Page History

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5V barrel jack, J12
RJ-45 Gigabit Ethernet MegJack, J3
RJ-45 10/100-BaseT Ethernet MegJack, J4
RJ-45 10/100-BaseT Ethernet MegJack, J5
VG96 connector placeholder, J9
XMOD (TE0790) header, JB3
2-pin header for VBAT-IN supply-voltage, J2
2x6 pin header for setting VCCIO_33, J6
2x6 pin header for setting VCCIO_13, J7
MicroSD Card socket, J1
Red LED, D1
Push Button, S1
Micro USB2.0 B Receptacle
VG96 connector placeholder, J8
B2B Connector, JB1
B2B Connector, JB2
4-bit DIP-switch, S2

Initial Delivery State

Storage device name	Content	Notes
Configuration EEPROM, U1	Empty	Not programmed
Configuration EEPROM, U2	Empty	Not programmed

Table 1: Initial delivery state of programmable devices on the module.

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Following table gives a summary of the available I/O's, interfaces and LVDS-pairs of the B2B connectors JB1 and JB2:

VG96 Connector Designator

Count of IO's

Count of LVDS-pairs

Available VCCIO's

Interfaces

Notes

JB1

72

48

1.8V, 2.5V

-

JB2

64

5

VCCIO_13, VCCIO_33
3.3V

I²C,
SD IO,
UART,
USB2.0,
2x 10/100-BaseT Ethernet,
GbE MDI and SGMII,
JTAG

The 5 LVDS-pairs on connector JB2 have
the prefix 'DISP' in the schematic net names.

The I²C, SD IO and the UART interface pins are connected
to MIO-pins of the mounted Zynq-SoM, so this pins can also be
used for user and general purposes.

Table 2: General overview of PL I/O signals and SoM's interfaces connected to the B2B connectors.

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Following table gives a summary of the pin-assignment, available interfaces and functional IO's of the VG96 connectors J8 and J9:

VG96 Connector	Count of IO's	Count of LVDS-pairs	Interfaces	SoM Control Signals	Notes
J8	72	48	-	-	-
J9	64	5	I²C GbE SGMII	'NRST_IN', pin J9-A29	Drive to ground (Push Button S1, JB3-11 (G) on XMOD header) to reset the SoM. ¹⁾
				'NRST_OUT', pin J9-B30	Incoming reset signal from SoM's watchdog (implemented on SoM's SC CPLD). ¹⁾
				'BOARD_STAT', pin J9-B32	Frequently flipping signal indicating running SoM. Routed also to XMOD Header, pin JB3-9 (E).
				'BOOT_MODE1', pin J9-C31	Bootmode pin 1, use in conjunction with Bootmode pin 2.
				'BOOT_MODE2', pin J9-C32	Bootmode pin 2, use in conjunction with Bootmode pin 1.

Table 3: General overview of PL I/O signals, SoM's interfaces and control signals connected to the VG96 connectors.

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JTAG access to the mounted SoM is provided through B2B connector JB2 and is also routed to the XMOD header JB3. With the TE0790 XMOD USB2.0 to JTAG adapter, the Zynq chip on the mounted SoM can be programed via USB2.0 interface.

JTAG Signal	B2B Connector Pin	XMOD Header JB3	Note
TCK	JB2-119	JB3-4	-
TDI	JB2-115	JB3-10	-
TDO	JB2-117	JB3-8	-
TMS	JB2-113	JB3-12	-
JTAGSEL	JB2-111	-	Select SoM's programming mode on DIP-switch S2-1.

Table 4: JTAG interface signals.

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UART interface is available on B2B connector JB2. With the TE0790 XMOD USB2.0 adapter, the UART signals can be converted to USB2.0 interface signals:

UART Signal Schematic Name	B2B	XMOD Header JB3	Note
USART0_RX	JB2-94	JB3-7	UART receive line
USART0_TX	JB2-96	JB3-3	UART transmit line

Table 5: UART interface signals.

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Two I²C interfaces are provided on B2B connector JB2. I²C0 interface is connected to the Configuration EEPROMs U1 and U2 and is dedicated to these on-board peripherals. Interface I²C1 is routed to the VG96 connector J9 and is available to the user for general purposes:

I²C Signal Schematic Name	B2B	Connected to	Note
I2C0_SDA	JB2-90	EEPROMs U1, U2	I²C data line
I2C0_SCL	JB2-92	EEPROMs U1, U2	I²C clock line
I2C1_SDA	JB2-93	J9-A30	I²C data line
I2C1_SCL	JB2-95	J9-A31	I²C clock line

Table 6: I²C interface signals.

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The SD IO interface of the SoM's Zynq chip (MIO-bank) is routed to the on-board MicroSD Card socket J1. By this interface, the Zynq chip can be booted from an inserted MicroSD Card:

SD IO Signal Schematic Name	B2B	Connected to	Note
ESD_DAT0	JB2-108	J1-7	SD IO data
ESD_DAT1	JB2-110	J1-8	SD IO data
ESD_DAT2	JB2-100	J1-1	SD IO data
ESD_DAT3	JB2-102	J1-2	SD IO data
ESD_CLK	JB2-106	J1-5	SD IO clock
ESD_CMD	JB2-104	J1-3	SD IO command
MIO0	JB2-87	J1-9	Card Detect signal

Table 7: SD IO interface signals.

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Following table gives an overview of the USB2.0 interface signals:

USB2.0 Signal Schematic Name	B2B	Connected to	Note
OTG-D_N	JB2-103	J11-2, (J10-2)	USB2.0 data
OTG-D_P	JB2-101	J11-3, (J10-3)	USB2.0 data
OTG-ID	JB2-109	J11-4	Ground this pin for A-Device (host), left floating this pin for B-Device (peripheral).
VBUS_V_EN	JB2-97	U3, pin 4	Enable USB-VBUS.
USB-VBUS	JB2-107	J11-1, (J10-1)	USB supply voltage in Host mode.
USB_OC	JB2-48, J9-B29	U3, pin 5	USB-VBUS over current signal: current-limit threshold exceeded by the connected USB device in USB Host mode.

Table 8: USB2.0 interface signals and connections.

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The TEB0729 Carrier Board is fitted with one RJ-45 Gigabit Ethernet Magnetic jack J3. The MegJack has two integrated LEDs (both green), its signals are routed as MDI (Media Dependent Interface) to the B2B connector JB2, where they can be accessed by the GbE PHY transceiver of the mounted SoM:

GbE PHY Signal Schematic Name	B2B	Connected to	Notes
PHY_MDI0_P	JB2-84	J3-2	-
PHY_MDI0_N	JB2-82	J3-3	-
PHY_MDI1_P	JB2-78	J3-4	-
PHY_MDI1_N	JB2-76	J3-5	-
PHY_MDI2_P	JB2-72	J3-6	-
PHY_MDI2_N	JB2-70	J3-7	-
PHY_MDI3_P	JB2-66	J3-8	-
PHY_MDI3_N	JB2-64	J3-9	-
PHY_LED0	JB2-59	Green MegJack J3 LED	-
PHY_LED1	JB2-57	Green MegJack J3 LED	-

Table 9: GbE interface signals and connections.

For the same GbE transceiver PHY on the mounted SoM, on the Carrier Board is also a SGMII (Serial Gigabit Media Independent Interface) available. The SGMII pins are available on VG96 connector:

GbE PHY Signal Schematic Name	B2B	Connected to	Notes
SIN_P	JB2-52	J9-A16	-
SIN_N	JB2-54	J9-A17	-
SOUT_P	JB2-58	J9-A19	-
SOUT_N	JB2-60	J9-A20	-

Table 10: GbE SGMII signals and connections.

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The TEB0729 Carrier Board is also fitted with two additional RJ-45 MegJacks providing 10/100-BaseT Ethernet interfaces. This interfaces are routed to the B2B connector JB2

10/100-BaseT PHY Signal Schematic Name	B2B	Connected to	Notes
ETH1_RX_P	JB2-26	J4-3	-
ETH1_RX_N	JB2-28	J4-6	-
ETH1_TX_P	JB2-20	J4-1	-
ETH1_TX_N	JB2-22	J4-2	-
ETH1_CTREF	JB2-30	J4-4, J4-5	Centre Tap Reference point
ETH1_LED0	JB2-34	Yellow MegJack J4 LED	-
ETH1_LED1	JB2-32	Green MegJack J4 LED	-

ETH2_RX_P	JB2-8	J5-3	-
ETH2_RX_N	JB2-10	J5-6	-
ETH2_TX_P	JB2-2	J5-1	-
ETH2_TX_N	JB2-4	J5-2	-
ETH2_CTREF	JB2-18	J5-4, J5-5	Centre Tap Reference point
ETH2_LED0	JB2-16	Yellow MegJack J5 LED	-
ETH2_LED1	JB2-14	Green MegJack J5 LED	-

Table 11: 10/100-BaseT Ethernet interfaces signals and connections.

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Following table describes the signals and interfaces of the XMOD header JB3:

JB3 pin	Signal Schematic Net Name	B2B	Note
C (pin 4)	TCK	JB2-119	-
D (pin 8)	TDO	JB2-117	-
F (pin 10)	TDI	JB2-115	-
H (pin 12)	TMS	JB2-113	-
A (pin 3)	USART0_TX	JB2-96	-
B (pin 7)	USART0_RX	JB2-94	-
E (pin 9)	BOARD_STAT	JB2-112	also connected to VG96 connector pin J9-B32
G (pin 11)	NRST_IN	JB2-89	also connected to VG96 connector pin J9-A29

Table 12: XMOD header signals and connections.

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Table below describes DIP-switch S2 settings for configuration of the mounted SoM:

DIP-switches S2	Signal Schematic Net Name	Function	Note
S2-1	JTAGSEL	Select Zynq chip or SC CPLD programming of mounted SoM

on DIP-switch S2-1.

:

OFF: Zynq chip programming.
ON: SC CPLD programming

Depends also on SoM's SC CPLD firmware configuration.

S2-2

BOOT_MODE1

Select first bit of Zynq

chips bootmode

chip boot mode code	Refer to TE0729 TRM for detailed information about boot modes.
S2-3	BOOT_MODE2	Select second bit of Zynq

chips bootmode

chip boot mode code	-
S2-4	x	x	not used

Table 13: DIP-Switch S2 SoM configuration settings.

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Following table describes how to configure the VCCIO of the SoM's banks with jumpers:

VCCIO vs. voltage levels	VCCIO_13	VCCIO_33	Note
1.8V	J7:1-2	J6:1-2	-
2.5V	J7: 3-4	J6:3-4	-
3.3V	J7: 5-6	J6: 5-6	-

Table 14: VCCIO jumper settings.

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The Carrier Board's push button S1 is connected to the 'NRST_IN' signal of the mounted SoM. The function of the button is to trigger a reset of the mounted SoM by driving the reset-signal 'NRST_IN' to ground.

On-board LEDs

LED	Color	Connected to	Description and Notes
D1	Red	'MIO9', JB2- 88	user LED

Table 15: On-board LEDs.

Power and Power-On Sequence

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The maximum power consumption of a module mainly depends the Carrier Board depends mainly on the mounted SoM's FPGA design running on the FPGAZynq chip.

Xilinx provide a power estimator excel sheets to calculate power consumption. It's also possible to evaluate the power consumption of the developed design with Vivado. See also Trenz Electronic Wiki FAQ.

Power Input	Typical Current
5VIN	TBD*

Table 16: Typical power consumption.

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Figure : Module power-on diagram.

Power Rails

Module Connector (B2B) Designator	VCC / VCCIO	Direction	Pins	Notes
JB1	VIN33	Out	Pin 1, 2, 3, 4, 5, 6	3.3V module supply voltage
	VCCIO_13	Out	Pin 101, 102	PL IO-bank VCCIO
	VCCIO_33	Out	Pin 29, 30	PL IO-bank VCCIO
	3.3V	In	Pin 65, 66	voltage output from module
JB2	1.8V	In	Pin 49	voltage output from module
	2.5V	In	Pin 13	voltage output from module
	USB-VBUS	Out	Pin 107	USB Host supply voltage
	VBAT_IN	Out	Pin 118	RTC buffer voltage

Table 17: Power pin description of B2B Module Connector.

Jumper / Header Designator	VCC / VCCIO	Direction	Pins	Notes
J6	VCCIO_33	Out	Pin 2, 4, 6	-
	1.8V	In	5	-
	2.5V	In	3	-
	3.3V	In	1	-
J7	VCCIO_13	Out	Pin 2, 4, 6	-
	1.8V	In	5	-
	2.5V	In	3	-
	3.3V	In	1	-

Table 18: Power Pin description of VCCIO selection jumper pin header.

Main Power Jack and Pins Designator	VCC / VCCIO	Direction	Pins	Notes
J12	5VIN	In	-	-
J9	5VIN	In	Pin A1, A2	'5VIN' power supply to the Carrier Board as alternative to J12

Table 19: Main Power jack and pins description.

Peripheral Socket Designator	VCC / VCCIO	Direction	Pins	Notes
J10	USB-VBUS	Out	Pin 1	-
J11	USB-VBUS	Out	Pin 1	-
J1	VIN33	Out	Pin 4	MikroSD Card socket VDD

Table 20: Power pin description of peripheral connector.

XMOD Header Designator	VCC / VCCIO	Direction	Pins	Notes
JB3	3.3V	-	Pin 5	not connected
JB3	VIO	In	Pin 6	connected to VIN33

Table 21: Power pin description of XMOD/JTAG Connector.

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NB! Note that here we look at the module as a whole, so you just can't rely only on junction temperature or max voltage of particular SoC or FPGA chip on the module. See examples in the table below.

Module Variant	FPGA / SoC	Operating Temperature	Temperature Range
TE0710-02-35-2CF	XC7A35T-2CSG324C	0°C to +70°C	Commercial
TE0715-04-30-3E	XC7Z030-3SBG485E	0°C to +85°C	Extended
TE0841-01-035-1I	XCKU035-1SFVA784I	–40°C to +85°C	Industrial
..	..	..	..

Table : Module variants.

Technical Specifications

Absolute Maximum Ratings

Parameter	Min	Max	Units	Reference Document
VIN supply voltage			V	-
Storage temperature			°C	-

Table : Module absolute maximum ratings.

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Recommended Operating Conditions

Parameter	Min	Max	Units	Reference Document
VIN supply voltage
Operating temperature

Table : Module recommended operating conditions.

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Hardware Revision History

Date	Revision	Notes	PCN	Documentation Link
-	01	Prototypes

Table : Module hardware revision history.

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Date

Revision

Contributors

Description

Page info

	modified-date
	modified-date
dateFormat	yyyy-MM-dd

Ali Naseri

initial document

Table : Document change history.

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