Info Box Applies to Diva

Preface[edit | edit source]

About this manual[edit | edit source]

This Hardware Manual describes the Diva CPU module series, their design and functions. Precise specifications for the Texas Instruments AM335x processor family can be found in the CPU datasheets and/or reference manuals.

Copyright/Trademarks[edit | edit source]

Ethernet® is a registered trademark of XEROX Corporation.

All other products and trademarks mentioned in this manual are property of their respective owners.

All rights reserved. Specifications may change at any time without notice.

Standards[edit | edit source]

DAVE Embedded Systems is certified to ISO 9001 standards.

Disclaimers[edit | edit source]

DAVE Embedded Systems does not assume any responsibility for availability, supply and support related to all products mentioned in this manual that are not strictly part of the Diva CPU module. Diva CPU Modules are not designed for use in life support appliances, devices, or systems where malfunctioning of these products can reasonably be expected to result in personal injury. DAVE Embedded Systems' customers who are using or selling these products for use in such applications do so at their own risk and agree to fully indemnify DAVE Embedded Systems for any damage resulting from such improper use or sale.

Warranty[edit | edit source]

Diva is guaranteed against defects in material and workmanship for the warranty period from the shipment date. During the warranty period, DAVE Embedded Systems will at its discretion decide to repair or replace defective products. Within the warranty period, the repair of products is free of charge provided that warranty conditions are observed. The warranty does not apply to defects resulting from improper or inadequate maintenance or handling by the customer, unauthorized modification or misuse, operation outside of the product’s specifications or improper installation or maintenance. DAVE Embedded Systems will not be responsible for any defects or damages to other products not supplied by DAVE Embedded Systems that are caused by a faulty Diva module.

Technical Support[edit | edit source]

We are committed to making our products easy to use and will help customers use our CPU modules in their systems. Technical support is delivered through email for registered kits owners. Support requests can be sent to helpdesk@dave.eu.

Software upgrades are available for download in the restricted download area of DAVE Embedded Systems git server: git@git.dave.eu . An account is required to access this area.

Please refer to our Web site at https://www.dave.eu/dave-cpu-module-am335x-diva.html for the latest product documents, utilities, drivers, Product Change Notices, Board Support Packages, Application Notes, mechanical drawings and additional tools and software.

Related Documents[edit | edit source]

Table: related documents

Document	Location
DAVE Embedded Systems Developers' Wiki	http://wiki.dave.eu/index.php/Main_Page

Hardware Manual in PDF format[edit | edit source]

N.B. The latest Hardware Manual version is 1.0.6.

Please download the Manual in pdf format.

Conventions, Abbreviations, Acronyms[edit | edit source]

Table: Abbreviations and acronyms used in this manual

Abbreviation	Definition
BTN	Button
GPI	General Purpose Input
GPIO	Generla Purpose Input and Output
GPO	General Purpose Output
DIVELK	Diva Embedded Linux Kit
PCB	Printed Circuit Board
RTC	Real Time Clock
SOM	System On Module
PMIC	Power Managemente Integrated Circuit

Introduction[edit | edit source]

Diva is a family of system-on-modules (SOM) that belongs to DAVE Embedded Systems Lite Line product class.

Diva is based on Texas Instruments "Sitara" AM335x Cortex-A8 application processor. It offers lots of graphics, processing, peripherals and industrial interface options, allowing customers to implement cost-effective design.

The Programmable Real-Time Unit and Industrial Communication Subsystem (PRU-ICSS) adds further flexibility and enables additional peripheral interfaces and real-time protocols such as EtherCAT, PROFINET, EtherNet/IP, PROFIBUS, Ethernet Powerlink.

Typical applications for Diva are:

• Industrial sensors and I/O units
• Industrial drives with integrated communications and multi-axis motor control
• Programmable logic/automation controllers (PLC/PAC) with integrated industrial communications such as PROFIBUS, CAN and Ethernet
• Home and Building Automation

Product Highlights[edit | edit source]

• ARM Cortex-A8 architecture @ 300/600/800/1000 MHz
• Lite Line
  • "No-frills" CPU module
  • SODIMM connector
  • Great cost-efficiency
• Extended power supply range [3.6 - 5.5]V, power regulation on board
• Coprocessing modules
  • NEON
  • PowerVR SGX
  • Crypto accelerator
• Industrial specification compliance
  • Extended temperature range (-40°C/+85°C)
  • Industrial-oriented interfaces set
• Programmable Real-Time Unit and Industrial Communication Subsystem (PRU-ICSS)
  • Supports protocols such as EtherCAT, PROFIBUS, PROFINET, EtherNet/IP™, and more
  • Peripherals Inside the PRU-ICSS: UART port with flow control pins, MII Ethernet ports, MDIO port, ...

Block Diagram[edit | edit source]

The following image shows Diva's block diagram:

Feature Summary[edit | edit source]

Table: CPU and Memories

Feature	Specifications	Options
CPU	"Sitara" AM335x ARMv7 architecture Cortex A8 @ 300/600/800/1000
RAM	16-bit DDR3 @ 333 MHz Up to 512 MB
Storage	Flash NOR SPI Flash NAND on Local bus I²C 32 kbit EEPROM

Table: Peripherals

Feature	Specifications	Options
Graphics Controller	Up to 24-Bits Data Output Resolution Up to 2048x2048 (With Maximum 126-MHz Pixel Clock) TFT/RGB support
2D/3D Engine	NEON Multimedia SIMD coprocessor PowerVR SGX 530 3D Accelerator
Coprocessors	Crypto Hardware Accelerator (AES, SHA, PKA, RNG) Up to 2x Programmable Realtime Units (PRUs)
USB	Up to 2x 2.0 OTG ports
UARTs	Up to 6x UART ports
GPIO	Up to 118 lines, shared with other functions (interrupts available)
Input interfaces	Integrated 4/5/8-wire resistive touch screen controller
Networking	Fast Ethernet with PHY Additional MII/RMII/RGMII interface
CAN	Dual CAN controller (version 2 part A, B)
SD/MMC	Up to 3x MMC/SD/SDIO Serial interfaces (up to 48 MHz)
Serial busses	Up to 3x I²C channels Up to 2x SPI channels
Audio	Up to 2x McASP interface
Timers	Up to N programmable general purpose timers (PWM function available)
RTC and watchdog	On board, external battery powered
Debug	JTAG IEEE 1149.1 Test Access Port ETM Port ETB Port
Miscellaneous	Up to 8x 12-bit ADC channels

Table: Electrical, Mechanical and Environmental Specifications

Feature	Specifications	Options
Supply Voltage	[3.6 - 5.5] V, voltage regulation on board
Active power consumption	Please refer to Power consumption section
Dimensions	67.5 mm x 38.3 mm
Weight
MTBF
Operating temperature	0..70 °C -40..+85 °C
Connectors	204-pin SO-DIMM

Design Overview[edit | edit source]

Processor Info[edit | edit source]

Diva module supports all flavours of Texas Instruments Sitara AM335x processors.

RAM memory bank[edit | edit source]

Main RAM memory consists of 16-bit wide DDR3 SDRAM running at 333 MHz. Maximum size is 512 MByte.

NOR flash bank[edit | edit source]

NOR flash memory - if populated - provides serial interface (SPI) and is connected to AM335X_SPI0 signals. Chip select is AM335X_SPI0_CS0.

NAND flash bank[edit | edit source]

NAND flash memory - if populated - is 8-bit wide and is connected to AM335X_GPMC signals. Chip select is connected to AM335X_GPMC_CS0n.

Memory map[edit | edit source]

Mechanical specifications[edit | edit source]

This chapter describes the mechanical characteristics of the Diva module.

Mechanical drawings are available in DXF format from the Diva page on DAVE Embedded Systems website: https://www.dave.eu/dave-cpu-module-am335x-diva.html

Board Layout[edit | edit source]

The following figure shows the physical dimensions of the Diva module:

The following figure highlights the maximum components' heights on Diva module:

Connectors[edit | edit source]

The following figure shows the Diva connector layout:

CAD Drawings[edit | edit source]

• 2D (DXF format): https://mirror.dave.eu/diva/mechanicals/diva.dxf.zip
• 3D (STEP format): https://mirror.dave.eu/diva/mechanicals/diva_stp.zip

Power, reset and control[edit | edit source]

Power Supply Unit (PSU) and recommended power-up sequence[edit | edit source]

Implementing correct power-up sequence for AM335x processors family is not a trivial task because several power rails are involved. DIVA SOM simplifies this task and embeds all the needed circuitry. The following picture shows a simplified block diagram of PSU/voltage monitoring circuitry.

The recommended power-up sequence is:

1. main power supply rail (VIN) ramps up
2. carrier board circuitry raises CB_PWR_GOOD; this indicates VIN rail is stable (1)
3. auxiliary regulator is enabled, thus processor's VDDS_RTC domain is powered
4. processor raises PMIC_PWR_EN signal to start main PSU
5. this step is composed of two events
   • main PSU enables several voltage rails to complete CPU, memories and peripheral power up sequence
   • VAUX33 signal is raised; this active-high signal indicates that SoM's I/O is powered. This signal can be used to manage carrier board power up sequence in order to prevent back powering (from SoM to carrier board or vice versa)
6. PORSTn_OUT signal is raised to indicate that all power rails of SOM are stable

(1) This step is not mandatory and VIN and CB_PWR_GOOD can be connected together. CB_PWR_GOOD is provided to prevent, if necessary, Diva's PSU to turn on during ramp of carrier board VIN rail. Depending on carrier board's PSU design, this may lead to undesired glitches.

PMIC[edit | edit source]

Main PSU subsystem of Diva SOM is based on Power Management Integrated Circuit (PMIC) Texas Instruments TPS65910A3A1. PMIC controls processor's power up sequence and sources the majority of power rails needed by AM335x.

Once processors is booted, it can control PMIC via the I2C0 bus to:

• set all the voltage needed by CPU in all operating conditions
• set RTC and control it
• manage power modes.

Besides I2C bus, PMIC has several control signals including:

• PWRHOLD (input): This signal is connected to processor's PMIC_PWR_EN and is used to initiate power up sequence.
• PMIC_PWRON (input): A rising edge of this pin (automatically done at startup) the PMIC performs an OFF-to-ACTIVE state transition. On a falling edge of this pin, the PMIC performs an ACTIVE-to-OFF state transition. This signal is pulled-up to VIN through 10kOhm resistor.

Power tree and voltage domains[edit | edit source]

Even though Diva is powered by one supply rail, several voltage domains exist according to circuitry and components' specifications.

From the system integrator's perspective, it is crucial to know how interface signals are related to these domains in order to design the carrier board properly.

The following image depicts Diva's simplified power tree and voltage domains organization.

Reset scheme and voltage monitoring[edit | edit source]

Diva implements a flexible reset scheme that offers several different solutions for system integrators at carrier board level. The following picture shows a diagram of the reset scheme:

Apart from processor, there are four reset sources on Diva SOM:

1. voltage monitor #1
   • this device monitors VDDS_RTC power rail and acts on processor's RTC_PWRONRSTn signal
2. voltage monitor #2
   • this device monitors processor's I/O power rail (3.3V) and acts on processor's PWRONRSTn signal
3. watchdog timer (please note that this watchdog timer has nothing to do with AM335x watchdog)
   • this optional device (Maxim MAX6373KA+) acts on processor's PWRONRSTn signal
4. PMIC
   • PMIC's nRESPWRON ouput acts on processor's PWRONRSTn signal.

In case a reset is issued by sources 2, 3 or 4 - eg. as consequence of a voltage glitch on power rail - or by an external source via EXT_PORSTn signal, non-volatile memories are protected against spurious write operations that might occur.

Some of these reset signals are accessible by carrier board circuitry as described below.

EXT_PORSTn[edit | edit source]

The EXT_PORSTn signal is an open-drain system reset input. When issued, a complete reset is done of all Diva SOM circuitry. Note that the power sequence is not retriggered when a system reset is performed. Only CPU and peripherals on module are reset when this pin is in low state and they remain in reset state while the EXT_PORSTn remains low. When the board is powered up, EXT_PORSTn is automatically asserted by Diva reset circuitry.

EXT_PORSTn is pulled-up to processor's I/O voltage (3.3V) with 10kOhm resistor.

PORSTn_OUT[edit | edit source]

PORSTn_OUT is an active-low push-pull ouput signal. PORSTn_OUT is asserted whenever any of the following conditions are met:

• EXT_PORSTn is asserted
• watchdog timer reset is asserted
• voltage monitor #2 reset is asserted
• PMIC_nRESPWRON is asserted.

PORSTn_OUT is connected to processor's PWRONRSTn (aka PORZ) signal.

PORSTn_OUT is pulled-down with 10kOhm resistor.

WARMRSTn[edit | edit source]

WARMRSTn is an active-low open-drain bidirectional signal. It is connected to processor's WARMRSTn (aka nRESETIN_OUT) signal and it is asserted by processor itself as described by AM335x Technical Reference Manual.

WARMRSTn is pulled-up to processor's I/O voltage (3.3V) with 10kOhm resistor.

RTC_PWRONRSTn[edit | edit source]

RTC_PORZ This signal is connected to processor's RTC_PWRONRSTn (aka RTC_PORZ) signal. It is an output-only signal pulled-down with a 100kOhm resistor. It only affects processor's RTC operations and registers.

JTAG_TRSTn[edit | edit source]

JTAG_TRSTn is the test and emulation logic reset input. It is pulled-down with 10kOhm resistor.

PMIC_nRESPWRON[edit | edit source]

PMIC_nRESPWRON is push-pull output signal. It is connected to PMIC's nRESPWRON. It is asserted by PMIC and acts on PORSTn_OUT signal. PMIC_nRESPWRON is pulled-down with 10kOhm resistor. For more details please refer to PMIC Data Manual.

MRSTn[edit | edit source]

MRSTn is connected to the RESET IN input of the voltage monitor #2 (Maxim MAX6389XS31D3+T). This signal is compared to the voltage monitor internal +1.27V reference. If the voltage at RESET IN is less than 1.27V, reset asserts.

MRSTn is pulled-up to processor's I/O voltage (3.3V) with 10kOhm resistor.

Boot Options[edit | edit source]

AM335x processor provides several boot sequences selectable via BTMODE[15:0] bootstrap pins. In order to fully understand how boot works on Diva platform, please refer to chapter 26 ("Initialization") of the AM335x Technical Reference Manual.

SYSBOOT[15:0] terminals are respectively LCD_DATA[15:0] inputs, latched on the rising edge of PWRONRSTn. The booting device list is created based on the SYSBOOT pins. A booting device can be a memory booting device (soldered flash memory or temporarily booting device like memory card) or a peripheral interface connected to a host. The main loop of the booting procedure goes through the booting device list and tries to search for an image from the currently selected booting device. This loop is exited if a valid booting image is found and successfully executed or upon watchdog expiration. The memory booting procedure is executed when the booting device type is one of NOR, NAND, MMC or SPI-EEPROM. The peripheral booting is executed when the booting device type is Ethernet, USB or UART.

Default boot configuration[edit | edit source]

The default Diva boot sequence is configured through a pull-up/pull-down resistors network. The following table describes the default boot signals (SYSBOOT[15:0]) configuration:

Function	Boot signals	Default configuration	Selection
Crystal frequency	SYSBOOT[15:14]	01	24 MHz
Reserved	SYSBOOT[13:12]	00	Normal operation
XIP/NAND boot	SYSBOOT[11:10]	00	Non-muxed device
NAND ECC / WAIT	SYSBOOT[9]	0	ECC by ROM
Bus width	SYSBOOT[8]	0	8 bit device
EMAC Phy mode	SYSBOOT[7:6]	01	RMII
CLKOUT1	SYSBOOT[5]	0	CLKOUT1 disabled
Boot sequence	SYSBOOT[4:0]	10111	MMC0/SPI0/UART0

With this settings, the default boot sequence is:

1. MMC0
2. SPI0
3. UART0

The internal bootrom tries each boot mode in sequence and stops when it finds a valid boot code.

Assuming that:

• default configuration is not changed,
• no boot MMC card is connected to processor's MMC0 interface,
• and there's a valid boot code programmed in SPI memory

the actual boot sequence performed by ARM core will be:

1. bootrom: this is executed from internal ROM code memory
2. U-Boot bootloader (1st stage)
   • copied from on-board NOR flash memory connected to SPI0 port to on-chip SRAM by bootrom
   • executed from on-chip SRAM
3. U-Boot bootloader (2nd stage)
   • copied by U-Boot 1st stage from NOR flash memory connected to SPI0 port to SDRAM
   • executed from SDRAM.

If no boot code is available in SPI NOR flash (for the bootrom this means that the first sector read returns 0xFFFFFFFF) the bootrom tries UART0 peripheral booting.

Boot sequence customization[edit | edit source]

Diva default boot sequence can be changed by optional external circuitry implemented on the carrier board.

Clock scheme[edit | edit source]

This section will be completed in a future version of this manual.

Recovery[edit | edit source]

For different reason, starting from image corruption due power loss during upgrade or unrecoverable bug while developing a new U-Boot feature, the user will need, sooner or later, to recover (bare-metal restore) the Diva SOM without using the bootloader itself. The following paragraphs introduce the available options. For further information, please refer to DAVE Embedded Systems Developers Wiki or contact the Technical Support Team.

JTAG recovery[edit | edit source]

JTAG recovery, though very useful (especially in development or production environment), requires dedicated hardware and software tools. Diva provides the JTAG interface, which, besides the debug purpose, can be used for programming and recovery operations. For further information on how to use the JTAG interface, please contact the Technical Support Team.

UART recovery[edit | edit source]

UART recovery does not requires any specialized hardware, apart a PC and a DB9 serial cross cable. The boot sequence must include the UART option and a way to enable it. Then a simple procedure allow to load the 1st and 2nd stage bootloader from the serial line. When the 2nd stage bootloader is running, reprogramming the flash memory is straightforward.

SD/MMC recovery[edit | edit source]

MMC recovery is a valuable option that requires no special hardware at all, apart a properly formatted MMC. The boot sequence must include the SD/MMC option and a way to enable it. When SD/MMC boot option is selected, bootrom looks for a valid boot sector on SD/MMC0. Once the board is running after booting from SD, reprogramming the flash memory is straightforward.

Multiplexing[edit | edit source]

AM335x pins can have up to N alternate function modes. The I/O pins can be internally routed to/from one of several peripheral modules within the device: this routing is referred to as Pin Multiplexing. Pin Multiplexing allows software to choose the subset of internal signals which will be mapped to balls of the device for a given application. Pin multiplexing selects which one of several peripheral pin functions controls the pin's I/O buffer output data values.

Please note that pin mux configuration is a very critical step. Wrong configuration may lead to system instability, side effects or even damage the hardware permanently.

Pin multiplexing configuration is quite complex in Diva but a tool from TI, the Pin Mux Utility, can help to perform this operation. Software installation and generic usage documentation is available on this page of the TI Embedded Processors Wiki: http://processors.wiki.ti.com/index.php/Pin_Mux_Utility_for_ARM_MPU_Processors

RTC[edit | edit source]

The TPS65910A3 PMIC provides a real-time clock (RTC) resource with:

• Oscillator for 32.768-kHz crystal
• Date, time and calendar
• Alarm capability
• Backup power from external battery

Backup power is provided through the PMIC_VBACKUP (J1.203) signal. If not used, PMIC_VBACKUP must be externally connected to PMIC.VCC5 (VIN).

For a detailed description of RTC characteristics, please refer to the TPS65910A3 PMIC datasheet.

Watchdog[edit | edit source]

An external watchdog (MAX6373 device) is connected to the AM335X_GMII1_TXD2 (J1.159) signal. During normal operation, the microprocessor should repeatedly toggle the watchdog input WDI (AM335X_GMII1_TXD2) before the selected watchdog timeout period elapses to demonstrate that the system is processing code properly. If the μP does not provide a valid watchdog input transition before the timeout period expires, the supervisor asserts a watchdog (WDO) output to signal that the system is not executing the desired instructions within the expected time frame. The watchdog output pulse is used to reset the μP.

The MAX6373 watchdog timer is pin-selectable and the timer can be configured through the WD_SET0 (J1.7), WD_SET1 (J1.9) and WD_SET2 (J1.11) signals. As a default, the watchdog is configured through a pull-up/pull-down resistors network (WD_SET[2..0] = 110) that keeps the watchdog timer inactive at startup. Startup delay ends when WDI sees its first level transition. The default watchdog timeout period is 10 s.

The configuration can be changed by optional external circuitry implemented on the carrier board.

Pinout table[edit | edit source]

This chapter contains the pinout description of the SODIMM-204 edge connector of the Diva module. The following table reports the pin mapping of the module signals routed to the J1 204 connector's pins.

Each row in the pinout tables contains the following information:

Table: Pinout information

Pin	Reference to the connector pin
Pin Name	Pin (signal) name on the Diva connectors
Internal Connection(s)	Connections to the Diva components: CPU.<x> : pin connected to CPU pad named <x> PMIC.<x> : pin connected to the Power Manager IC ETHPHY.<x> : pin connected to the LAN PHY
Ball/Pin #	Component ball/pin number connected to signal
Voltage domain	Please refer to this section
Type	I = Input O = Output D = Differential Z = High impedance S = Supply voltage G = Ground A = Analog signal
Pull	This refers to discrete pull-up/down resistors (if any). Additional pull-up/downs may be present if the signal is connected to any integrated circuit. In this case, please refer to the datasheet of the IC.

The Internal connection column reports the name of the microprocessor signal, which in turn contains references to all the peripheral functions that can be associated with that pin. For example, the following pin name

CPU.[GPMC_CSN1/GPMC_CLK/MMC1_CLK/PR1_EDIO_DATA_IN6/PR1_EDIO_DATA_OUT6/PR1_PRU1_PRU_R30_12/PR1_PRU1_PRU_R31_12/GPIO1_30]

INDICATES that the pin can be configured as:

• GPMC_CSN1
• GPMC_CLK
• MMC1_CLK
• PR1_EDIO_DATA_IN6
• PR1_EDIO_DATA_OUT6
• PR1_PRU1_PRU_R30_12
• PR1_PRU1_PRU_R31_12
• GPIO1_30.

For more details, please refer to the muxing options described in the Reference Manual of the AM355x.

Carrier board mating SO-DIMM connector - J1 pinout[edit | edit source]

Pin	Pin name	Internal connection(s)	Ball/pin #	Voltage domain	Type	Pull (1)	Notes
1	DGND				G
2	AM335X_GPMC_WPn	CPU.[GPMC_WPN/GMII2_RXERR/GPMC_CSN5/RMII2_RXERR/MMC2_SDCD/PR1_MII1_TXEN/UART4_TXD/GPIO0_31]	U17	VAUX2	IO		Optionally, this pin can connected to the WP NAND flash
3	AM335X_I2C0_SCL	CPU.[I2C0_SCL/TIMER7/UART2_RTSN/ECAP1_IN_PWM1_OUT////GPIO3_6]	C16	VAUX2	IO	10kΩ ↑	Internally connected to the PMIC and EEPROM
4	AM335X_GPMC_CS0n	CPU.[GPMC_CSN0///////GPIO1_29]	V6	VAUX2	IO	10kΩ ↑	Internally connected to the NAND flash (if present)
5	AM335X_I2C0_SDA	CPU.[I2C0_SDA/TIMER4/UART2_CTSN/ECAP2_IN_PWM2_OUT////GPIO3_5]	C17	VAUX2	IO	10kΩ ↑	Internally connected to the PMIC and EEPROM
6	AM335X_GPMC_CS1n	CPU.[GPMC_CSN1/GPMC_CLK/MMC1_CLK/PR1_EDIO_DATA_IN6/PR1_EDIO_DATA_OUT6/PR1_PRU1_PRU_R30_12/PR1_PRU1_PRU_R31_12/GPIO1_30]	U9	VAUX2	IO
7	WD_SET0			3.3V	I	10kΩ ↓	Optionally, this pin can be pullup
8	AM335X_GPMC_CS2n	CPU.[GPMC_CSN2/GPMC_BE1N/MMC1_CMD/PR1_EDIO_DATA_IN7/PR1_EDIO_DATA_OUT7/PR1_PRU1_PRU_R30_13/PR1_PRU1_PRU_R31_13/GPIO1_31]	V9	VAUX2	IO
9	WD_SET1			3.3V	I	10kΩ ↑	Optionally, this pin can be pulldown
10	AM335X_GPMC_CS3n	CPU.[GPMC_CSN3///MMC2_CMD/PR1_MII0_CRS/PR1_MDIO_DATA/EMU4/GPIO2_0]	T13	VAUX2	IO
11	WD_SET2			3.3V	I	10kΩ ↑	Optionally, this pin can be pulldown
12	DGND				G
13	EEPROM_WP			3.3V	I	10kΩ ↓	Optionally, this pin can be pullup
14	AM335X_GPMC_CLK	CPU.[GPMC_CLK/LCD_MEMORY_CLK/GPMC_WAIT1/MMC2_CLK/PR1_MII1_CRS/PR1_MDIO_MDCLK/MCASP0_FSR/GPIO2_1]	V12	VAUX2	IO
15	EEPROM_A1			3.3V	I	10kΩ ↓	Optionally, this pin can be pullup
16	AM335X_GPMC_WEn	CPU.[GPMC_WEN//TIMER6/////GPIO2_4]	U6	VAUX2	IO		Internally connected to the NAND flash (if present)
17	EEPROM_A0			3.3V	I	10kΩ ↓	Optionally, this pin can be pullup
18	AM335X_GPMC_OEn_REn	CPU.[GPMC_OEN_REN//TIMER6/////GPIO2_4]	T7	VAUX2	IO		Internally connected to the NAND flash (if present)
19	AM335X_EXT_WAKEUP	CPU.EXT_WAKEUP	C5	VRTC
20	AM335X_GPMC_ADVn_ALE	CPU.[GPMC_ADVN_ALE//TIMER4/////GPIO2_2]	R7	VAUX2	IO		Internally connected to the NAND flash (if present)
21	DGND				G
22	AM335X_GPMC_BE0n_CLE	CPU.[GPMC_BE0N_CLE//TIMER5/////GPIO2_5]	T6	VAUX2	IO		Internally connected to the NAND flash (if present)
23	AM335X_RMII1_REFCLK		H18	VAUX2	IO		HW option (not connected by default)
24	AM335X_GPMC_BE1n	CPU.[GPMC_BE1N/GMII2_COL/GPMC_CSN6/MMC2_DAT3/GPMC_DIR/PR1_MII1_RXLINK/MCASP0_ACLKR/GPIO1_28]	U18	VAUX2	IO
25	AM335X_UART0_TXD	CPU.[UART0_TXD/SPI1_CS1/DCAN0_RX/I2C2_SCL/ECAP1_IN_PWM1_OUT/PR1_PRU1_PRU_R30_15/PR1_PRU1_PRU_R31_15/GPIO1_11]	E16	VAUX2	IO
26	AM335X_GPMC_WAIT	CPU.[GPMC_WAIT0/GMII2_CRS/GPMC_CSN4/RMII2_CRS_DV/MMC1_SDCD/PR1_MII1_COL/UART4_RXD/GPIO0_30]	T17	VAUX2	IO		Internally connected to the NAND flash (if present)
27	AM335X_UART0_RXD	CPU.[UART0_RXD/SPI1_CS0/DCAN0_TX/I2C2_SDA/ECAP2_IN_PWM2_OUT/PR1_PRU1_PRU_R30_14/PR1_PRU1_PRU_R31_14/GPIO1_10]	E15	VAUX2	IO
28	AM335X_GPMC_A0	CPU.[GPMC_A0/GMII2_TXEN/RGMII2_TCTL/RMII2_TXEN/GPMC_A16/PR1_MII_MT1_CLK/EHRPWM1_TRIPZONE_INPUT/GPIO1_16]	R13	VAUX2	IO
29	AM335X_UART0_RTSn	CPU.[UART0_RTSN/UART4_TXD/DCAN1_RX/I2C1_SCL/SPI1_D1/SPI1_CS0/PR1_EDC_SYNC1_OUT/GPIO1_9]	E17	VAUX2	IO		HW option: connected to PMIC_SLEEP
30	AM335X_GPMC_A1	CPU.[GPMC_A1/GMII2_RXDV/RGMII2_RCTL/MMC2_DAT0/GPMC_A17/PR1_MII1_TXD3/EHRPWM0_SYNCO/GPIO1_17]	V14	VAUX2	IO
31	AM335X_UART0_CTSn	CPU.[UART0_CTSN/UART4_RXD/DCAN1_TX/I2C1_SDA/SPI1_D0/TIMER7/PR1_EDC_SYNC0_OUT/GPIO1_8]	E18	VAUX2	IO		HW option: connected to PMIC_INT1
32	DGND				G
33	AM335X_UART1_TXD	CPU.[UART1_TXD/MMC2_SDWP/DCAN1_RX/I2C1_SCL//PR1_UART0_TXD/PR1_PRU0_PRU_R31_16/GPIO0_15]	D15	VAUX2	IO
34	AM335X_GPMC_A2	CPU.[GPMC_A2/GMII2_TXD3/RGMII2_TD3/MMC2_DAT1/GPMC_A18/PR1_MII1_TXD2/EHRPWM1A/GPIO1_18]	U14	VAUX2	IO
35	AM335X_UART1_RXD	CPU.[UART1_RXD/MMC1_SDWP/DCAN1_TX/I2C1_SDA//PR1_UART0_RXD/PR1_PRU1_PRU_R31_16/GPIO0_14]	D16	VAUX2	IO
36	AM335X_GPMC_A3	CPU.[GPMC_A3/GMII2_TXD2/RGMII2_TD2/MMC2_DAT2/GPMC_A19/PR1_MII1_TXD1/EHRPWM1B/GPIO1_19]	T14	VAUX2	IO
37	AM335X_UART1_RTSn	CPU.[UART1_RTSN/TIMER5/DCAN0_RX/I2C2_SCL/SPI1_CS1/PR1_UART0_RTS_N/PR1_EDC_LATCH1_IN/GPIO0_13]	D17	VAUX2	IO
38	AM335X_GPMC_A4	CPU.[GPMC_A4/GMII2_TXD1/RGMII2_TD1/RMII2_TXD1/GPMC_A20/PR1_MII1_TXD0/EQEP1A_IN/GPIO1_20]	R14	VAUX2	IO
39	AM335X_UART1_CTSn	CPU.[UART1_CTSN/TIMER6/DCAN0_TX/I2C2_SDA/SPI1_CS0/PR1_UART0_CTS_N/PR1_EDC_LATCH0_IN/GPIO0_12]	D18	VAUX2	IO
40	AM335X_GPMC_A5	CPU.[GPMC_A5/GMII2_TXD0/RGMII2_TD0/RMII2_TXD0/GPMC_A21/PR1_MII1_RXD3/EQEP1B_IN/GPIO1_21]	V15	VAUX2	IO
41	DGND				G
42	AM335X_GPMC_A6	CPU.[GPMC_A6/GMII2_TXCLK/RGMII2_TCLK/MMC2_DAT4/GPMC_A22/PR1_MII1_RXD2/EQEP1_INDEX/GPIO1_22]	U15	VAUX2	IO
43	AM335X_SPI0_SCLK	CPU.[SPI0_SCLK/UART2_RXD/I2C2_SDA/EHRPWM0A/PR1_UART0_CTS_N/PR1_EDIO_SOF/EMU2/GPIO0_2]	A17	VAUX2	IO		Internally connected to the NOR flash (if present)
44	AM335X_GPMC_A7	CPU.[GPMC_A7/GMII2_RXCLK/RGMII2_RCLK/MMC2_DAT5/GPMC_A23/PR1_MII1_RXD1/EQEP1_STROBE/GPIO1_23]	T15	VAUX2	IO
45	AM335X_SPI0_D0	CPU.[SPI0_D0/UART2_TXD/I2C2_SCL/EHRPWM0B/PR1_UART0_RTS_N/PR1_EDIO_LATCH_IN/EMU3/GPIO0_3]	B17	VAUX2	IO		Internally connected to the NOR flash (if present)
46	AM335X_GPMC_A8	CPU.[GPMC_A8/GMII2_RXD3/RGMII2_RD3/MMC2_DAT6/GPMC_A24/PR1_MII1_RXD0/MCASP0_ACLKX/GPIO1_24]	V16	VAUX2	IO
47	AM335X_SPI0_D1	CPU.[SPI0_D1/MMC1_SDWP/I2C1_SDA/EHRPWM0_TRIPZONE_INPUT/PR1_UART0_RXD/PR1_EDIO_DATA_IN0/PR1_EDIO_DATA_OUT0/GPIO0_4]	B16	VAUX2	IO		Internally connected to the NOR flash (if present)
48	AM335X_GPMC_A9	CPU.[GPMC_A9/GMII2_RXD2/RGMII2_RD2/MMC2_DAT7/GPMC_A25/PR1_MII_MR1_CLK/MCASP0_FSX/GPIO1_25]	U16	VAUX2	IO
49	AM335X_SPI0_CS0	CPU.[SPI0_CS0/MMC2_SDWP/I2C1_SCL/EHRPWM0_SYNCI/PR1_UART0_TXD/PR1_EDIO_DATA_IN1/PR1_EDIO_DATA_OUT1/GPIO0_5]	A16	VAUX2	IO		Internally connected to the NOR flash (if present)
50	AM335X_GPMC_A10	CPU.[GPMC_A10/GMII2_RXD1/RGMII2_RD1/RMII2_RXD1/GPMC_A26/PR1_MII1_RXDV/MCASP0_AXR0/GPIO1_26]	T16	VAUX2	IO
51	AM335X_SPI0_CS1	CPU.[SPI0_CS1/UART3_RXD/ECAP1_IN_PWM1_OUT/MMC0_POW/XDMA_EVENT_INTR2/MMC0_SDCD/EMU4/GPIO0_6]	C15	VAUX2	IO		Optionally, this pin can connected to the RFU NOR flash
52	DGND				G
53	USB0_CE	CPU.USB0_CE	M15	VAUX33/VAUX1	A
54	AM335X_GPMC_A11	CPU.[GPMC_A11/GMII2_RXD0/RGMII2_RD0/RMII2_RXD0/GPMC_A27/PR1_MII1_RXER/MCASP0_AXR1/GPIO1_27]	V17	VAUX2	IO
55	USB0_ID	CPU.USB0_ID	P16	VAUX33/VAUX1	A
56	AM335X_GPMC_AD0	CPU.[GPMC_AD0/MMC1_DAT0//////GPIO1_0]	U7	VAUX2	IO		Internally connected to the NAND flash (if present)
57	USB0_DP	CPU.USB0_DP	N17	VAUX33/VAUX1	D
58	AM335X_GPMC_AD1	CPU.[GPMC_AD1/MMC1_DAT1//////GPIO1_1]	V7	VAUX2	IO		Internally connected to the NAND flash (if present)
59	USB0_DM	CPU.USB0_DM	N18	VAUX33/VAUX1	D
60	AM335X_GPMC_AD2	CPU.[GPMC_AD2/MMC1_DAT2//////GPIO1_2]	R8	VAUX2	IO		Internally connected to the NAND flash (if present)
61	DGND				G
62	AM335X_GPMC_AD3	CPU.[GPMC_AD3/MMC1_DAT3//////GPIO1_3]	T8	VAUX2	IO		Internally connected to the NAND flash (if present)
63	USB0_DRVVBUS	CPU.USB0_DRVVBUS	F16	VAUX2	O
64	AM335X_GPMC_AD4	CPU.[GPMC_AD4/MMC1_DAT4//////GPIO1_4]	U8	VAUX2	IO		Internally connected to the NAND flash (if present)
65	VUSB_VBUS0	CPU.USB0_VBUS	P15	VAUX33/VAUX1	A
66	AM335X_GPMC_AD5	CPU.[GPMC_AD5/MMC1_DAT5//////GPIO1_5]	V8	VAUX2	IO		Internally connected to the NAND flash (if present)
67	AM335x_EXTINTn	CPU.NMIn	B18	VAUX2	I
68	AM335X_GPMC_AD6	CPU.[GPMC_AD6/MMC1_DAT6//////GPIO1_6]	R9	VAUX2	IO		Internally connected to the NAND flash (if present)
69	AM335X_XDMA_EVENT_INTR0	CPU.[XDMA_EVENT_INTR0//TIMER4/CLKOUT1/SPI1_CS1/PR1_PRU1_PRU_R31_16/EMU2/GPIO0_19]	A15	VAUX2	IO
70	AM335X_GPMC_AD7	CPU.[GPMC_AD7/MMC1_DAT7//////GPIO1_7]	T9	VAUX2	IO		Internally connected to the NAND flash (if present)
71	AM335X_XDMA_EVENT_INTR1	CPU.[XDMA_EVENT_INTR1//TCLKIN/CLKOUT2/TIMER7/PR1_PRU0_PRU_R31_16/EMU3/GPIO0_20]	D14	VAUX2	IO
72	DGND				G
73	USB1_CE	CPU.USB1_CE	P18	VAUX33/VAUX1	A
74	AM335X_GPMC_AD8	CPU.[GPMC_AD8/LCD_DATA23/MMC1_DAT0/MMC2_DAT4/EHRPWM2A/PR1_MII_MT0_CLK//GPIO0_22]	U10	VAUX2	IO
75	USB1_ID	CPU.USB1_ID	P17	VAUX33/VAUX1	A
76	AM335X_GPMC_AD9	CPU.[GPMC_AD9/LCD_DATA22/MMC1_DAT1/MMC2_DAT5/EHRPWM2B/PR1_MII0_COL//GPIO0_23]	T10	VAUX2	IO
77	USB1_DP	CPU.USB1_DP	R17	VAUX33/VAUX1	D
78	AM335X_GPMC_AD10	CPU.[GPMC_AD10/LCD_DATA21/MMC1_DAT2/MMC2_DAT6/EHRPWM2_TRIPZONE_INPUT/PR1_MII0_TXEN//GPIO0_26]	T11	VAUX2	IO
79	USB1_DM	CPU.USB1_DM	R18	VAUX33/VAUX1	D
80	AM335X_GPMC_AD11	CPU.[GPMC_AD11/LCD_DATA20/MMC1_DAT3/MMC2_DAT7/EHRPWM2_SYNCO/PR1_MII0_TXD3//GPIO0_27]	U12	VAUX2	IO
81	DGND				G
82	AM335X_GPMC_AD12	CPU.[GPMC_AD12/LCD_DATA19/MMC1_DAT4/MMC2_DAT0/EQEP2A_IN/PR1_MII0_TXD2/PR1_PRU0_PRU_R30_14/GPIO1_12]	T12	VAUX2	IO
83	USB1_DRVVBUS	CPU.USB1_DRVVBUS	F15	VAUX2	O
84	AM335X_GPMC_AD13	CPU.[GPMC_AD13/LCD_DATA18/MMC1_DAT5/MMC2_DAT1/EQEP2B_IN/PR1_MII0_TXD1/PR1_PRU0_PRU_R30_15/GPIO1_13]	R12	VAUX2	IO
85	VUSB_VBUS1	CPU.USB1_VBUS	T18	VAUX33/VAUX1	A
86	AM335X_GPMC_AD14	CPU.[GPMC_AD14/LCD_DATA17/MMC1_DAT6/MMC2_DAT2/EQEP2_INDEX/PR1_MII0_TXD0/PR1_PRU0_PRU_R31_14/GPIO1_14]	V13	VAUX2	IO
87	AM335X_AIN0	CPU.AIN0	B6	VPLL	A
88	AM335X_GPMC_AD15	CPU.[GPMC_AD15/LCD_DATA16/MMC1_DAT7/MMC2_DAT3/EQEP2_STROBE/PR1_ECAP0_ECAP_CAPIN_APWM_O/PR1_PRU0_PRU_R31_15/GPIO1_15]	U13	VAUX2	IO
89	AM335X_AIN1	CPU.AIN1	C7	VPLL	A
90	AM335X_LCD_PCLK	CPU.[LCD_PCLK/GPMC_A10/PR1_MII0_CRS/PR1_EDIO_DATA_IN4/PR1_EDIO_DATA_OUT4/PR1_PRU1_PRU_R30_10/PR1_PRU1_PRU_R31_10/GPIO2_24]	V5	VAUX2	IO
91	AM335X_AIN2	CPU.AIN2	B7	VPLL	A
92	DGND				G
93	AGND_TSC				G
94	AM335X_LCD_VSYNC	CPU.[LCD_VSYNC/GPMC_A8//PR1_EDIO_DATA_IN2/PR1_EDIO_DATA_OUT2/PR1_PRU1_PRU_R30_8/PR1_PRU1_PRU_R31_8/GPIO2_22]	U5	VAUX2	IO
95	AM335X_AIN3	CPU.AIN3	A7	VPLL	A
96	AM335X_LCD_HSYNC	CPU.[LCD_HSYNC/GPMC_A9//PR1_EDIO_DATA_IN3/PR1_EDIO_DATA_OUT3/PR1_PRU1_PRU_R30_9/PR1_PRU1_PRU_R31_9/GPIO2_23]	R5	VAUX2	IO
97	AM335X_AIN4	CPU.AIN4	C8	VPLL	A
98	AM335X_LCD_AC_BIAS_EN	CPU.[LCD_AC_BIAS_EN/GPMC_A11/PR1_MII1_CRS/PR1_EDIO_DATA_IN5/PR1_EDIO_DATA_OUT5/PR1_PRU1_PRU_R30_11/PR1_PRU1_PRU_R31_11/GPIO2_25]	R6	VAUX2	IO
99	AM335X_AIN5	CPU.AIN5	B8	VPLL	A
100	AM335X_LCD_DATA0	CPU.[LCD_DATA0/GPMC_A0/PR1_MII_MT0_CLK/EHRPWM2A//PR1_PRU1_PRU_R30_0/PR1_PRU1_PRU_R31_0/GPIO2_6]	R1	VAUX2	IO
101	AGND_TSC				G
102	AM335X_LCD_DATA1	CPU.[LCD_DATA1/GPMC_A1/PR1_MII0_TXEN/EHRPWM2B//PR1_PRU1_PRU_R30_1/PR1_PRU1_PRU_R31_1/GPIO2_7]	R2	VAUX2	IO
103	AM335X_AIN6	CPU.AIN6	A8	VPLL	A
104	AM335X_LCD_DATA2	CPU.[LCD_DATA2/GPMC_A2/PR1_MII0_TXD3/EHRPWM2_TRIPZONE_INPUT//PR1_PRU1_PRU_R30_2/PR1_PRU1_PRU_R31_2/GPIO2_8]	R3	VAUX2	IO
105	AM335X_AIN7	CPU.AIN7	C9	VPLL	A
106	AM335X_LCD_DATA3	CPU.[LCD_DATA3/GPMC_A3/PR1_MII0_TXD2/EHRPWM2_SYNCI_O//PR1_PRU1_PRU_R30_3/PR1_PRU1_PRU_R31_3/GPIO2_9]	R4	VAUX2	IO
107	AGND_TSC				G
108	AM335X_LCD_DATA4	CPU.[LCD_DATA4/GPMC_A4/PR1_MII0_TXD1/EQEP2A_IN//PR1_PRU1_PRU_R30_4/PR1_PRU1_PRU_R31_4/GPIO2_10]	T1	VAUX2	IO
109	AM335X_ECAP0_IN_PWM0_OUT	CPU.[ECAP0_IN_PWM0_OUT/UART3_TXD/SPI1_CS1/PR1_ECAP0_ECAP_CAPIN_APWM_O/SPI1_SCLK/MMC0_SDWP/XDMA_EVENT_INTR2/GPIO0_7]	C18	VAUX2	IO		HW option: connected to Oscillator EN
110	AM335X_LCD_DATA5	CPU.[LCD_DATA5/GPMC_A5/PR1_MII0_TXD0/EQEP2B_IN//PR1_PRU1_PRU_R30_5/PR1_PRU1_PRU_R31_5/GPIO2_11]	T2	VAUX2	IO
111	AM335X_MMC_D3	CPU.[MMC0_DAT3/GPMC_A20/UART4_CTSN/TIMER5/UART1_DCDN/PR1_PRU0_PRU_R30_8/PR1_PRU0_PRU_R31_8/GPIO2_26]	F17	VMMC	IO
112	DGND				G
113	AM335X_MMC_D2	CPU.[MMC0_DAT2/GPMC_A21/UART4_RTSN/TIMER6/UART1_DSRN/PR1_PRU0_PRU_R30_9/PR1_PRU0_PRU_R31_9/GPIO2_27]	F18	VMMC	IO
114	AM335X_LCD_DATA6	CPU.[LCD_DATA6/GPMC_A6/PR1_EDIO_DATA_IN6/EQEP2_INDEX/PR1_EDIO_DATA_OUT6/PR1_PRU1_PRU_R30_6/PR1_PRU1_PRU_R31_6/GPIO2_12]	T3	VAUX2	IO
115	AM335X_MMC_D1	CPU.[MMC0_DAT1/GPMC_A22/UART5_CTSN/UART3_RXD/UART1_DTRN/PR1_PRU0_PRU_R30_10/PR1_PRU0_PRU_R31_10/GPIO2_28]	G15	VMMC	IO
116	AM335X_LCD_DATA7	CPU.[LCD_DATA7/GPMC_A7/PR1_EDIO_DATA_IN7/EQEP2_STROBE/PR1_EDIO_DATA_OUT7/PR1_PRU1_PRU_R30_7/PR1_PRU1_PRU_R31_7/GPIO2_13]	T4	VAUX2	IO
117	AM335X_MMC_D0	CPU.[MMC0_DAT0/GPMC_A23/UART5_RTSN/UART3_TXD/UART1_RIN/PR1_PRU0_PRU_R30_11/PR1_PRU0_PRU_R31_11/GPIO2_29]	G16	VMMC	IO
118	AM335X_LCD_DATA8	CPU.[LCD_DATA8/GPMC_A12/EHRPWM1_TRIPZONE_INPUT/MCASP0_ACLKX/UART5_TXD/PR1_MII0_RXD3/UART2_CTSN/GPIO2_14]	U1	VAUX2	IO
119	AM335X_MMC_CMD	CPU.[MMC0_CMD/GPMC_A25/UART3_RTSN/UART2_TXD/DCAN1_RX/PR1_PRU0_PRU_R30_13/PR1_PRU0_PRU_R31_13/GPIO2_31]	G18	VMMC	IO
120	AM335X_LCD_DATA9	CPU.[LCD_DATA9/GPMC_A13/EHRPWM1_SYNCO/MCASP0_FSX/UART5_RXD/PR1_MII0_RXD2/UART2_RTSN/GPIO2_15]	U2	VAUX2	IO
121	DGND				G
122	AM335X_LCD_DATA10	CPU.[LCD_DATA10/GPMC_A14/EHRPWM1A/MCASP0_AXR0//PR1_MII0_RXD1/UART3_CTSN/GPIO2_16]	U3	VAUX2	IO
123	AM335X_MMC_CLK	CPU.[MMC0_CLK/GPMC_A24/UART3_CTSN/UART2_RXD/DCAN1_TX/PR1_PRU0_PRU_R30_12/PR1_PRU0_PRU_R31_12/GPIO2_30]	G17	VMMC	IO
124	AM335X_LCD_DATA11	CPU.[LCD_DATA11/GPMC_A15/EHRPWM1B/MCASP0_AHCLKR/MCASP0_AXR2/PR1_MII0_RXD0/UART3_RTSN/GPIO2_17]	U4	VAUX2	IO
125	JTAG_EMU1	CPU.[EMU1///////GPIO3_8]	B14	VAUX2	IO	10kΩ ↑
126	AM335X_LCD_DATA12	CPU.[LCD_DATA12/GPMC_A16/EQEP1A_IN/MCASP0_ACLKR/MCASP0_AXR2/PR1_MII0_RXLINK/UART4_CTSN/GPIO0_8]	V2	VAUX2	IO
127	JTAG_EMU0	CPU.[EMU0///////GPIO3_7]	C14	VAUX2	IO	10kΩ ↑
128	AM335X_LCD_DATA13	CPU.[LCD_DATA13/GPMC_A17/EQEP1B_IN/MCASP0_FSR/MCASP0_AXR3/PR1_MII0_RXER/UART4_RTSN/GPIO0_9]	V3	VAUX2	IO
129	JTAG_TDO	CPU.TDO	A11	VAUX2	O
130	AM335X_LCD_DATA14	CPU.[LCD_DATA14/GPMC_A18/EQEP1_INDEX/MCASP0_AXR1/UART5_RXD/PR1_MII_MR0_CLK/UART5_CTSN/GPIO0_10]	V4	VAUX2	IO
131	JTAG_TDI	CPU.TDI	B11	VAUX2	I
132	DGND				G
133	JTAG_TMS	CPU.TMS	C11	VAUX2	I
134	AM335X_LCD_DATA15	CPU.[LCD_DATA15/GPMC_A19/EQEP1_STROBE/MCASP0_AHCLKX/MCASP0_AXR3/PR1_MII0_RXDV/UART5_RTSN/GPIO0_11]	T5	VAUX2	IO
135	JTAG_TRSTn	CPU.TRSTn	B10	VAUX2	I	10kΩ ↓
136	AM335X_MCASP0_FSR	CPU.[MCASP0_FSR/EQEP0B_IN/MCASP0_AXR3/MCASP1_FSX/EMU2/PR1_PRU0_PRU_R30_5/PR1_PRU0_PRU_R31_5/GPIO3_19]	C13	VAUX2	IO
137	JTAG_TCK	CPU.TCK	A12	VAUX2	I
138	AM335X_MCASP0_AXR1	CPU.[MCASP0_AXR1/EQEP0_INDEX//MCASP1_AXR0/EMU3/PR1_PRU0_PRU_R30_6/PR1_PRU0_PRU_R31_6/GPIO3_20]	D13	VAUX2	IO
139	ETH_CTTD				S
140	AM335X_MCASP0_FSX	CPU.[MCASP0_FSX/EHRPWM0B//SPI1_D0/MMC1_SDCD/PR1_PRU0_PRU_R30_1/PR1_PRU0_PRU_R31_1/GPIO3_15]	B13	VAUX2	IO
141	DGND				G
142	AM335X_MCASP0_AXR0	CPU.[MCASP0_AXR0/EHRPWM0_TRIPZONE_INPUT//SPI1_D1/MMC2_SDCD/PR1_PRU0_PRU_R30_2/PR1_PRU0_PRU_R31_2/GPIO3_16]	D12	VAUX2	IO
143	ETH_CTRD				S
144	AM335X_MCASP0_AHCLKR	CPU.[MCASP0_AHCLKR/EHRPWM0_SYNCI_O/MCASP0_AXR2/SPI1_CS0/ECAP2_IN_PWM2_OUT/PR1_PRU0_PRU_R30_3/PR1_PRU0_PRU_R31_3/GPIO3_17]	C12	VAUX2	IO
145	ETH_TX-	ETHPHY.TXN	28		D
146	AM335X_MCASP0_ACLKR	CPU.[MCASP0_ACLKR/EQEP0A_IN/MCASP0_AXR2/MCASP1_ACLKX/MMC0_SDWP/PR1_PRU0_PRU_R30_4/PR1_PRU0_PRU_R31_4/GPIO3_18]	B12	VAUX2	IO
147	ETH_TX+	ETHPHY.TXP	29		D
148	AM335X_MCASP0_AHCLKX	CPU.[MCASP0_AHCLKX/EQEP0_STROBE/MCASP0_AXR3/MCASP1_AXR1/EMU4/PR1_PRU0_PRU_R30_7/PR1_PRU0_PRU_R31_7/GPIO3_21]	A14	VAUX2	IO
149	ETH_RX-	ETHPHY.RXN	30		D
150	AM335X_MCASP0_ACLKX	CPU.[MCASP0_ACLKX/EHRPWM0A//SPI1_SCLK/MMC0_SDCD/PR1_PRU0_PRU_R30_0/PR1_PRU0_PRU_R31_0/GPIO3_14]	A13	VAUX2	IO
151	ETH_RX+	ETHPHY.RXP	31		D
152	DGND				G
153	EMAC0_PHY_LED_SPEED	ETHPHY.LED2/nINTSEL	2	3.3V	O	10kΩ ↓	10kOhm pull-down
154	NC Optional routing: PMIC_VRTC VDD3_SMPS VDIG1						By default, this pin must not be connected. Optionally, it can route power voltages generated by Diva PSU. This option is meant to allow monitoring of such voltages by carrier board circuitry. It is not meant to power carrier board devices. As these options requires custom manufacturing BOMs, please contact the Sales Department for more information.
155	EMAC0_PHY_LED_LINK/ACT	ETHPHY.LED1/nREGOFF	3	3.3V	O	10kΩ ↓	10kOhm pull-down
156	NC Options routing: VRTC_LDO						By default, this pin must not be connected. Optionally, it can route power voltages generated by Diva PSU. This option is meant to allow monitoring of such voltages by carrier board circuitry. It is not meant to power carrier board devices. As these options requires custom manufacturing BOMs, please contact the Sales Department for more information.
157	AM335X_GMII1_TXD3	CPU.[GMII1_TXD3/DCAN0_TX/RGMII1_TD3/UART4_RXD/MCASP1_FSX/MMC2_DAT1/MCASP0_FSR/GPIO0_16]	J18	VAUX2	IO
158	NC Optional routing: VDAC						By default, this pin must not be connected. Optionally, it can route power voltages generated by Diva PSU. This option is meant to allow monitoring of such voltages by carrier board circuitry. It is not meant to power carrier board devices. As these options requires custom manufacturing BOMs, please contact the Sales Department for more information.
159	AM335X_GMII1_TXD2 Ordering codes: DDxxxxx1xxx DDxxxxx2xxx DDxxxxx5xxx	CPU.[GMII1_TXD2/DCAN0_RX/RGMII1_TD2/UART4_TXD/MCASP1_AXR0/MMC2_DAT2/MCASP0_AHCLKX/GPIO0_17]	K15	VAUX2	IO		Internally connected to the WDT
159	NC Ordering codes: DDxxxxx0xxx DDxxxxx3xxx
160	NC Optional routing: VPLL						By default, this pin must not be connected. Optionally, it can route power voltages generated by Diva PSU. This option is meant to allow monitoring of such voltages by carrier board circuitry. It is not meant to power carrier board devices. As these options requires custom manufacturing BOMs, please contact the Sales Department for more information.
161	DGND				G
162	NC Optional routing: VAUX1						By default, this pin must not be connected. Optionally, it can route power voltages generated by Diva PSU. This option is meant to allow monitoring of such voltages by carrier board circuitry. It is not meant to power carrier board devices. As these options require custom manufacturing BOMs, please contact the Sales Department for more information.
163	AM335X_GMII1_RXDV	CPU.[GMII1_RXDV/LCD_MEMORY_CLK/RGMII1_RCTL/UART5_TXD/MCASP1_ACLKX/MMC2_DAT0/MCASP0_ACLKR/GPIO3_4]	J17	VAUX2	IO
164	NC Optional routing: VAUX2						By default, this pin must not be connected. Optionally, it can route power voltages generated by Diva PSU. This option is meant to allow monitoring of such voltages by carrier board circuitry. It is not meant to power carrier board devices. As these options requires custom manufacturing BOMs, please contact the Sales Department for more information.
165	AM335X_GMII1_MDIO_CLK	CPU.[MDIO_CLK/TIMER5/UART5_TXD/UART3_RTSN/MMC0_SDWP/MMC1_CLK/MMC2_CLK/GPIO0_1]	M18	VAUX2	IO		Internally connected to the ETH PHY
166	NC Optional routing: VDD1_SMPS						By default, this pin must not be connected. Optionally, it can route power voltages generated by Diva PSU. This option is meant to allow monitoring of such voltages by carrier board circuitry. It is not meant to power carrier board devices. As these options requires custom manufacturing BOMs, please contact the Sales Department for more information.
167	AM335X_GMII1_MDIO_DATA	CPU.[MDIO_DATA/TIMER6/UART5_RXD/UART3_CTSN/MMC0_SDCD/MMC1_CMD/MMC2_CMD/GPIO0_0]	M17	VAUX2	IO	1.5kΩ ↑	Internally connected to the ETH PHY
168	NC Optional routing: VDD2_SMPS						By default, this pin must not be connected. Optionally, it can route power voltages generated by Diva PSU. This option is meant to allow monitoring of such voltages by carrier board circuitry. It is not meant to power carrier board devices. As these options requires custom manufacturing BOMs, please contact the Sales Department for more information.
169	AM335X_GMII1_COL	CPU.[GMII1_COL/RMII2_REFCLK/SPI1_SCLK/UART5_RXD/MCASP1_AXR2/MMC2_DAT3/MCASP0_AXR2/GPIO3_0]	H16	VAUX2	IO		Internally used for DDR power management (if required) – HW option
170	PORSTn_OUT			VAUX2	I	10kΩ ↓	See #Reset scheme and voltage monitoring.
171	AM335X_GMII1_RXD3	CPU.[GMII1_RXD3/UART3_RXD/RGMII1_RD3/MMC0_DAT5/MMC1_DAT2/UART1_DTRN/MCASP0_AXR0/GPIO2_18]	L17	VAUX2	IO
172	DGND				G
173	AM335X_GMII1_RXD2	CPU.[GMII1_RXD2/UART3_TXD/RGMII1_RD2/MMC0_DAT4/MMC1_DAT3/UART1_RIN/MCASP0_AXR1/GPIO2_19]	L16	VAUX2	IO
174	CB_PWR_GOOD			VIN	I		See #Power Supply Unit (PSU) and recommended power-up sequence.
175	AM335X_GMII1_RXCLK	CPU.[GMII1_RXCLK/UART2_TXD/RGMII1_RCLK/MMC0_DAT6/MMC1_DAT1/UART1_DSRN/MCASP0_FSX/GPIO3_10]	L18	VAUX2	IO
176	NC Optional routing: VDIG2						By default, this pin must not be connected. Optionally, it can route power voltages generated by Diva PSU. This option is meant to allow monitoring of such voltages by carrier board circuitry. It is not meant to power carrier board devices. As these options requires custom manufacturing BOMs, please contact the Sales Department for more information.
177	AM335X_GMII1_TXCLK	CPU.[GMII1_TXCLK/UART2_RXD/RGMII1_TCLK/MMC0_DAT7/MMC1_DAT0/UART1_DCDN/MCASP0_ACLKX/GPIO3_9]	K18	VAUX2	IO
178	NC Optional routing: DDR_VDDS						By default, this pin must not be connected. Optionally, it can route power voltages generated by Diva PSU. This option is meant to allow monitoring of such voltages by carrier board circuitry. It is not meant to power carrier board devices. As these options requires custom manufacturing BOMs, please contact the Sales Department for more information.
179	PMIC_CLK32OUT	PMIC.CLK32KOUT	PMIC.38	VAUX33	O
180	OUT_VAUX33	PMIC.VAUX33	PMIC.4	VAUX33	O		This signal can be used to synchronize powering on/off of carrier board circuitry that interfaces CPU I/O directly. Please refer to section PSU and recommended power up sequence.
181	DGND				G
182	NC Optional routing: VMMC						By default, this pin must not be connected. Optionally, it can route power voltages generated by Diva PSU. This option is meant to allow monitoring of such voltages by carrier board circuitry. It is not meant to power carrier board devices. As these options requires custom manufacturing BOMs, please contact the Sales Department for more information.
183	PMIC_PWR_EN	CPU.PMIC_PWR_EN, PMIC.PWRHOLD	CPU.C6, PMIC.1	VRTC	O
184	NC Optional routing: 3.3V						By default, this pin must not be connected. Optionally, it can route power voltages generated by Diva PSU. This option is meant to allow monitoring of such voltages by carrier board circuitry. It is not meant to power carrier board devices. As these options requires custom manufacturing BOMs, please contact the Sales Department for more information.
185	PMIC_INT1	PMIC.INT1	PMIC.45	VAUX33	O
186	VIN				S
187	PMIC_SLEEP	PMIC.SLEEP	PMIC.37	VAUX33	I
188	VIN				S
189	PMIC_PWRON	PMIC.PWRON	PMIC.33	VIN	I	10kΩ ↑
190	VIN				S
191	PMIC_nRESPWRON	PMIC.nRESPWRON	PMIC.40	VAUX33	O	10kΩ ↓
192	DGND				G
193	MRSTn			3.3V	I	10kΩ ↑	Internally connected to PORSTn with logic port
194	VIN				S
195	RTC_PWRONRSTn	CPU.RTC_PWRONRSTn	B5	VRTC	I	100kΩ ↓	Internally connected to VRTC with logic port
196	VIN				S
197	WARMRSTn	CPU.WARMRSTn	A10	VAUX2	O	10kΩ ↑	Internally connected to NOR flash and ETH PHY
198	VIN				S
199	EXT_PORSTn			3.3V	I	10kΩ ↑	Internally connected to PORSTn_OUT with logic port
200	VIN				S
201	DGND				G
202	VIN				S
203	PMIC_VBACKUP	PMIC.VBACKUP	27	VBACKUP	S		Short to VIN if No not used
204	VIN				S

Peripheral interfaces[edit | edit source]

Diva modules implement a number of peripheral interfaces routed through the SO-DIMM connector. The following notes apply to those interfaces:

• Some interfaces/signals are available only with/without certain configuration options of the Diva module. Each signal’s availability is noted in the “Notes” column on each interface's table.

The signals for each interface are described in the related tables. The following notes summarize the column headers for these tables:

• “Pin name” – The interface signal name
• “Conn. Pin” – The pin number on the module connectors
• “Function” – Signal description
• “Notes” – This column summarizes configuration requirements and recommendations for each signal.

Programmable Real-Time Unit and Industrial Communication Subsystem[edit | edit source]

The Programmable Real-Time Unit and Industrial Communication Subsystem (PRU-ICSS) consists of dual 32-bit RISC cores (Programmable Real-Time Units, or PRUs), memories, interrupt controller, and internal peripherals that enable additional peripheral interfaces and protocols. The programmable nature of the PRUs, along with their access to pins and events, provide flexibility in implementing custom peripheral interfaces, fast real-time responses, power saving techniques, specialized data handling and DMA operations, and in offloading tasks from the other processor cores of the system-on-chip (SoC).

Among the interfaces supported by the PRU-ICSS are the real-time industrial protocols used in master and slave mode, such as:

• EtherCAT®
• PROFINET
• EtherNet/IP™
• PROFIBUS
• POWERLINK
• SERCOS III

The PRU subsystem includes the following main features:

• Two PRUs each with:
  • 8KB program memory
  • 8KB data memory
  • High Performance Interface/OCP Master port for accessing external memories
  • Enhanced GPIO (EGPIO) with async capture and serial support
• 12 KB general purpose shared memory
• One Interrupt Controller (INTC)
  • Up to 64 input events supported
  • Interrupt mapping to 10 interrupt channels
  • 10 Host interrupts (2 to PRU0 and PRU1, 8 output to chip level)
  • Each system event can be enabled and disabled
  • Each host event can be enabled and disabled
  • Hardware prioritization of events
• 16 software Events generation by 2 PRUs
• One Ethernet MII_RT module with two MII ports and configurable connections to PRUs*
• One MDIO Port*
• One Industrial Ethernet Peripheral (IEP) to manage/generate Industrial Ethernet functions
  • One Industrial Ethernet timer with 10 capture* and eight compare events
  • Two Industrial Ethernet sync signals*
  • Two Industrial Ethernet 16-bit watchdog timers*
  • Industrial Ethernet digital IOs*
• One 16550-compatible UART with a dedicated 192-MHz clock
• One Enhanced Capture Module (ECAP)
• Flexible power management support
• Integrated switched central resource (SCR) bus for connecting the various internal and external masters to the resources inside the PRU-ICSS
• Interface/OCP Slave port for external masters to access PRU-ICSS memories
• Optional address translation for PRU transaction to External Host
• All memories within the PRU-ICSS support parity

PRU signals[edit | edit source]

All the PRU signals are routed to the J1 connector, although they are multiplexed with other signals. Please refer to the AM335x datasheet and PRU-ICSS Reference Guide for more information about PRU pinout, configuration and usage.

Ethernet ports[edit | edit source]

The AM335x 3PSW (Three Port Switch) Ethernet Subsystem provides ethernet packet communication and can be configured as an ethernet switch. It provides the gigabit media independent interface (GMII), reduced gigabit media independent interface (RGMII), reduced media independent interface (RMII), the management data input output (MDIO) for physical layer device (PHY) management. Diva provides two ethernet ports, one Fast Ethernet with on-board PHY, and one Gigabit class MAC interface (GMII ??).

Ethernet 10/100[edit | edit source]

On-board Ethernet PHY (SMSC LAN8710Ai) provides interface signals required to implement the 10/100 Ethernet port. It is connected to processor EMAC0 controller through RMII interface. The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
ETH_CTTD	J1.139	Tx Center Tap
ETH_CTRD	J1.143	Rx Center Tap
ETH_TX-	J1.145	Transmit Negative channel
ETH_TX+	J1.147	Transmit Positive channel
ETH_RX-	J1.149	Receive Negative channel
ETH_RX+	J1.151	Receive Positive channel
EMAC0_PHY_LED_LINK/ACT	J1.155	Link activity LED Indication
EMAC0_PHY_LED_SPEED	J1.153	Link Speed LED Indication

Gigabit EMAC[edit | edit source]

Diva provides a Gigabit class ethernet interface connected to processor EMAC1 controller through RGMII interface. When required, an external PHY must be mounted on the carrier board. The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
RGMII2_RCLK	J1.44	RGMII Receive Clock
RGMII2_RCTL	J1.30	RGMII Receive Control
RGMII2_RD0	J1.54	RGMII Receive Data bit 0
RGMII2_RD1	J1.50	RGMII Receive Data bit 1
RGMII2_RD2	J1.48	RGMII Receive Data bit 2
RGMII2_RD3	J1.46	RGMII Receive Data bit 3
RGMII2_TCLK	J1.42	RGMII Transmit Clock
RGMII2_TCTL	J1.28	RGMII Transmit Control
RGMII2_TD0	J1.40	RGMII Transmit Data bit 0
RGMII2_TD1	J1.38	RGMII Transmit Data bit 1
RGMII2_TD2	J1.36	RGMII Transmit Data bit 2
RGMII2_TD3	J1.34	RGMII Transmit Data bit 3

UART ports[edit | edit source]

Up to six UART ports (UART0 – UART5) are routed to Diva connectors. UART0 provides wakeup capability. Only UART 1 provides full modem control signals. All UARTs support IrDA and CIR modes and RTS/CTS flow control (subject to pin muxing configuration).

UART0[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
UART0_TXD	J1.25	UART0 Transmit data
UART0_RXD	J1.27	UART0 Receive data
UART0_CTSn	J1.31	UART0 Clear To Send
UART0_RTSn	J1.29	UART0 Request To Send

UART1[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
UART1_TXD	J1.33	UART1 Transmit data
UART1_RXD	J1.35	UART1 Receive data
UART1_CTSn	J1.39	UART1 Clear To Send
UART1_RTSn	J1.37	UART1 Request To Send
UART1_DCDn	J1.111 J1.177	UART1 Data Carrier Detect
UART1_DSRn	J1.113 J1.175	UART1 Data Set Ready
UART1_DTRn	J1.115 J1.171	UART1 Data Terminal Ready
UART1_RIn	J1.117 J1.173	UART1 Ring Indicator

UART2[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
UART2_TXD	J1.45 J1.119 J1.175	UART2 Transmit data
UART2_RXD	J1.43 J1.123 J1.177	UART2 Receive data
UART2_CTSn	J1.5 J1.118	UART2 Clear To Send
UART2_RTSn	J1.3 J1.120	UART2 Request To Send

UART3[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
UART3_TXD	J1.109 J1.117 J1.173	UART3 Transmit data
UART3_RXD	J1.51 J1.115 J1.171	UART3 Receive data
UART3_CTSn	J1.122 J1.123 J1.167	UART3 Clear To Send
UART3_RTSn	J1.119 J1.124 J1.165	UART3 Request To Send

UART4[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
UART4_TXD	J1.2 J1.29 J1.159	UART4 Transmit data
UART4_RXD	J1.26 J1.31 J1.157	UART4 Receive data
UART4_CTSn	J1.111 J1.126	UART4 Clear To Send
UART4_RTSn	J1.113 J1.128	UART4 Request To Send

UART5[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
UART5_TXD	J1.23 J1.118 J1.163 J1.165	UART5 Transmit data
UART5_RXD	J1.120 J1.130 J1.167 J1.169	UART5 Receive data
UART5_CTSn	J1.115 J1.130	UART5 Clear To Send
UART5_RTSn	J1.117 J1.134	UART5 Request To Send

CAN ports[edit | edit source]

Diva provides two DCAN interfaces (DCAN0 and DCAN1) for supporting distributed realtime control with a high level of security. The DCAN interfaces implement the CAN protocol version 2.0 part A, B and supports bit rates up to 1 Mbit/s.

DCAN0[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
DCAN0_RX	J1.25 J1.37 J1.159	DCAN0 Receive data
DCAN0_TX	J1.27 J1.39 J1.157	DCAN0 Transmit data

DCAN1[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
DCAN1_RX	J1.29 J1.33 J1.119	DCAN1 Receive data
DCAN1_TX	J1.31 J1.35 J1.123	DCAN1 Transmit data

USB ports[edit | edit source]

Diva provides two USB 2.0 (Full Speed, up to 480 Mbps) ports with integrated PHY and support to the On-The-Go (OTG) specifications.

USB port 0[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
USB0_CE	J1.53	USB0 Charger Enable output	Active high
USB0_DM	J1.59	USB0 Data minus
USB0_DP	J1.57	USB0 Data plus
USB0_DRVVBUS	J1.63	USB0 VBUS control output	Active high
USB0_ID	J1.55	USB0 OTG ID
USB0_VBUS	J1.65	USB0 VBUS

USB port 1[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
USB1_CE	J1.73	USB1 Charger Enable output	Active high
USB1_DM	J1.79	USB1 Data minus
USB1_DP	J1.77	USB1 Data plus
USB1_DRVVBUS	J1.83	USB1 VBUS control output	Active high
USB1_ID	J1.75	USB1 OTG ID
USB1_VBUS	J1.85	USB1 VBUS

SD/MMC channels[edit | edit source]

Three standard MMC/SD/SDIO interfaces are available on Diva module. The processor includes 3 MMC/SD/SDIO interface modules which are compliant with MMC V4.3, Secure Digital Part 1 Physical Layer Specification V2.00 and Secure Digital Input Output (SDIO) V2.00 specifications. High capacity SD cards (SDHC) are supported.

SD/MMC/SDIO 0[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
MMC0_CLK	J1.123	MMC/SD/SDIO Clock
MMC0_CMD	J1.119	MMC/SD/SDIO Command
MMC0_DAT0	J1.117	MMC/SD/SDIO Data bus
MMC0_DAT1	J1.115	MMC/SD/SDIO Data bus
MMC0_DAT2	J1.113	MMC/SD/SDIO Data bus
MMC0_DAT3	J1.111	MMC/SD/SDIO Data bus
MMC0_DAT4	J1.173	MMC/SD/SDIO Data bus
MMC0_DAT5	J1.171	MMC/SD/SDIO Data bus
MMC0_DAT6	J1.175	MMC/SD/SDIO Data bus
MMC0_DAT7	J1.177	MMC/SD/SDIO Data bus
MMC0_POW	J1.51 J1.23	MMC/SD Power switch control
MMC0_SDCD	J1.51 J1.150 J1.167	MMC/SD Card Detect
MMC0_SDWP	J1.109 J1.146 J1.165	MMC/SD Write Protect

SD/MMC/SDIO 1[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
MMC1_CLK	J1.6 J1.165	MMC/SD/SDIO Clock
MMC1_CMD	J1.8 J1.167	MMC/SD/SDIO Command
MMC1_DAT0	J1.56 J1.74 J1.177	MMC/SD/SDIO Data bus
MMC1_DAT1	J1.58 J1.76 J1.175	MMC/SD/SDIO Data bus
MMC1_DAT2	J1.60 J1.78 J1.171	MMC/SD/SDIO Data bus
MMC1_DAT3	J1.62 J1.80 J1.173	MMC/SD/SDIO Data bus
MMC1_DAT4	J1.64 J1.82	MMC/SD/SDIO Data bus
MMC1_DAT5	J1.66 J1.84	MMC/SD/SDIO Data bus
MMC1_DAT6	J1.68 J1.86	MMC/SD/SDIO Data bus
MMC1_DAT7	J1.70 J1.88	MMC/SD/SDIO Data bus
MMC1_SDCD	J1.26 J1.140	MMC/SD Card Detect
MMC1_SDWP	J1.35 J1.47	MMC/SD Write Protect

SD/MMC/SDIO 2[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
MMC2_CLK	J1.14 J1.165	MMC/SD/SDIO Clock
MMC2_CMD	J1.10 J1.167	MMC/SD/SDIO Command
MMC2_DAT0	J1.30 J1.82 J1.163	MMC/SD/SDIO Data bus
MMC2_DAT1	J1.34 J1.84 J1.157	MMC/SD/SDIO Data bus
MMC2_DAT2	J1.36 J1.86 J1.159	MMC/SD/SDIO Data bus
MMC2_DAT3	J1.24 J1.88 J1.169	MMC/SD/SDIO Data bus
MMC2_DAT4	J1.42 J1.74	MMC/SD/SDIO Data bus
MMC2_DAT5	J1.44 J1.76	MMC/SD/SDIO Data bus
MMC2_DAT6	J1.46 J1.78	MMC/SD/SDIO Data bus
MMC2_DAT7	J1.48 J1.80	MMC/SD/SDIO Data bus
MMC2_SDCD	J1.2 J1.142	MMC/SD Card Detect
MMC2_SDWP	J1.33 J1.49	MMC/SD Write Protect

LCD controller[edit | edit source]

The AM335x integrates an LCD Controller which provides support for up to 24-bit data output (RGB, 8 bits-per-pixel) and up to WXGA (1366x768) resolution. It can drive Character, STN, TFT and OLED panels. The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
LCD_AC_BIAS_EN	J1.98	LCD AC bias enable chip select
LCD_DATA0	J1.100	LCD Data bus
LCD_DATA1	J1.102	LCD Data bus
LCD_DATA2	J1.104	LCD Data bus
LCD_DATA3	J1.106	LCD Data bus
LCD_DATA4	J1.108	LCD Data bus
LCD_DATA5	J1.110	LCD Data bus
LCD_DATA6	J1.114	LCD Data bus
LCD_DATA7	J1.116	LCD Data bus
LCD_DATA8	J1.118	LCD Data bus
LCD_DATA9	J1.120	LCD Data bus
LCD_DATA10	J1.122	LCD Data bus
LCD_DATA11	J1.124	LCD Data bus
LCD_DATA12	J1.126	LCD Data bus
LCD_DATA13	J1.128	LCD Data bus
LCD_DATA14	J1.130	LCD Data bus
LCD_DATA15	J1.134	LCD Data bus
LCD_DATA16	J1.88	LCD Data bus
LCD_DATA17	J1.86	LCD Data bus
LCD_DATA18	J1.84	LCD Data bus
LCD_DATA19	J1.82	LCD Data bus
LCD_DATA20	J1.80	LCD Data bus
LCD_DATA21	J1.78	LCD Data bus
LCD_DATA22	J1.76	LCD Data bus
LCD_DATA23	J1.74	LCD Data bus
LCD_HSYNC	J1.96	LCD Horizontal Sync
LCD_MEMORY_CLK	J1.14 J1.163	LCD MCLK
LCD_PCLK	J1.90	LCD pixel clock
LCD_VSYNC	J1.94	LCD Vertical Sync

Touch screen / ADC[edit | edit source]

The AM335x processor provides a touchscreen controller and analog-to-digital converter subsystem (TSC_ADC_SS), which is an 8-channel general-purpose analog-to-digital converter (ADC) with optional support for Touch screens. The TSC_ADC_SS can be configured for use in one of the following applications:

• 8 general-purpose ADC channels
• 4-wire TSC with 4 general-purpose ADC channels
• 5-wire TSC with 3 general-purpose ADC channels
• 8-wire TSC

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
AIN0	J1.87	Analog Input/Output
AIN1	J1.89	Analog Input/Output
AIN2	J1.91	Analog Input/Output
AIN3	J1.95	Analog Input/Output
AIN4	J1.97	Analog Input/Output
AIN5	J1.99	Analog Input
AIN6	J1.103	Analog Input
AIN7	J1.105	Analog Input
AGND_TSC	J1.93 J1.101 J1.107	Analog TSC ground

I2C buses[edit | edit source]

Up to three I2C channels are available on Diva to provide an interface to other devices compliant with Philips Semiconductors Inter-IC bus (I2C-bus™) specification version 2.1. External components attached to this 2-wire serial bus can transmit/receive 8-bit data to/from the device through the I2C module. The I2C ports support standard (up to 100 Kbps) and fast (up to 400 Kbps) modes; the controller supports the multi-master mode that allows more than one device capable of controlling the bus to be connected to it.

I2C channel 0[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
I2C0_SCL	I2C0 clock	J1.3	Internally connected to a 10K pull-up resistor
I2C0_SDA	I2C0 data	J1.5	Internally connected to a 10K pull-up resistor

I2C channel 1[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
I2C1_SCL	I2C1 clock	J1.29 J1.33 J1.49	No pull-up/pull-down
I2C1_SDA	I2C1 data	J1.31 J1.35 J1.47	No pull-up/pull-down

I2C channel 2[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
I2C2_SCL	I2C2 clock	J1.25 J1.37 J1.45	No pull-up/pull-down
I2C2_SDA	I2C2 data	J1.27 J1.39 J1.43	No pull-up/pull-down

EEPROM[edit | edit source]

One EEPROM is available to provide additional non-volatile storage area for user-specific usage. It is connected to the I2C-0 bus. A1 and A0 bits of address can be configured at carrier board level. Device address is 10100[A1][A0]b. The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
EEPROM_A0	J1.17	I²C Address pin	A0 address bit can be configured at carrier board level
EEPROM_A1	J1.15	I²C Address pin	A1 address bit can be configured at carrier board level
EEPROM_WP	J1.13	Write protect	Active high

SPI buses[edit | edit source]

Up to two SPI channels are available on Diva, to allow for a duplex, synchronous, serial communication between a CPU and SPI compliant external devices (Slaves and Masters). Each port has a maximum supported frequency of 48 MHz and provides 2 chip selects. Communication parameters (frequency, polarity, phase) are programmable.

SPI channel 0[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
SPI0_CS0	J1.49	SPI0 Chip Select #0
SPI0_CS1	J1.51	SPI0 Chip Select #1
SPI0_D0	J1.45	SPI0 data
SPI0_D1	J1.47	SPI0 data
SPI0_SCLK	J1.43	SPI0 clock

SPI channel 1[edit | edit source]

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
SPI1_CS0	J1.27 J1.29 J1.39 J1.144	SPI1 Chip Select #0
SPI1_CS1	J1.25 J1.37 J1.69 J1.109	SPI1 Chip Select #1
SPI1_D0	J1.31 J1.140	SPI1 data
SPI1_D1	J1.29 J1.142	SPI1 data
SPI1_SCLK	J1.109 J1.150 J1.169	SPI1 clock

Local bus (GPMC)[edit | edit source]

The general-purpose memory controller (GPMC) is an unified memory controller dedicated to interfacing external memory devices:

• Asynchronous SRAM-like memories and application-specific integrated circuit (ASIC) devices
• Asynchronous, synchronous, and page mode (only available in non-multiplexed mode) burst NOR flash devices
• NAND Flash (with BCH and Hamming Error Code Detection)
• Pseudo-SRAM devices

GPMC offers support for the following memory types:

• External asynchronous or synchronous 8-bit width memory or device (non burst device)
• External asynchronous or synchronous 16-bit width memory or device
• External 16-bit non-multiplexed NOR Flash device
• External 16-bit address and data multiplexed NOR Flash device
• External 8-bit and 16-bit NAND flash device
• External 16-bit pSRAM device

The following table describes the interface signals:

Pin name	Connector pin	Function	Notes
GPMC_A0	J1.28 J1.100	GPMC Address bit 0
GPMC_A1	J1.30 J1.94 J1.102	GPMC Address bit 1
GPMC_A2	J1.34 J1.96 J1.104	GPMC Address bit 2
GPMC_A3	J1.10 J1.36 J1.106	GPMC Address bit 3
GPMC_A4	J1.38 J1.108	GPMC Address bit 4
GPMC_A5	J1.40 J1.110	GPMC Address bit 5
GPMC_A6	J1.42 J1.114	GPMC Address bit 6
GPMC_A7	J1.44 J1.116	GPMC Address bit 7
GPMC_A8	J1.46 J1.94	GPMC Address bit 8
GPMC_A9	J1.48 J1.96	GPMC Address bit 9
GPMC_A10	J1.50 J1.90	GPMC Address bit 10
GPMC_A11	J1.54 J1.98	GPMC Address bit 11
GPMC_A12	J1.118	GPMC Address bit 12
GPMC_A13	J1.120	GPMC Address bit 13
GPMC_A14	J1.122	GPMC Address bit 14
GPMC_A15	J1.124	GPMC Address bit 15
GPMC_A16	J1.28 J1.126	GPMC Address bit 16
GPMC_A17	J1.30 J1.128	GPMC Address bit 17
GPMC_A18	J1.34 J1.130	GPMC Address bit 18
GPMC_A19	J1.36 J1.134	GPMC Address bit 19
GPMC_A20	J1.38 J1.111	GPMC Address bit 20
GPMC_A21	J1.40 J1.113	GPMC Address bit 21
GPMC_A22	J1.42 J1.115	GPMC Address bit 22
GPMC_A23	J1.44 J1.117	GPMC Address bit 23
GPMC_A24	J1.46 J1.123	GPMC Address bit 24
GPMC_A25	J1.48 J1.119	GPMC Address bit 25
GPMC_A26	J1.50	GPMC Address bit 26
GPMC_A27	J1.54	GPMC Address bit 27
GPMC_AD0	J1.56	GPMC Address and Data bit 0
GPMC_AD1	J1.58	GPMC Address and Data bit 1
GPMC_AD2	J1.60	GPMC Address and Data bit 2
GPMC_AD3	J1.62	GPMC Address and Data bit 3
GPMC_AD4	J1.64	GPMC Address and Data bit 4
GPMC_AD5	J1.66	GPMC Address and Data bit 5
GPMC_AD6	J1.68	GPMC Address and Data bit 6
GPMC_AD7	J1.70	GPMC Address and Data bit 7
GPMC_AD8	J1.74	GPMC Address and Data bit 8
GPMC_AD9	J1.76	GPMC Address and Data bit 9
GPMC_AD10	J1.78	GPMC Address and Data bit 10
GPMC_AD11	J1.80	GPMC Address and Data bit 11
GPMC_AD12	J1.82	GPMC Address and Data bit 12
GPMC_AD13	J1.84	GPMC Address and Data bit 13
GPMC_AD14	J1.86	GPMC Address and Data bit 14
GPMC_AD15	J1.88	GPMC Address and Data bit 15
GPMC_ADVn_ALE	J1.20	GPMC Address Valid / Address Latch Enable
GPMC_BE0n_CLE	J1.22	GPMC Byte Enable 0 / Command Latch Enable
GPMC_BE1n	J1.8 J1.24	GPMC Byte Enable 1
GPMC_CLK	J1.6 J1.14	GPMC Clock
GPMC_CSN0	J1.4	GPMC Chip Select 0
GPMC_CSN1	J1.6	GPMC Chip Select 1
GPMC_CSN2	J1.8	GPMC Chip Select 2
GPMC_CSN3	J1.10	GPMC Chip Select 3
GPMC_CSN4	J1.26	GPMC Chip Select 4
GPMC_CSN5	J1.2	GPMC Chip Select 5
GPMC_CSN6	J1.24	GPMC Chip Select 6
GPMC_DIR	J1.24	GPMC Data Direction
GPMC_OEN_REN	J1.18	GPMC Output / Read Enable
GPMC_WAIT0	J1.26	GPMC Wait 0
GPMC_WAIT1	J1.14	GPMC Wait 1
GPMC_WEN	J1.16	GPMC Write Enable
GPMC_WPN	J1.2	GPMC Write Protect

3.3V GPIOs[edit | edit source]

The GPIO peripheral provides general-purpose pins that can be configured as either inputs or outputs, for connections to external devices. In addition, the GPIO peripheral can produce CPU interrupts in different interrupt generation modes. The device contains four 3.3 V GPIO modules, for up to 118 pins (GP0[0:31], GP1[0:31], GP2[0:31], and GP3[0:21]). Each channel must be properly configured, since GPIO signals are multiplexed with other interfaces signals.

Operational Characteristics[edit | edit source]

Maximum ratings[edit | edit source]

Parameter	Min	Typ	Max	Unit
Main power supply voltage	3.6	5.0	5.5	V

Recommended ratings[edit | edit source]

Parameter	Min	Typ	Max	Unit
Main power supply voltage	3.6	5.0	5.5	V

Power consumption[edit | edit source]

The use case here presented should cover a worst-case scenario. So, actual customer application might require less power than values reported here. Generally speaking, application specific requirements have to be taken into consideration in order to size power supply unit and to implement thermal management properly. Please note that Diva platform is so flexible that it is virtually impossible to test for all possible configurations and applications on the market.

Set 1[edit | edit source]

Measurements have been performed on the following platform:

• Diva SOM @ 5V
• CPU frequency: 800 MHz
• Carrier board: DivaEVB-Lite on DACU
• System software: DIVELK preliminary version

The test bench runs a stress test suite, comprising several processes:

• burnCortexA8 in continuous loop
• MEMTest: memtester 6M 1 with logddrXXX.txt
• USB:
  • mount
  • head -c 10485760 /dev/urandom
  • md5sum
  • copy
  • md5sum
  • diff md5
  • remount
  • md5sum
  • diff md5
  • umount
• NAND: mtd13 mtd14
  • flash_erase
  • nandbadcount /dev/mtd
• slide_show with fbi

Results[edit | edit source]

With this test bench, the CPU load is always 100% and many components are active at the same time, so this is a non-realistic worst case scenario. The average measured power consumption is 2.6 W.

Application notes[edit | edit source]

Please refer to the following documents available on DAVE Embedded Systems Developers Wiki:

• Carrier_board_design_guidelines_(SOM)
• Integration_guide_(Diva)