Uno32 Reference Manual


The Uno32 is retired and no longer for sale in our store.

The Uno32 is based on the popular Arduino™ open-source hardware prototyping platform and adds the performance of the Microchip PIC32 microcontroller. The Uno32 is the same form factor as the Arduino Uno board and is compatible with Arduino shields. It features a USB serial port interface for connection to the IDE and can be powered via USB or an external power supply. The Uno32 board takes advantage of the powerful PIC32MX320F128 microcontroller. This microcontroller features a 32-bit MIPS processor core running at 80Mhz, 128K of flash program memory and 16K of SRAM data memory.

The Uno32 can be programmed using the Multi-Platform Integrated Development Environment (MPIDE), an environment based on the original Arduino IDE modified to support PIC32. It contains everything needed to start developing embedded applications. In addition, the Uno32 is fully compatible with the advanced Microchip MPLAB® IDE and the PICKit3 in-system programmer/debugger.

The Uno32 is easy to use and suitable for both beginners and advanced users experimenting with electronics and embedded control systems. The Uno32 provides 42 I/O pins that support a number of peripheral functions, such as UART, SPI, and I2C ports and pulse width modulated outputs. Twelve of the I/O pins can be used as analog inputs or as digital inputs and outputs.


  • Microchip® PIC32MX320F128H microcontroller (80 Mhz 32-bit MIPS, 128K Flash, 16K SRAM)
  • compatible with many existing Arduino code samples and other resources
  • Arduino Uno form factor
  • compatible with many Arduino shields
  • 42 available I/O pins
  • two user LEDs
  • PC connection uses a USB A > mini B cable (not included)
  • 12 analog inputs
  • 3.3V operating voltage
  • 80Mhz operating frequency
  • 75mA typical operating current
  • 7V to 15V input voltage (recommended)
  • 20V input voltage (maximum)
  • 0V to 3.3V analog input voltage range
  • +/-18mA DC current per pin

Uno32 Hardware Overview

The Uno32 board has the following hardware features:

1. USB Connector for USB Serial Converter

This connects to a USB port on the PC to provide the communications port for the MPIDE to talk to the Uno32 board. This can also be used to power the Uno32 board when connected to the PC.

2. JP3 – Microchip Debug Tool Connector

This connector is used to connect Microchip programmer/debugger tools, such as the PICkit™3. This allows the Uno32 board to be used as a traditional microcontroller development board using the Microchip MPLAB® IDE.

3. J4 – External Power Connector

This is a 5.5mm x 2.1mm barrel connector used to power the Uno32 board from an external power supply. It is wired with the center terminal as the positive supply voltage. The power supply voltage must be in the range 7V to 15V.

4. Power Supply – 3.3V Regulator

Voltage regulator for the 3.3V power supply. This power supply can provide up to 500mA of current.

5. JP2 – Power Select Jumper

This jumper is used to route power from the external power connector through the on-board 5V voltage regulator or to bypass the 5V regulator. The REG position routes power through the 5V regulator. The BYP position bypasses the on-board 5V regulator. With this jumper in the BYP position the maximum input voltage that can be applied at the external power connector is 6V.

6. Power Supply – 5V Regulator

This on-board 5V voltage regulator regulates the input voltage applied at the external power connector to 5V. This is used to power the 3.3V regulator and to provide 5V power to expansion shields. This regulator can provide up to 800mA of current.

7. J2 – Shield Power Connector

This connector provides power to I/O expansion shields connected to the board.

8. PIC32 Microcontroller

The PIC32MX320F128H microcontroller is the main processor for the board.

9. J7 – Analog Signal Connector

This connector provides access to analog/digital I/O pins on the microcontroller.

10. JP6/JP7 – A4/A5 Signal Select Jumpers

These jumpers are used to switch pins 9 and 11 on connector J7 between analog inputs A4 and A5 or the I²C signals SDA and SCL.

11. J8 – SPI Signal Connector

This connector provides alternative access to the SPI signals. This is used by some shields for access to the SPI bus.

12. JP5/JP7 – SPI Master/Slave Select Jumpers

These jumpers are used to switch the SPI signals for use of the Uno32 board as an SPI master device or as an SPI slave device. Both jumpers should be switched together. Place the shorting blocks in the MASTER position for master operation and in the SLAVE position for slave operation. Normally, these jumpers are in the MASTER position.

13. User LEDs

Two LEDs connected to digital signal pins 13 and 43.

14. J6 – Digital Signal Connector

This connector provides access to digital I/O pins on the microcontroller.

15. JP4 – Pin 10 Signal Select Jumprt

This jumper is used to switch connector J5 pin 5 (digital signal 10) between pulse width modulator (PWM) operation and SPI operation. The jumper is placed in the RD4 position for PWM output and in the RG9 position for SPI slave operation. The shorting block on this jumper will normally be in the RD4 position. The only time it normally needs to be in the RG9 is when using the Uno32 board as an SPI slave device.

16. J5 – Digital Signal Connector

This connector provides access to digital I/O pins on the microcontroller.

17. J11 - I²C

Dedicated I²C signals. These pins are independent of the setting of jumpers JP6 and JP8. However, if JP6 and JP8 are in the RG3 and RG2 positions, the I²C signals will be tied to pins A4 and A5 on J7.

18. Communications Status LEDs

These LEDs indicate activity on the USB serial interface.

19. Reset Button

This button can be used to reset the microcontroller, restarting operation from the boot loader.

Jumper Settings

The development platforms use a Microchip PIC32 microcontroller. These are 32-bit products that bring unprecedented features to the Arduino community. In order to maintain compatibility with existing hardware and software, additional jumpers and row headers are provided.

Used in conjunction with an external DC power supply of 7V-15V connected to J4. Placing the shorting block in the REG position will force the input voltage from the power connector J4 to pass through the 5V voltage regulator IC2. This regulated 5V output is then tied to the VCC5V0 bus. It is also used to power the 3.3V regulator IC3. The VIN bus will have the same potential as the external power supply. This should also be the default position if you are unsure.

Placing the shorting block in the BYP position bypasses the 5V regulator IC2 and ties directly to the VCC5V0 bus and also powers the 3.3V regulator IC3. It is not recommended to connect more than 6V external power through the power connector J4 when JP1 is in the BYP position.

When powering the board from only the USB, placing the shorting block in the REG position will disconnect the VIN bus. Placing the shorting block in the BYP position will tie the VIN bus to the VCC5V0 and USB5V0 busses. Power limitations on the USB5V0 bus will apply the VIN bus in this case.

The Uno32 can be connected to both a 5V USB power source and an external power source of 7V or more at the same time. Place the shorting block in the REG position in this case.

For more information on power supplies, see section 5 Power Supply below.


Configures digital pin 10 on J5 to be used as either a PWM output or a Slave Select input for use as an SPI slave device. Moving the jumper block to the RD4 position sets pin 10 as PWM and is the normal operating position. Moving the jumper block to the RG9 position allows the Uno32 to operate as a slave device according to standard SPI protocol.

JP5 & JP7
Used in conjunction with SPI connector J8. The Uno32 can be configured as either a Master device or Slave device according to standard SPI protocol. Both shorting blocks should be moved together when switching between Master and Slave. Data flow will also swap depending on the position of the shorting blocks.

JP6 & JP8
Used to configure pins A4 and A5 on J7. These can be set as either analog pins or as I²C communication pins. With the jumper blocks in the A4/A5 position, pins A4 and A5 are analog pins. With the jumper blocks in the RG3/RG2 position, JP6 is tied to the SDA signal and JP8 is tied to the SCL signal.

Uno32 Hardware Description

MPIDE and USB Serial Communications

The Uno32 board is designed to be used with the Multi-Platform IDE (MPIDE). Digilent produced the MPIDE development platform by modifying the Arduino™ IDE. It is backwards-compatible with the Arduino IDE.

The MPIDE uses a serial communications port to communicate with a boot loader running on the Uno32 board. The serial port on the Uno32 board is implemented using an FTDI FT232R USB serial converter. Before attempting to use the MPIDE to communicate with the Uno32, the appropriate USB device driver must be installed.

The Uno32 board uses a standard mini-USB connector for connection to a USB port on the PC.

When the MPIDE needs to communicate with the Uno32 board, the board is reset and starts running the boot loader. The MPIDE then establishes communications with the boot loader and downloads the program to the board.

When the MPIDE opens the serial communications connection on the PC, the DTR pin on the FT232R chip is driven low. This pin is coupled through a capacitor to the MCLR pin on the PIC32 microcontroller. Driving the MCLR line low resets the microcontroller, restarting execution with the boot loader.

This automatic reset action (when the serial communications connection is opened) can be disabled. To disable this operation, there is a cut-able trace on the bottom of the board between the pins on JP1. JP1 is normally not loaded. If the trace between the pins on JP1 has been cut, the automatic reset operation can be restored by loading JP1 and inserting a shorting block across it.

Two red LEDs (LD1 and LD2) will blink when data is being sent or received between the Uno32 and the PC over the serial connection.

The header connector J3 provides access to the other serial handshaking signals provided by the FT232R. Connector J3 is not loaded at the factory and can be installed by the user to access these signals.

Power Supply

The Uno32 is designed to be powered either via USB or from an external power supply. There is an automatic switch-over circuit that causes the external supply to be used if both supplies are present.

The power supply section in the Uno32 uses two voltage regulators. The first regulates the external voltage to 5V to power the VCC5V0 bus. The second regulates the VCC5V0 bus to 3.3V to provide power to the VCC3V3 bus that powers the PIC32 microcontroller.

The 5V voltage regulator is normally an NCP1117. The board is designed to be able to also use an LM1117, but the NCP1117 is the part normally used. The NCP1117 is rated for an output current of 1A (the LM1117 is rated for 800mA). The dropout voltage of the NCP1117 is a maximum of 1.2V at the rated output current (1.3V for the LM1117).

There is a reverse polarity protection diode in the external power supply circuit. Considering the diode drop plus the forward drop across the regulator, the minimum input voltage to the regulator should be 7V to produce a reliable 5V output. The absolute maximum input voltage of both the NCP1117 and the LM1117 is 20V. The recommended maximum operating voltage is 15V.

For input voltages above 9V, the regulator will get extremely hot when drawing high currents. Both the NCP1117 and the LM1117 have output short circuit protection and internal thermal protection and will shut down automatically to prevent damage.

The 3.3V regulator is a Microchip MCP1725. This regulator is rated for a maximum output current of 500mA. The absolute maximum input voltage for the MCP1725 is 6V. This regulator has internal short circuit protection and thermal protection. It will get noticeably warm when the current consumed by the VCC3V3 bus is close to the 500mA maximum.

The 5V power bus, VCC5V0 can be powered from one of three sources:

  • the USB5V0 bus when the board is operating under USB power,
  • the output of the on-board 5V regulator when operating from an external 7V-15V supply,
  • directly from the external supply when operating from a regulated 5V external supply with jumper JP2 in the BYP position.

Switch-over from USB power to external power is done automatically and the external supply will be used if both are present.

Jumper JP2 is used to route the external power supply voltage through the on-board 5V regulator or directly to the VCC5V0 bus, bypassing the on-board 5V regulator. Normally, JP2 is in the REG position. This routes the external supply through the 5V regulator. Operation from an externally regulated 5V supply is provided by placing the jumper in the BYP position.

The forward drop across the MCP1725 is typically 210mV (350mV max) at 500mA output. With JP2 in the BYP position, this will allow correct operation of the 3.3V power supply from an input voltage down to 3.5V. This lets you power the board from batteries and other lower voltage power sources. In that case, the VCC5V0 power bus will not be powered at 5V.

Note: When JP2 is in the BYP position, do not apply more than 6V to the external power input. This can destroy the 3.3V regulator and possibly the PIC32 microcontroller as well.

The PIC32 microcontroller is rated to use a maximum of 75mA of current when operating at 80Mhz. This allows up to 425mA from the VCC3V3 bus and up to 925mA from the VCC5V0 bus to power external devices.

The POWER connector, J2, is used to power shields connected to the Uno32 board. The following pins are provided on this connector:

P32_RST (pin 1): This connects to the MCLR pin on the PIC32 microcontroller and can be used to reset the PIC32.

VCC3V3 (pin 2): This routes the 3.3V power bus to shields. This pin can provide ~425mA.

VCC5V0 (pin 3): This routes the 5V power bus to shields. This pin can provide up to ~900mA to shields, however the total provided by pins 2 and 3 shouldn’t exceed 925mA.

GND (pin 4, 5): This provides a common ground connection between the Uno32 and the shields.

VIN (pin 6): This connects to the voltage provided at the external power supply connector. This can be used to provide unregulated input power to the shield. It can also be used to power the Uno32 board from the shield instead of from the external power connector.

5V Compatibility

The PIC32 microcontroller operates at 3.3V. The original Arduino boards operate at 5V as do many Arduino shields.

There are two issues to consider when dealing with 5V compatibility for 3.3V logic. The first is protection of 3.3V inputs from damage caused by 5V signals. The second is whether the 3.3V output is high enough to be recognized as a logic high value by a 5V input.

The digital I/O pins on the PIC32 microcontroller are 5V tolerant. The analog capable I/O pins are not 5V tolerant. To provide 5V tolerance on those pins, the Uno32 contains clamp diodes and current limiting resistors to protect them from 5V input voltages.

The fact that all I/O pins are 5V tolerant means that it is safe to apply 5V logic levels to any pins on the board without risk of damaging the PIC32 microcontroller.

The minimum high-voltage output of the PIC32 microcontroller is rated at 2.4V when sourcing 12mA of current. When driving a high impedance input (typical of CMOS logic) the output high voltage will be close to 3.3V. Some 5V devices will recognize this voltage as a logic high input, and some won't. Many 5V logic devices will work reliably with 3.3V inputs.

Input/Output Connections

The Uno32 board provides 42 of the I/O pins from the PIC32 microcontroller to pins on the input/output connectors J5, J6, and J7.

The PIC32 microcontroller can source or sink a maximum of 18mA on all digital I/O pins. However, to keep the output voltage within the specified voltage range (VOL 0.4V, VOH 2.4V) the pin current must be restricted to +7/-12mA. The maximum current that can be sourced or sunk across all I/O pins simultaneously is +/-200mA. The maximum voltage that can be applied to any I/O pin is 5.5V. For more detailed specifications, refer to the PIC32MX3XX/4XX Data Sheet available from the Microchip web site.

Connectors J5 and J6 are 2×8 female pin header connectors that provide digital I/O signals. The outer row of pins (closer to the board edge) corresponds to the I/O connector pins on an Arduino Uno or Duemilanove board. The inner row of pins provides access to the extra I/O signals provided by the PIC32 microcontroller.

Connector J7 is a 2×6 female pin header connector that provides access to the analog input pins on the microcontroller. The outer row of pins corresponds to the six analog pins on an Arduino Uno or Duemilanove. The inner row of pins are the additional I/O signals provided by the PIC32 microcontroller. The analog pins on J7 can also be used as digital I/O pins.

The microcontroller/Arduino system uses logical pin numbers to identify digital I/O pins on the connectors. The logical pin numbers for the I/O pins on the Uno32 are 0-43. These pin numbers are labeled in the silk screen on the board.

Pin numbers 0-13 are the outer row of pins on J6 and J5, from right to left. Pin numbers 14-19 are the outer row of pins on J7 from left to right. Pins 20-25 are the inner row of pins on J7 from left to right. Pin numbers 26-41 are the inner row of pins on J6 and J5 from right to left. Pin 42 is the pin labeled A on J5. This pin is normally the reference voltage for the microcontroller’s A/D converter, but can also be used as a digital I/O pin.

In addition to the connector pin, Pin 13 also connects to the user LED LD4. Pin 43 connects to user LED LD5. Pin 43 pin does not go to any connector.

The analog inputs on connector J7 are assigned pin numbers. The outer row of pins on J7 are analog inputs A0-A5. The inner row of pins are A6-A11. These pins are also assigned digital pin numbers: A0-A5 are digital pins 14-19, and A6-A11 are 20-25.

Peripheral I/O Functions

The PIC32 microcontroller on the Uno32 board provides a number of peripheral functions. The following peripherals are provided:

UART port 1: Asynchronous serial port. Pin 0 (RX), Pin 1 (TX). These pins are connected to I/O connector J6 and are also connected to the FT232R USB serial converter. It is possible to use these pins to connect to an external serial device when not using the USB serial interface. This uses UART1 (U1RX, U1TX) on the PIC32 microcontroller.

UART port 2: Asynchronous serial port. Pin 39 (RX), Pin 40 (TX). This uses UART2 (U2RX, U2TX) on the PIC32 microcontroller.

SPI: Synchronous serial port. Pin 10 (SS), Pin 11 (MOSI), Pin 12 (MISO), Pin 13 (SCK). This uses SPI2 (SS2, SDI2, SDO2, SCK2) on the PIC32 microcontroller These signals also appear on connector J8. Jumpers JP5 and JP7 are used to select whether the Uno32 operates as a Master (transmit on MOSI, receive on MISO) or a Slave (transmit on MISO, receive on MOSI) device. The shorting blocks on JP5 and JP7 are normally placed in the Master position for the Uno32 to function as an SPI master. Jumper JP4 is used to select PWM output or the SPI SS function on Pin 10. The shorting block on JP4 should be in the RD4 position to select PWM output. It should be in the RG9 position to select the SPI SS function.. JP4 will normally be in the RD4 position. In general, the only time it needs to be in the RG9 position is when the Uno32 board is being used as an SPI slave device.

I^2C: Synchronous serial interface. The PIC32 microcontroller shares analog pins A4 and A5 with the two I2C signals SDA and SCL. Jumpers JP6 and JP8 are used to select whether the analog pin functions or the I2C pin functions are being used. The shorting blocks are placed in the A4/A5 position to select the analog input function or general digital I/O. They are placed in the RG3/RG2 position to use the pins for I2C operation. This uses I2C1 (SDA1, SCL1) on the PIC32 microcontroller.

Note: The I2C bus uses open collector drivers to allow multiple devices to drive the bus signals. This means that pull-up resistors must be provided to supply the logic high state for the signals. These pull-up resistors are not on the Uno32 board and must be provided externally. The required resistance of the pull-up resistor to use depends on the total number of devices on the bus, the length of wire, and the clock speed being used. It essentially depends on distributed capacitance on the bus. The higher the distributed capacitance and the faster the clock speed, the smaller the resistance should be. Values typically used are in the range of 2K to 10K ohms.

PWM: Pulse width modulated output. Pins 3 (OC1), 5 (OC2), 6 (OC3), 9 (OC4), and 10 (OC5).

External Interrupts: Pin 38 (INT0), Pin 2 (INT1), Pin 7 (INT2), Pin 8 (INT3), Pin 35 (INT4)

User LEDs: Pin 13 (LD4), Pin 43 (LD5). Pin 13 is shared between a connector pin and the LED. Pin 43 only goes to the LED and not any connector pin. Driving the pin high turns the LED on, driving it low turns it off.

A/D Converter Reference: Labeled A, the left-most outer pin on connector J5. This is used to provide an external voltage reference to determine the input voltage range of the analog pins. The maximum voltage that can be applied to this pin is 3.3V. This pin can also be used as digital pin 42.

RTCC: Real Time Clock Calendar. The PIC32 microcontroller contains an RTCC circuit that can be used to maintain time and date information. The operation of the RTCC requires a 32.768Khz frequency source. Crystal X2 (not loaded), just above and to the right of the PIC32 microcontroller IC, is provided for you to solder a 32Khz watch crystal. The Citizen CFS206-32.768KDZF-UB crystal can be used in this location.

RESET: The PIC32 microcontroller is reset by bringing its MCLR pin low. The MCLR pin is connected to the P32_RST net on the circuit board.

As described earlier, reset of the PIC32 microcontroller can be initiated by the USB serial converter. The USB serial converter brings the DTR pin low to reset the microcontroller. Jumper JP1 can be used to enable/disable the ability for the USB serial converter to initiate a reset.

The P32_RST net is connected to pin 1 of connector J2. This allows circuitry on a shield to reset the microcontroller, or to ensure that the circuitry on the shield is reset at the same time as the microcontroller.

Connector J8 provides access to the SPI bus. Pin 5 provides access to the SPI Slave Select signal (SS).

On Arduino boards, the corresponding connector is also used as an in-system programming connector as well as providing access to some of the SPI signals. On Arduino boards, pin 5 of this connector is connected to the reset net.

Some Arduino shields, e.g. the Ethernet shield, connect pin 5 to the reset net on pin 1 of connector J2. This causes the processor to be reset each time an attempt is made to access the SPI port. Jumper JP9 can be used to break the connection between J8 pin 5 and reset when using Arduino shields that make this connection. JP9 has a cut-able trace on the bottom of the board that can be cut to break the connection between SPI SS and reset. JP9 is not loaded at the factory. To restore the connection, solder a two pin header at the JP9 position and install a shorting block.

A reset button is at the upper left corner of the board. Pressing this button resets the PIC32 microcontroller.

Microchip Development Tool Compatibility

In addition to being used with the MPIDE, the Uno32 board can be used as a more traditional microcontroller development board using Microchip Development Tools.

Unloaded connector JP3 on the left side of the board is used to connect to a Microchip development tool, such as the PICkit3™. The holes for JP3 are staggered so that a standard 100-mil spaced 6-pin header can be press fit to the board without the need to solder it in place. Any Microchip development tool that supports the PIC32 microcontroller family, and can be connected via the same 6-pin interface as the PICkit3, can be used.

Typically, a right-angle male connector is used in JP3 so that a PICkit3 can be attached coplanar with the Uno32 board. The connector can be loaded from the top, or it can be loaded from the bottom. In either case the PICkit3 will be upright (button and LEDs visible).

If JP3 is loaded from the top, the PICkit3 will interfere with the USB connector and the external power connector. A short six-wire cable can be used between the PICkit3 and the Uno32. If JP3 is loaded from the bottom, the PICkit3 won’t interfere with the USB and external power connectors.

The Digilent PICkit3 Programming Cable Kit includes all necessary connectors and a cable for connecting a PICkit3 to the Uno32.

The Microchip MPLAB® IDE or the MPLAB® X IDE can be used to program and debug code running on the Uno32 board. These programs can be downloaded from the Microchip web site.

Reloading the MPIDE bootloader

Using the Microchip development tools to program the Uno32 board will cause the boot loader to be erased. To use the board with the MPIDE again, it is necessary to program the boot loader back onto the board. The boot loader source code and compiled image can be found in the MPIDE software download.

Pinout Tables

The following tables give the relationship between the digital pin numbers, the connector pin numbers and the microcontroller pin numbers.

In the following tables, columns labeled pin # refer to the digital pin number. This is the value that is passed to the pinMode(), digitalRead(), digitalWrite() and other functions to refer to the pin.

For most pins, this pin number will agree with the pin number labeled on the board. For the pins whose function can be switched using jumpers, the pin number labeled on the board is correct when the jumper is in the 'normal' position.

For example: The normal position for JP4 is the RD4 position. The digital pin number for the microcontroller signal RD4 is 10. With JP4 in the RD4 position, digital pin 10 is connected to the pin labeled 10 on the board. The alternate position for JP4 is the RG9 position. The digital pin number for the microcontroller signal RG9 is 44. With JP4 in the RG9 position, digital pin 44 is connected to the pin labeled 10 on the board, and digital pin 10 is not connected.

The pin labeled 10 on the board is connected to connector J5 pin 5. This is shown as J5-05 in the following tables. In the 'Pinout Table by Shield Connector Pin' table below, J5-05 is shown has being either pin # 10 or 44. J5-04 is connected to pin # 10 when JP4 is in the RD4 position and is connected to pin # 44 when in the RG9 position.

Pinout Table by Logical Pin Number

Pin # Connector Pin # PIC32 Pin # PIC32 Signal Notes
0 J6-01 34 U1RX/SDI1/RF2
1 J6-03 33 U1TX/SDO1/RF3
2 J6-05 42 IC1/RTCC/INT1/RD8
3 J6-07 46 OC1/RD0
4 J6-09 59 RF1
5 J6-11 49 OC2/RD1
6 J6-13 50 OC3/RD2
7 J6-15 43 IC2/U1CTS/INT2/RD9
8 J5-01 44 IC3/PMCS2/PMA15/INT3/RD10
9 J5-03 51 OC4/RD3
10 J5-05 52 PMWR/OC5/IC5/CN13/RD4 Selected by JP4, also on J8-6
11 J5-07 6 SDO2/PMA3/CN10/RG8 Selected by JP5, also on J8-1
12 J5-09 5 SDI2/PMA5/CN8/RG7 Selected by JP7, also on J8-4
13 J5-11 4 SCK2/PMA5/CN8/RG6 Also on J8-3, User LED LD4
14/A0 J7-01 14 C2IN-/AN2/SS1/CN4/RB2
15/A1 J7-03 12 C1IN-/AN4/CN6/RB4
16/A2 J7-05 21 U2CTS/C1OUT/AN8/RB8
17/A3 J7-07 23 TMS/CVREFOUT/PMA13/AN10/RB10
18/A4 J7-09 27 TCK/PMA11/AN12/RB12 Selected by JP6
19/A5 J7-11 29 PMALH/PMA1/U2RTS/AN14/RB14 Selected by JP8
20/A6 J7-02 13 C2IN+/AN3/CN5/RB3
21/A7 J7-03 11 C1IN+/AN5/CN7/RB5
22/A8 J7-06 22 PMA7/C2OUT/AN9/RB9
23/A9 J7-08 24 TDO/PMA12/AN11/RB11
24/A10 J7-10 28 TDI/PMA10/AN13/RB13
25/A11 J7-12 30 PMALL/PMA0/AN15/OCFB/CN12/RB15
26 J6-02 60 PMD0/RE0
27 J6-04 61 PMD1/RE1
28 J6-06 62 PMD2/RE2
29 J6-08 63 PMD3/RE3
30 J6-10 64 PMD4/RE4
31 J6-12 1 PMD5/RE5
32 J6-14 2 PMD6/RE6
33 J6-16 3 PMD7/RE7
34 J5-02 53 PMRD/CN14/RD5
35 J5-04 45 IC4/PMCS1/PMA14/INT4/RD11
36 J5-06 54 CN15/RD6
37 J5-08 55 CN16/RD7
38 J5-10 35 U1RTS/BCLK1/SCK1/INT0/RF6
39 J5-12 31 PMA9/U2RX/SDA2/CN17/RF4
40 J5-14 32 PMA8/U2TX/SCL2/CN18/RF5
41 J5-16 15 PGC1/AN1/VREF-/CVREF-/CN3/RB1
42 J5-15 16 PGED1/PMA6/AN0/VREF+/CVREF+/CN2/RB0
43 N/A 58 RF0 User LED LD5
44 J5-05 8 PMA2/SS2/CN11/RG9 Selected by JP4, also on J8-6
45 J11-1, J7-09 36 SDA1/RG3 J7-09 selected by JP6
46 J11-2, J7-11 37 SCL1/RG2 J7-11 selected by JP8

Pinout Table By Shield Connector Pin

Connector Pin # Pin # PIC32 Pin # PIC32 Signal Notes
J5-01 8 44 IC3/PMCS2/PMA15/INT3/RD10
J5-02 34 53 PMRD/CN14/RD5
J5-03 9 51 OC4/RD3
J5-04 35 45 IC4/PMCS1/PMA14/INT4/RD11
J5-05 10 or 44 52 or 8 PMWR/OC5/IC5/CN13/RD4 or SS2/PMA2/CN11/RG9 Selected by JP4, also on J8-6
J5-06 36 54 CN15/RD6
J5-07 11 or 12 6 or 5 SDO2/PMA3/CN10/RG8 or SDI2/PMA5/CN8/RG7 Selected by JP5, also on J8-1
J5-08 37 55 CN16/RD7
J5-09 12 or 11 5 or 6 SDI2/PMA5/CN8/RG7 or SDO2/PMA3/CN10/RG8 Selected by JP7, also on J8-4
J5-10 38 35 U1RTS/BCLK1/SCK1/INT0/RF6
J5-11 13 4 SCK2/PMA5/CN8/RG6 Also on J8-3, user LED LD4
J5-12 39 31 PMA9/U2RX/SDA2/CN17/RF4
J5-13 GND
J5-14 40 32 PMA8/U2TX/SCL2/CN18/RF5
J5-15 42 16 PGED1/PMA6/AN0/VREF+/CVREF+/CN2/RB0
J5-16 41 15 PGC1/AN1/VREF-/CVREF-/CN3/RB1
J6-01 0 34 U1RX/SDI1/RF2
J6-02 26 60 PMD0/RE0
J6-03 1 33 U1TX/SDO1/RF3
J6-04 27 61 PMD1/RE1
J6-05 2 42 IC1/RTCC/INT1/RD8
J6-06 28 62 PMD2/RE2
J6-07 3 46 OC1/RD0
J6-09 4 59 RF1
J6-10 30 64 PMD4/RE4
J6-11 5 49 OC2/RD1
J6-12 31 1 PMD5/RE5
J6-13 6 50 OC3/RD2
J6-14 32 2 PMD6/RE6
J6-15 7 43 IC2/U1CTS/INT2/RD9
J6-16 33 3 PMD7/RE7
J7-01 A00/14 14 C2IN-/AN2/SS1/CN4/RB2
J7-02 A06/20 13 C2IN+/AN3/CN5/RB3
J7-03 A01/15 12 C1IN-/AN4/CN6/RB4
J7-03 A07/21 11 C1IN+/AN5/CN7/RB5
J7-05 A02/16 21 U2CTS/C1OUT/AN8/RB8
J7-06 A08/22 22 PMA7/C2OUT/AN9/RB9
J7-07 A03/17 23 TMS/CVREFOUT/PMA13/AN10/RB10
J7-08 A09/23 24 TDO/PMA12/AN11/RB11
J7-09 A04/18 or 45 27 or 36 TCK/PMA11/AN12/RB12 or SDA1/RG3 Selected by JP6
J7-10 A10/24 28 TDI/PMA10/AN13/RB13
J7-11 A05/19 or 46 29 or 37 PMALH/PMA1/U2RTS/AN14/RB14 or SCL1/RG2 Selected by JP8
J7-12 A11/25 30 PMALL/PMA0/AN15/OCFB/CN12/RB15
J11-1 45 36 SDA1/RG3
J11-2 46 37 SCL1/RG2

Pinout Table by PIC32 Microcontroller Pin

PIC32 Pin # Connector Pin # Pin # PIC32 Signal Notes
1 J6-12 31 PMD5/RE5
2 J6-14 32 PMD6/RE6
3 J6-16 33 PMD7/RE7
4 J5-11 13 SCK2/PMA5/CN8/RG6 Also on J8-3, User LED LD4
5 J5-09 or J5-07 12 SDI2/PMA5/CN8/RG7 Selected by JP7/JP5, also on J8-1
6 J5-07 or J5-09 11 SDO2/PMA3/CN10/RG8 Selected by JP5/JP7, also on J8-4
7 JP3-01 MCLR PIC32 reset, ICSP signal
8 J5-05 44 SS2/PMA2/CN11/RG9 Selected by JP4, also on J8-6
10 VDD
11 J7-03 A07/21 C1IN+/AN5/CN7/RB5
12 J7-03 A01/15 C1IN-/AN4/CN6/RB4
13 J7-02 A06/20 C2IN+/AN3/CN5/RB3
14 J7-01 A00/14 C2IN-/AN2/SS1/CN4/RB2
15 J5-16 41 PGC1/AN1/VREF-/CVREF-/CN3/RB1
16 J5-15 42 PGED1/PMA6/AN0/VREF+/CVREF+/CN2/RB0
17 JP3-05 PGEC2/AN8/OCFARB6 ICSP signal
18 JP3-04 PGED2/AN7/RB7 ICSP signal
21 J7-05 A02/16 U2CTS/C1OUT/AN8/RB8
22 J7-06 A08/22 PMA7/C2OUT/AN9/RB9
23 J7-07 A03/17 TMS/CVREFOUT/PMA13/AN10/RB10
24 J7-08 A09/23 TDO/PMA12/AN11/RB11
25 VSS
26 VDD
27 J7-09 A04/18 TCK/PMA11/AN12/RB12 Selected by JP6
28 J7-10 A10/24 TDI/PMA10/AN13/RB13
29 J7-11 A05/19 PMALH/PMA1/U2RTS/AN14/RB14 Selected by JP8
30 J7-12 A11/25 PMALL/PMA0/AN15/OCFB/CN12/RB15
31 J5-12 39 PMA9/U2RX/SDA2/CN17/RF4
32 J5-14 40 PMA8/U2TX/SCL2/CN18/RF5
33 J6-03 1 U1TX/SDO1/RF3
34 J6-01 0 U1RX/SDI1/RF2
35 J5-10 38 U1RTS/BCLK1/SCK1/INT0/RF6
36 J7-09, J11-1 45 SDA1/RG3 J7-09 selected by JP6
37 J7-11, J11-2 46 SCL1/RG2 J7-11 selected by JP8
38 VDD
39 OSC1/CLKI/RC12 X1, system clock oscillator
40 OSC2/CLKO/RC15 X1, system clock oscillator
41 VSS
42 J6-05 2 IC1/RTCC/INT1/RD8
43 J6-15 7 IC2/U1CTS/INT2/RD9
44 J5-01 8 IC3/PMCS2/PMA15/INT3/RD10
45 J5-04 35 IC4/PMCS1/PMA14/INT4/RD11
46 J6-07 3 OC1/RD0
47 SOSCI/CN1/RC13 X2, secondary oscillator
48 SOSCO/T1CK/CN0/RC14 X2, secondary oscillator
49 J6-11 5 OC2/RD1
50 J6-13 6 OC3/RD2
51 J5-03 9 OC4/RD3
52 J5-05 10 PMWR/OC5/IC5/CN13/RD4 Selected by JP4
53 J5-02 34 PMRD/CN14/RD5
54 J5-06 36 CN15/RD6
55 J5-08 37 CN16/RD7
56 VCAP/VDDcore
58 43 RF0 User LED LD5
59 J6-09 4 RF1
60 J6-02 26 PMD0/RE0
61 J6-04 27 PMD1/RE1
62 J6-06 28 PMD2/RE2
63 J6-08 29 PMD3/RE3
64 J6-10 30 PMD4/RE4