

Revisions(1)

A0 A1 A3

I2C™ —1. The SDA line state may not be detected correctly. X X X

Ethernet RMII 10 MB 2. Pause frames are sent at 10x the normal rate. XXX

ADC Interrupt

Generation

3. The interrupt generated by the module cannot be cleared

when the module is disabled.

XXX

Parallel

Master

Port

Slave Mode 4. A PMP interrupt used to wake the device will not be

reflected in the interrupt flag until the end of the write

strobe.

XXX

Output

Compare

Electrical

Specification

5. OC Fault detection is not asynchronous. X X X

SPI —6. The SPIBUSY and SRMT bits assert 1 bit time before the

end of the transaction.

XXX

UART —7. The TXBF bit deasserts one PB clock after the interrupt is

generated.

XXX

USB USB PLL 8. The USBPLL does not automatically suspend in Idle

mode.

XXX

Output

Compare

PWM 9. In PWM mode, the output waveform is one PB clock

longer than the expected value.

XXX

Output

Compare

PWM Fault

Input Mode

10. A Fault interrupt will not be generated if firmware clears

the Fault while the Fault is still asserted.

XXX

DMA Pattern Match 11. In Pattern Match mode, the DMA module may not append

all of the CRC results to the result buffer.

XXX

Timers External Clock 12. In Synchronized External Clock mode, the first period of

the count is short.

XXX

SPI Frame Slave

Mode

13. Outgoing data corruption occurs when the frame signal is

coincident with the clock.

XXX

CAN —14. TXABAT, TXLARB and TXERR may erroneously be

cleared by an aborted read of the CiFIFOCONn register.

XXX

CAN —15. Requested aborts to a TX message via setting

CxCON.ABAT or clearing CiFIFOCON.TXREQ may not

complete.

XXX

Note 1: Only those issues indicated in the last column apply to the current silicon revision.

PIC32MX575/675/695/775/795

CAN —16. The CFIFOCONx.FRESET and CFIFOCONx.UINC bits

are not settable via a normal SFR write.

XXX

CAN DeviceNet™ 17. DeviceNet filtering does not function. X X X

Output

Compare

PWM Fault

Input Mode

18. A Fault may be erroneously cleared due to an aborted

read.

XXX

SPI Slave Mode 19. In Slave mode with STXISEL = 00, a TX buffer underrun

condition will not assert the TX interrupt flag.

XXX

USB —20. The TOKBUSY bit does not correctly indicate status when

a transfer completes within the Start of Frame (SOF)

threshold.

XXX

USB Host Mode 21. In Host mode, the interval between the first two SOF

packets may be less than what is specified by the USB

specification.

XXX

WDT —22. When code-protect is enabled, the WDT is not held in

Reset during the POR RAM Clear Sequence (RCS).

XXX

Oscillator Clock Switch

and Two -Speed

Start-Up

23. Clock switching and Two-Speed Start-up may cause a

general exception when the reserved bit 8 of the DDPCON

XXX

Oscillator Clock Switch 24. Clock source switching may cause a general exception or

POR when switching from a slow clock to a fast clock.

XXX

SPI Slave Mode 25. A wake-up interrupt may not be clearable. X X X

PORTS —26. I/O pins do not tri-state immediately, if previously driven

high.

XXX

SPI —27. Byte writes to the SPISTAT register are not decoded

correctly.

XXX

SPI Frame Mode 28. Recovery from an underrun requires multiple SPI clock

periods.

XXX

CAN —29. The TXBAT bit status may be incorrect after an abort. X X X

UART IrDA®30. The IrDA minimum bit time is not detected at all baud

rates.

XXX

UART IrDA 31. TX data is corrupted when BRG values greater than 0x200

are used.

XXX

JTAG —32. On 64-pin devices, the TMS pin requires an external

pull-up.

XXX

UART —33. The TRMT bit is asserted before the transmission is

complete.

XXX

UART UART Receive

Buffer Overrun

Error Status

34. The OERR bit does not get cleared on a module Reset.

The OERR bit retains its value even after the UART

module is reinitialized.

XXX

ADC Conversion

Trigger from

INT0 Interrupt

35. The ADC module conversion triggers occur on the rising

edge of the INT0 signal even when INT0 is configured to

generate an interrupt on the falling edge.

XXX

JTAG Boundary Scan 36. Pin 100 on 100-pin packages and pin A1 on 121-pin

packages do not respond to boundary scan commands.

XXX

DMA Suspend Status 37. The DMABUSY status bit may not reflect the correct

status if the DMA module is suspended.

XXX

TABLE 2: SILICON ISSUE SUMMARY (CONTINUED)

Module Feature Item

Number Issue Summary

Affected

Revisions(1)

A0 A1 A3

Note 1: Only those issues indicated in the last column apply to the current silicon revision.

PIC32MX575/675/695/775/795

Voltage

Regulator

BOR 38. Device may not exit BOR state if BOR event occurs. X X

Output

Compare

PWM Mode 39. If the Output Compare module is configured for a 0% duty

cycle (OCxRS = 0), a glitch may occur on the next cycle.

XXX

Oscillator Clock Switch 40. If a Fail-Safe Clock Monitor (FSCM) event occurs when

Primary Oscillator (POSC) mode is used, firmware clock

switch requests to switch from FRC mode will fail.

XXX

I2CSlave Mode 41. The I2C module does not respond to address 0x78 when

the STRICT and A10M bits are cleared in the I2CxCON

XXX

USB UIDLE Interrupt 42. UIDLE interrupts cease if the UIDLE interrupt flag is

cleared.

XXX

TABLE 2: SILICON ISSUE SUMMARY (CONTINUED)

Module Feature Item

Number Issue Summary

Affected

Revisions(1)

A0 A1 A3

Note 1: Only those issues indicated in the last column apply to the current silicon revision.

PIC32MX575/675/695/775/795

Silicon Errata Issues

1. Module: I2C™

The I2C modules, with the exception of I2C1 and

I2C2, may not detect state of SDA line correctly:

- In Master mode, module may encounter a

bus collision when performing a Start

condition.

- In Slave mode, module may not Acknowl-

edge the first packet sent after enabling the

I2C module. In this case, it will return a NACK

instead of an ACK.OCxRS.

Work around

Master Mode:

1. Use another I2C node on the bus to

sequence I2C bus transactions such as the

Start event.

2. Connect an unused general-purpose I/O

pin to the SDAx pin of the I2C module to be

used.

The user software must perform the follow-

ing sequence of operations in order to

execute a Start condition on the I2C bus:

a) With the I2C module disabled, clear the

LAT bit of the general-purpose I/O pin

that is connected to the SDAx pin.

Then, clear the corresponding TRIS bit

to make sure the I/O pin is pulled low.

b) Enable the I2C module by setting the

ON bit (I2CxCON<15>); but do not

configure the I2CxBRG register at this

time.

c) Execute a software delay loop of at

least 10 µs.

d) Set the TRIS bit of the I/O pin con-

nected to the SDAx pin. This will make

it an input pin, thereby ensuring that it

goes to a high logic state.

e) Execute a software delay loop of at

least 10 usec.

f) Configure the I2CxBRG register with

the value required by the application.

g) Issue a Start condition by setting the

SEN bit (I2CxCON<0>) as needed. I2C

communications can now proceed

normally.

Slave Mode:

The I2C master device on the bus must either pull

the SDA line low, then high again, prior to sending

the first packet to the device, or must resend the

first packet.

Affected Silicon Revisions

2. Module: Ethernet

In 10 MB RMII mode only, pause frames are sent

at 10x the normal rate. This reduces the available

network bandwidth if the device is connected to

the network via a hub. This does not reduce

functionality or violate specifications.

Work around

If bandwidth is a concern, connect the PIC32

device to a network using an Ethernet switch.

Affected Silicon Revisions

3. Module: ADC

The interrupt generated by the ADC module

cannot be cleared when the ADC module is

disabled.

Work around

Ensure the interrupt is serviced and the interrupt

flag is cleared before turning off the ADC module.

Affected Silicon Revisions

Note: This document summarizes all silicon

errata issues from all revisions of silicon,

previous as well as current. Only the

issues indicated by the shaded column in

the following tables apply to the current

silicon revision (A3). A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

PIC32MX575/675/695/775/795

4. Module: Parallel Master Port

In Slave mode, a PMP interrupt will wake the

device; however, the interrupt source will not be

reflected in the interrupt flag until the end of the

write strobe.

Work around

There are two possible solutions to this issue:

1. If multiple wake-up sources are to be used,

firmware can poll all of the configured wake-

up source interrupt flags. If none are set,

assume the source was the PMP.

2. Firmware can wait for a period exceeding

the write strobe length, and then poll the

PMP interrupt flag.

Affected Silicon Revisions

5. Module: Output Compare

The Fault input detection is not asynchronous.

There is a 1 to 2 Peripheral Bus (PB) clock delay

between the Fault input assertion and the

shutdown of the appropriate OCMP output pin.

Work around

Ensure that the device driven by the OCMP

module can tolerate this shutdown delay.

Affected Silicon Revisions

6. Module: SPI

The SPIBUSY and SRMT bits assert 1 bit time

before the end of the transaction.

Work around

Firmware must provide a 1 bit time delay between

the assertion of these bits and performing any

operation that requires the transaction to be

complete.

Affected Silicon Revisions

7. Module: UART

The UxSTA.TXBF bit clears one PB clock cycle

after the interrupt is generated. When using a PB

bus divisor other than 1:1 and polling the UART

transmit interrupt flag with the next instruction

reading the UxSTA.TXBF bit, the result may not

reflect the actual TXBF status.

Work around

There are two possible solutions to this issue:

1. Only use a PB bus divisor of 1:1.

2. If firmware is polling the transmit interrupt

flag and the TXBF flag, insert a read of the

UxSTA register between these operations

and discard the result. This read will ensure

the status of the TXBF flag is correct when

the next read of this register occurs.

Affected Silicon Revisions

8. Module: USB

When U1CNFG1.USBSIDL is set, the USBPLL

does not automatically suspend in Idle mode.

Work around

Use firmware to manually suspend the USB clock

before entering Sleep mode.

Affected Silicon Revisions

9. Module: Output Compare

In PWM mode, the output waveform is one PB

clock longer than the expected value.

Work around

Load OCRS with a value one less than the number

expected to achieve the desired output.

Affected Silicon Revisions

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

PIC32MX575/675/695/775/795

10. Module: Output Compare

In PWM mode, if firmware attempts to clear the

OCFLT bit while the Fault still exists, a second

interrupt will not be generated for this Fault when

firmware exits the Interrupt Service Routine (ISR).

The OCFLT bit will remain set while a Fault is

detected.

Work around

In the ISR, clear the OSxFLT bit, and test the

OCxFLT bit before exiting the ISR. If the bit is set,

set the OCx interrupt to generate a second

interrupt.

Affected Silicon Revisions

11. Module: DMA

In Pattern Match mode, the DMA module may not

append all of the CRC results to the result buffer.

Work around

Use firmware to read the CRC result and append

it to the result buffer.

Affected Silicon Revisions

12. Module: Timers

When the Timer module is first enabled and the

prescaler value is greater than 1, the number of

input clocks required to increment the timer from 0

to 1 is one input clock, not the value stated by the

prescaler.

Work around

None.

Affected Silicon Revisions

13. Module: SPI

Outgoing data will be corrupted when in Frame

Slave mode with FRMCNT > 0 and the frame pulse

is coincident with the clock.

Work around

1. There is no work around for operation when

the Frame pulse is coincident with the clock.

2. Provide a frame signal that precedes the clock

signal.

Affected Silicon Revisions

14. Module: CAN

TXABAT, TXLARB and TXERR may erroneously

be cleared by an aborted read of the CiFIFOCONn

instruction in the CPU pipeline has started

execution, but is aborted due to an interrupt.

Work around

Disable interrupts before reading the contents of

the CiFIFOCONn register, and then re-enable

interrupts after reading the register.

Affected Silicon Revisions

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

PIC32MX575/675/695/775/795

15. Module: CAN

Requested aborts to a TX message via setting

CxCON.ABAT or clearing CiFIFOCON.TXREQ

may not complete. The CAN bus protocol is not

violated.

Work around

1. After a general abort request, firmware

should poll until CxCON.BUSY = 0 or wait

two message times. If CxCON.ABAT

remains high, the message was success-

fully aborted and the module must be reset

by clearing and setting bit CxCON.ON.

2. After a FIFO specific abort request,

firmware should poll until

CxCON.BUSY = 0 or wait two message

times. If CFIFOCONx.TXREQ remains

high, the message was successfully

aborted and the FIFO must be reset by

setting CFIFOCONx.FRESET and polling

until CFIFOCONx.FRESET = 0.

Affected Silicon Revisions

16. Module: CAN

The CFIFOCONx.FRESET and

CFIFOCONx.UINC bits are not settable via a

normal Special Function Register (SFR) write.

Work around

Use the SET register operations to change the

state of these bits.

Affected Silicon Revisions

17. Module: CAN

The DeviceNet™ message filtering does not

function.

Work around

Use hardware to filter the Standard Identifier (SID)

and use firmware to decode the DeviceNet

identifier.

Affected Silicon Revisions

18. Module: Output Compare

The Output Compare module may reinitialize or

clear a Fault on an aborted read of the OCxCON

instruction in the CPU pipeline has started

execution, but is aborted due to an interrupt.

Work around

Disable interrupts before reading the contents of

the OCxCON register, and then re-enable

interrupts after reading the register.

Affected Silicon Revisions

19. Module: SPI

In Slave mode with STXISEL<1:0> = 00, a TX

buffer underrun condition will not assert the TX

interrupt flag.

Work around

Use any other legal value of STXISEL<1:0> (i.e.,

“01”, “10”, or “11”.

Affected Silicon Revisions

20. Module: USB

The TOKBUSY bit does not correctly indicate sta-

tus when a transfer completes within the Start of

Frame threshold.

Work around

Use a firmware semaphore to track when a token

is written to U1TOK. Firmware then clears the

semaphore when the transfer is complete.

Affected Silicon Revisions

21. Module: USB

In Host mode, the interval between the first two

SOF packets may be less than what is specified by

the USB specification.

Work around

None.

Affected Silicon Revisions

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

PIC32MX575/675/695/775/795

22. Module: WDT

When code-protect is enabled, the WDT is not

held in reset during the POR RAM Clear Sequence

(RCS). If the WDT period does not exceed the

RCS period, the WDT will reset the part and the

RCS sequence will restart.

Work around

Use WDT periods equal to or longer than 128 ms.

Since the RCS and WDT run concurrently,

firmware will have a reduced period in which to

service the WDT for the first time.

Affected Silicon Revisions

23. Module: Oscillator

Clock switching and Two-Speed Start-up may

cause a general exception when the reserved bit 8

of the DDPCON register is ‘0’.

Work around

Ensure that the reserved bit 8 of the DDPCON

DDPCON |= 0x100;

Affected Silicon Revisions

24. Module: Oscillator

Clock source switching may cause a general

exception or POR when switching from a slow

clock to a fast clock.

Work around

Clock source switches should be performed by

first switching to the FRC, and then switching to

the target clock source.

Affected Silicon Revisions

25. Module: SPI

In Slave mode, when entering Sleep mode after a

SPI transfer with SPI interrupts enabled, a false

interrupt may be generated that wakes the device.

This interrupt can be cleared; however, entering

Sleep may cause the condition to occur again.

Work around

Do not use SPI in Slave mode as a wake-up

source from Sleep.

Affected Silicon Revisions

26. Module: PORTS

When an I/O pin is set to output a logic high signal,

and is then changed to an input using the TRISx

registers, the I/O pin should immediately tri-state

and let the pin float. Instead, the pin will continue

to partially drive a logic high signal out for a period

of time.

Work around

The pin should be driven low, prior to being tri-

stated, if it is desirable for the pin to tri-state

quickly.

Affected Silicon Revisions

27. Module: SPI

Byte writes to the SPISTAT register are not

decoded correctly. A byte write to byte zero of

SPISTAT is actually performed on both byte zero

and byte one. A byte write to byte one of SPISTAT

is ignored.

Work around

Only perform word operations on the SPISTAT

Affected Silicon Revisions

A0 A1 A3

XXX

A0 A1 A3

XXX

Note: If the peripheral library is being used,

clock switching is performed

automatically through the FRC.

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

PIC32MX575/675/695/775/795

28. Module: SPI

In Frame mode the module is not immediately

ready for further transfers after clearing the

SPITUR bit. The SPITUR bit will be cleared by

hardware before the SPI state machine is

prepared for the next operation.

Work around

Firmware must wait at least four bit times before

writing to the SPI registers after clearing the

SPITUR bit.

Affected Silicon Revisions

29. Module: CAN

When an abort request occurs concurrently with a

successful message transmission, and additional

messages remain in the FIFO, these remaining

messages are not transmitted and the TXABAT bit

does not reflect the abort.

Work around

The actual FIFO status can be determined by the

FIFO pointers CFIFOCI and CFIFOUA.

Affected Silicon Revisions

30. Module: UART

The UART module is not fully IrDA® compliant.

The module does not detect the 1.6 µs minimum

bit width at all baud rates as defined in the IrDA

specification. The module does detect the 3/16 bit

width at all baud rates.

Work around

None.

Affected Silicon Revisions

31. Module: UART

In IrDA mode with baud clock output enabled, the

UART TX data is corrupted when the BRG value is

greater than 0x200.

Work around

Use the Peripheral Bus (PB) divisor to lower the

PB frequency such that the required UART BRG

value is less than 0x201.

Affected Silicon Revisions

32. Module: JTAG

On 64-pin devices an external pull-up resistor is

required on the TMS pin for proper JTAG.

Work around

Connect a 100k-200k pull-up to the TMS pin.

Affected Silicon Revisions

33. Module: UART

The TRMT bit is asserted during the STOP bit

generation, not after the STOP bit has been sent.

Work around

If firmware needs to be aware when the transmis-

sion is complete, firmware should add a half bit

time delay after the TRMT bit is asserted.

Affected Silicon Revisions

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

PIC32MX575/675/695/775/795

34. Module: UART

The OERR bit does not get cleared on a module

Reset. If the OERR bit is set and the module is dis-

abled, the OERR bit retains its status even after

the UART module is reinitialized.

Work around

The user software must check this bit in the UART

module initialization routine and clear it if it is set.

Affected Silicon Revisions

35. Module: ADC

When the ADC module is configured to start con-

version on an external interrupt (SSRC<2:0> =

001), the start of conversion always occurs on a

rising edge detected at the INT0 pin, even when

the INT0 pin has been configured to generate an

interrupt on a falling edge (INT0EP = 0).

Work around

Generate ADC conversion triggers on the rising

edge of the INT0 signal.

Alternatively, use external circuitry to invert the sig-

nal appearing at the INT0 pin, so that a falling edge

of the input signal is detected as a rising edge by

the INT0 pin.

Affected Silicon Revisions

36. Module: JTAG

Pin 100 on 100-pin packages and pin A1 on

121-pin packages do not respond to boundary

scan commands.

Work around

None.

Affected Silicon Revisions

37. Module: DMA

If the DMA module is suspended by setting the

DMA Suspend bit (SUSPEND) in the DMA

Controller Control register (DMACON), the DMA

Module Busy Bit (DMABUSY) in the DMACON

the DMA module completes transaction.

Work around

Use the Channel Busy bit (CHBUSY) in the DMA

Channel Control Register (DCHxCON) to check

the status of the DMA channel.

Affected Silicon Revisions

38. Module: Voltage Regulator

Device may not exit BOR state if BOR event

occurs.

Work arounds

Work around 1:

VDD must remain within the published specification

(see parameter DC10 of the device data sheet).

Work around 2:

Reset device by providing POR condition.

Affected Silicon Revisions

39. Module: Output Compare

If the Output Compare module is configured for a

0% duty cycle (OCxRS = 0), a glitch may occur on

the next cycle.

Work around

The Output Compare module should be disabled

and then re-enabled to achieve a 0% duty cycle.

Affected Silicon Revisions

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

A0 A1 A3

XXX

PIC32MX575/675/695/775/795

40. Module: Oscillator

If the Primary Oscillator (POSC) mode is

implemented and a Fail-Safe Clock Monitor

(FSCM) event occurs (failure of the external

primary clock), the internal clock source will switch

to the FRC oscillator. Subsequent firmware clock

switch requests from the FRC oscillator to other

clock sources will fail and the device will continue

to execute on the FRC oscillator. Upon repair of

the external clock source and a power-on state,

the device will resume operation with the primary

oscillator clock source.

Work around

None.

Affected Silicon Revisions

41. Module: I2C

The slave address, 0x78, is one of a group of

reserved addresses. It is used as the upper byte of

a 10-bit address when 10-bit addressing is

enabled. The I2C module control register allows

the programmer to enable both 10-bit addressing

and strict enforcement of reserved addressing,

with the A10M and STRICT bits, respectively.

When both bits are cleared, the device should

respond to the reserved address 0x78, but does

not.

Work around

None.

Affected Silicon Revisions

42. Module: USB

In the case where the bus has been idle for > 3 ms,

and the UIDLE interrupt flag is set, if software

clears the interrupt flag, and the bus remains idle,

the UIDLE interrupt flag will not be set again.

Work around

Software can leave the UIDLE bit set until it has

received some indication of bus resumption.

(Resume, Reset, SOF, or Error).

Affected Silicon Revisions

A0 A1 A3

XXX

A0 A1 A3

XXX

Note: Resume and Reset are the only interrupts

that should be gotten following UIDLE

assertion. If, at any point in time, the

UIDLE bit is set, it should be okay to sus-

pend the USB module (as long as this

code is protected by the GUARD and/or

ACTPEND logic). Note that this will

require software to clear the UIDLE inter-

rupt enable bit to exit the USB ISR (if

using interrupt driven code).

A0 A1 A3

XXX

PIC32MX575/675/695/775/795

Data Sheet Clarifications

The following typographic corrections and clarifications

are to be noted for the latest version of the device data

sheet (DS61156G):

1. Module: Pin Diagrams

In all pin diagrams in the current revision of the

data sheet, the D- and D+ pins are incorrectly

indicated as 5V-tolerant pins through the use of

shading. The D- and D+ pins are not 5V-tolerant

pins and should not be shaded in the pin diagrams.

2. Module: AC Characteristics: Standard

Operating Conditions

The Standard Operating conditions in the following

table shows the incorrect starting voltage range of

2.3V. The correct starting range is: 2.9V:

• Table 31-35: Ethernet Module Specifications

The Standard Operating conditions in the following

tables show the incorrect starting voltage range of

2.3V. The correct starting range is: 2.5V:

• Table 31-36: ADC Module Specifications

• Table 31-37: 10-bit ADC Conversion Rate

Parameters

• Table 31-38: Analog-to-Digital Conversion

Timing Requirements

Note: Corrections are shown in bold. Where

possible, the original bold text formatting

has been removed for clarity.

PIC32MX575/675/695/775/795

APPENDIX A: REVISION HISTORY

Rev A Document (8/2009)

Initial release of this document; issued for revision A0

silicon.

Includes silicon issues 1 (I2C™), 2 (Ethernet), 3 (ADC),

4 (Parallel Master Port), 5 (Output Compare), 6 (SPI)

and 7 (UART).

Rev B Document (11/2009)

Added silicon issues 8 (USB), 9-10 (Output Compare),

11 (DMA), 12 (Timers), 13 (SPI), 14-17 (CAN), 18 (Out-

put Compare), 19 (SPI), 20-21 (USB), 22 (WDT), 23

(Oscillator) and 24 (Oscillator).

Rev C Document (9/2010)

The document title was changed to PIC32MX575/675/

/695/775/795 Family Silicon Errata and Data Sheet

Clarification.

Added devices to Table 1: Silicon DEVREV Values.

Modified silicon issue 1 (I2C™).

Added silicon issues 25 (SPI), 26 (PORTS), 27-28 (SPI),

29 (CAN), 30-31 (UART), 32 (JTAG), 33 (UART) and 34

(UART), and added data sheet clarification issue 1 (Pin

Diagrams).

Rev D Document (11/2010)

Removed data sheet clarification 1.

Added silicon issues 35 (ADC), 36 (JTAG) and 37

(DMA).

Rev E Document (12/2010)

Added silicon issue 38 (Voltage Regulator).

Rev F Document (3/2011)

Updated the current silicon revision to A1 throughout

the document. Added silicon issue 39 (Output

Compare) and data sheet clarification 1 (Pin

Diagrams).

Rev G Document (10/2011)

Updated issue 19 (SPI).

Added silicon issues 40 (Oscillator), 41 (I2C), and

42 (USB).

Added data sheet clarification 2 (AC Characteristics:

Standard Operating Conditions).

Rev H Document (10/2011)

Updated the current silicon revision to A3 throughout

the document.

Information contained in this publication regarding device

applications and the like is provided only for your convenience

and may be superseded by updates. It is your responsibility to

ensure that your application meets with your specifications.

MICROCHIP MAKES NO REPRESENTATIONS OR

WARRANTIES OF ANY KIND WHETHER EXPRESS OR

IMPLIED, WRITTEN OR ORAL, STATUTORY OR

OTHERWISE, RELATED TO THE INFORMATION,

INCLUDING BUT NOT LIMITED TO ITS CONDITION,

QUALITY, PERFORMANCE, MERCHANTABILITY OR

FITNESS FOR PURPOSE. Microchip disclaims all liability

arising from this information and its use. Use of Microchip

devices in life support and/or safety applications is entirely at

the buyer’s risk, and the buyer agrees to defend, indemnify and

hold harmless Microchip from any and all damages, claims,

suits, or expenses resulting from such use. No licenses are

conveyed, implicitly or otherwise, under any Microchip

intellectual property rights.

Trademarks

The Microchip name and logo, the Microchip logo, dsPIC,

KEELOQ, KEELOQ logo, MPLAB, PIC, PICmicro, PICSTART,

PIC32 logo, rfPIC and UNI/O are registered trademarks of

Microchip Technology Incorporated in the U.S.A. and other

countries.

FilterLab, Hampshire, HI-TECH C, Linear Active Thermistor,

MXDEV, MXLAB, SEEVAL and The Embedded Control

Solutions Company are registered trademarks of Microchip

Technology Incorporated in the U.S.A.

Analog-for-the-Digital Age, Application Maestro, chipKIT,

chipKIT logo, CodeGuard, dsPICDEM, dsPICDEM.net,

dsPICworks, dsSPEAK, ECAN, ECONOMONITOR,

FanSense, HI-TIDE, In-Circuit Serial Programming, ICSP,

Mindi, MiWi, MPASM, MPLAB Certified logo, MPLIB,

MPLINK, mTouch, Omniscient Code Generation, PICC,

PICC-18, PICDEM, PICDEM.net, PICkit, PICtail, REAL ICE,

rfLAB, Select Mode, Total Endurance, TSHARC,

UniWinDriver, WiperLock and ZENA are trademarks of

Microchip Technology Incorporated in the U.S.A. and other

countries.

SQTP is a service mark of Microchip Technology Incorporated

in the U.S.A.

All other trademarks mentioned herein are property of their

respective companies.

Printed on recycled paper.

ISBN: 978-1-61341-728-7

Note the following details of the code protection feature on Microchip devices:

• Microchip products meet the specification contained in their particular Microchip Data Sheet.

• Microchip believes that its family of products is one of the most secure families of its kind on the market today, when used in the

intended manner and under normal conditions.

• There are dishonest and possibly illegal methods used to breach the code protection feature. All of these methods, to our

knowledge, require using the Microchip products in a manner outside the operating specifications contained in Microchip’s Data

Sheets. Most likely, the person doing so is engaged in theft of intellectual property.

• Microchip is willing to work with the customer who is concerned about the integrity of their code.

• Neither Microchip nor any other semiconductor manufacturer can guarantee the security of their code. Code protection does not

mean that we are guaranteeing the product as “unbreakable.”

Code protection is constantly evolving. We at Microchip are committed to continuously improving the code protection features of our

products. Attempts to break Microchip’s code protection feature may be a violation of the Digital Millennium Copyright Act. If such acts

allow unauthorized access to your software or other copyrighted work, you may have a right to sue for relief under that Act.

Microchip received ISO/TS-16949:2009 certification for its worldwide

headquarters, design and wafer fabrication facilities in Chandler and

Tempe, Arizona; Gresham, Oregon and design centers in California

and India. The Company’s quality system processes and procedures

are for its PIC® MCUs and dsPIC® DSCs, KEELOQ® code hopping

devices, Serial EEPROMs, microperipherals, nonvolatile memory and

analog products. In addition, Microchip’s quality system for the design

and manufacture of development systems is ISO 9001:2000 certified.

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08/02/11