Template Revision 2.12

  • Module: TRM Name always "TE Series Name" +TRM
    Example: "TE0728 TRM"
  • Carrier: TRM Name usually "TEB Series Name" +TRM
    Example: "TEB0728 TRM"


<!-- tables have all same width (web max 1200px and pdf full page(640px), flexible width or fix width on menu for single column can be used as before) -->
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Important General Note:

  • If some section is configurable and depends on Firmware, please refer to the addition page (for example CPLD). If not available, add note, that this part is configurable
  • Designate all graphics and pictures with a number and a description, Use "Scroll Title" macro

    • Use "Scroll Title" macro for pictures and table labels. Figure number must be set manually at the moment (automatically enumeration is planned by scrollPDF)
      • Figure template:


        Create DrawIO object here: Attention if you copy from other page, objects are only linked.


        image link to the generate DrawIO PNG file of this page. This is a workaround until scroll pdf export bug is fixed



      • Table template:

        • Layout macro can be use for landscape of large tables

      • ExampleComment
        12



    • The anchors of the Scroll Title should be named consistant across TRMs. A incomplete list of examples is given below

      • <type>_<main section>_<name>

        • type: Figure, Table
        • main section:
          • "OV" for Overview
          • "SIP" for Signal Interfaces and Pins,
          • "OBP" for On board Peripherals,
          • "PWR" for Power and Power-On Sequence,
          • "B2B" for Board to Board Connector,
          • "TS" for Technical Specification
          • "VCP" for Variants Currently in Production
          •  "RH" for Revision History
        • name: custom, some fix names, see below
      • Fix names:
        • "Figure_OV_BD" for Block Diagram

        • "Figure_OV_MC" for Main Components

        • "Table_OV_IDS" for Initial Delivery State

        • "Table_PWR_PC" for Power Consumption

        • "Figure_PWR_PD" for Power Distribution
        • "Figure_PWR_PS" for Power Sequence
        • "Figure_PWR_PM" for Power Monitoring
        • "Table_PWR_PR" for Power Rails
        • "Table_PWR_BV" for Bank Voltages
        • "Table_TS_AMR" for Absolute_Maximum_Ratings

        • "Table_TS_ROC" for Recommended_Operating_Conditions

        • "Figure_TS_PD" for Physical_Dimensions
        • "Table_VCP_SO" for TE_Shop_Overview
        • "Table_RH_HRH" for Hardware_Revision_History

        • "Figure_RH_HRN" for Hardware_Revision_Number
        • "Table_RH_DCH" for Document_Change_History
    • Use Anchor in the document: add link macro and add "#<anchorname>
    • Refer to Anchror from external : <page url>#<pagename without space characters>-<anchorname>



-----------------------------------------------------------------------


Note for Download Link of the Scroll ignore macro:


Download PDF version of this document.


Table of Contents

Overview

The Trenz Electronic TE0821 is a powerful 4 x 5 cm MPSoC module integrated with a Xilinx Zynq UltraScale+ MPSoC. In addition, the module is equipped with 2x 1 GB DDR4 SDRAM chip, 4Gb up to 128 Gb eMMC chip,  2x 64 MB flash memory for configuration and data storage, as well as powerful switching power supplies for all required voltages. The module is equipped with a Lattice Mach XO2 CPLD for system controlling. 3x Robust high-speed connectors provide a large number of inputs and outputs.

The highly integrated modules are smaller than a credit card and are offered in several variants at an affordable price-performance ratio. Modules with a 4 x 5 cm form factor are completely mechanically and largely electrically compatible with each other.

All components cover at least the industrial temperature range. The temperature range in which the module can be used depends on the customer design and the selected cooling. Please contact us for special solutions.

Refer to http://trenz.org/te0821-info for the current online version of this manual and other available documentation.

Notes :

Key Features

Note:
 'description: Important components and connector or other Features of the module
→ please sort and indicate assembly options

Key Features'  must be split into 6 main groups for modules and mainboards:

  • SoC/FPGA
    • Package: SFVC784
    • Device: ZU2...ZU5*
    • Engine: CG, EG, EV*
    • Speed: -1LI, -2LE,*, **
    • Temperature: I, E,*, **
  • RAM/Storage
    • Low Power DDR4 on PS
      • Data width: 32bit
      • Size: def. 2GB*
      • Speed:***
    • eMMC
      • Data width: 8Bit
      • size: def. 8GB *
    • QSPI boot Flash in dual parallel mode (size depends on assembly version)
      • Data width: 8bit
      • size: def. 128MB *
    • HyperRAM/Flash (optional, default not assembled)
      • size:*
    • MAC address serial EEPROM with EUI-48™ node identity (Microchip 24AA025E48)
  • On Board
    • Lattice LCMXO2
    • PLL SI5338
    • Gigabit Ethernet transceiver PHY (Marvell Alaska 88E1512)
    • Hi-speed USB2 ULPI transceiver with full OTG support (Microchip USB3320C)
  • Interface
    • 132 x HP PL I/Os (3 banks)
    • ETH
    • USB
    • 4 GTR (for USB3, Sata, PCIe, DP)
    • MIO for UART
    • MIO for SD
    • MIO for PJTAG
    • JTAG
    • Ctrl
  • Power
    • 3.3V-5V Main Input
    • 3.3V Controller Input
    • Variable Bank IO Power Input
  • Dimension
    • 4 cm x 5 cm
  • Notes
    • * depends on assembly version
    • ** also non low power assembly options possible
    • *** depends on used U+ Zynq and DDR4 combination


Key Features'  must be split into 6 main groups for carrier:

  • Modules
    • TE0808, TE807, TE0803,...
  • RAM/Storage
    • E.g. SDRAM, SPI
  • On Board
    • E.g. CPLD, PLL
  • Interface
    • E.g. ETH, USB, B2B, Display port
  • Power
    • E.g. Input supply voltage
  • Dimension


Block Diagram

add drawIO object here.

For more information regarding how to draw a diagram, Please refer to "Diagram Drawing Guidline" .







Main Components

Notes :

  • Picture of the PCB (top and bottom side) with labels of important components
  • Add List below


For more information regarding how to add board photoes, Please refer to "Diagram Drawing Guidline" .






  1. Xilinx ZYNQ UltraScale+ MPSoC, U1
  2. Red LED (ERR_OUT), D3
  3. Green LED (ERR_STATUS), D4
  4. Red LED (DONE), D1
  5. 10/100/1000 Mbps Energy Efficient Ethernet Transceiver, U8
  6. 8Gb DDR4, U2-U3
  7. 512 Mbit QSPI flash memory, U7-U17
  8. Green User LED, D2
  9. B2B connector Samtec Razor Beam, JM1
  10. Programmable clock generator, U10
  11. USB2.0 Transceiver,  U18
  12. B2B connector Samtec Razor Beam, JM3
  13. B2B connector Samtec Razor Beam, JM2
  14. 8 GByte eMMC memory, U6
  15. Lattice Semiconductor MachXO2 System Controller CPLD, U21

Additional assembly options are available for cost or performance optimization upon request.

Initial Delivery State

Notes :

Only components like EEPROM, QSPI flash can be initialized by default at manufacture.

If there is no components which might have initial data ( possible on carrier) you must keep the table empty


Storage device name

Content

Notes

Dual QSPI Flash Memory

Not programmed


eMMC Memory

Not programmed


DDR4 SDRAMNot programmed
Programmable Clock GeneratorNot programmed
CPLD (LCMXO2-256HC)ProgrammedTE0821 CPLD


Configuration Signals

  • Overview of Boot Mode, Reset, Enables.

Two different firmware versions are available, one with the QSPI boot option and other with the SD Card boot option.

MODE Pin

Boot Mode
High

QSPI*

LowSD Card*


*changable also with other CPLD Firmware: TE0821 CPLD.


Signal

B2BI/ONote

EN

JM1-28InputCPLD Enable Pin



Signals, Interfaces and Pins

Notes :

  • For carrier or stand-alone boards use subsection for every connector type (add designator on description, not on the subsection title), for example:
    • SD
    • USB
    • ETH
    • FMC
    • ...
  • For modules which needs carrier use only classes and refer to B2B connector if more than one is used, for example
    • JTAG
    • UART
    • I2C
    • MGT
    • ...

Board to Board (B2B) I/Os

FPGA bank number and number of I/O signals connected to the B2B connector:

FPGA BankTypeB2B ConnectorI/O Signal CountVoltage LevelNotes
24HDJM224x I/O, 12x  LVDS PairsVariable Max voltage 3.3V
25HDJM1

24x I/O, 12x  LVDS Pairs

Variable Max voltage 3.3V
26HDJM124x I/O, 12x  LVDS PairsVariable Max voltage 3.3V
44HDJM224x I/O, 12x  LVDS PairsVariableMax voltage 3.3V
65

HP

JM2

18x I/O, 9x LVDS Pairs

VariableMax voltage 1.8V

65

HP

JM3

16x I/O, 8x LVDS Pairs

Variable

Max voltage 1.8V
505GTRJM316x I/O, 8x LVDS Pairs-4x lanes
505GTR CLKJM31x Diff Clock-

501

MIO

JM1

15 I/O

3.3V



For detailed information about the pin-out, please refer to the Pin-out table.

JTAG Interface

JTAG access to the Xilinx Zynq UltraScale+ is applicable by using Lattice MachXO CPLD  through B2B connector JM2.

JTAG Signal

B2B Connector

Note
TMSJM2-93
TDIJM2-95
TDOJM2-97
TCKJM2-99 
JTAGENJM1-89Pulled Low: Xilinx Zynq UltraScale+ MPSoC
Pulled High: Lattice MachXO CPLD


MGT Lanes

There are 4x MGT Lanes connected to FPGA Bank 505-GTR. The Xilinx Zynq UltraScale+ device used on the TE0821 module has 4 GTR transceivers. All 4 are wired directly to B2B connector JM3. MGT (Multi Gigabit Transceiver) lane consists of one transmit and one receive (TX/RX) differential pairs, four signals total per one MGT lane. Following table lists lane number, FPGA bank number, transceiver type, signal schematic name, board-to-board pin connection and FPGA pins connection:

Lane

SchematicB2BNote
0
  • B505_RX0_P
  • B505_RX0_N
  • B505_TX0_P
  • B505_TX0_N
  • JM3-26
  • JM3-28
  • JM3-25
  • JM3-27

1
  • B505_RX1_P
  • B505_RX1_N
  • B505_TX1_P
  • B505_TX1_N
  • JM3-20
  • JM3-22
  • JM3-19
  • JM3-21

2
  • B505_RX2_P
  • B505_RX2_N
  • B505_TX2_P
  • B505_TX2_N
  • JM3-14
  • JM3-16
  • JM3-13
  • JM3-15

3
  • B505_RX2_P
  • B505_RX2_N
  • B505_TX2_P
  • B505_TX2_N
  • JM3-8
  • JM3-10
  • JM3-7
  • JM3-9


Gigabit Ethernet

On-board Gigabit Ethernet PHY is provided with Marvell Alaska 88E1512 chip. The Ethernet PHY RGMII interface is connected to the Zynq Ethernet0 PS GEM0. I/O voltage is fixed at 1.8V for HSTL signaling. SGMII (SFP copper or fiber) can be used directly with the Ethernet PHY, as the SGMII pins are available on the B2B connector JM3. The reference clock input of the PHY is supplied from an on-board 25MHz oscillator (U11), the 125MHz output clock is left unconnected.

PinSchematicConnected toNote
MDIP0...3

PHY_MDI0...3

B2B, JM1


MDC

ETH_MDC

MIO76


MDIOETH_MDIOMIO77
S_INS_INB2B, JM3
S_OUTS_OUTB2B, JM3
TXD0..3ETH_TXD0...3MIO65...68
TX_CTRLETH_TXCTLMIO69
TX_CLKETH_TXCKMIO64
RXD0...3ETH_RXD0...3MIO71...74
RX_CTRLETH_RXCTLMIO75
RX_CLKETH_RXCKMIO70
LED0...2PHY_LED0...2FPGA Bank 66
RESETnETH_RSTMIO24


System Controller CPLD

Special purpose pins are connected to System Controller CPLD and have following default configuration:

Pin NameModeFunctionDefault Configuration
EN1InputPower Enable

No hard wired function on PCB. When forced low, PGOOD goes low without effect on power management

PGOODOutputPower GoodOnly indirect used for power status, see CPLD description
NOSEQ--No used for Power sequencing, see CPLD description
RESINInputReset

Active low reset, gated to POR_B

JTAGENInputJTAG SelectLow for normal operation, high for CPLD JTAG access


Please check the entire information at TE0821 CPLD.

USB Interface

USB PHY is provided by Microchip USB3320. The ULPI interface is connected to the Zynq PS USB0. I/O voltage is fixed at 1.8V. Reference clock input for the USB PHY is supplied by the on-board 52.00 MHz oscillator (U14). 

 PHY PinZYNQ PinB2B NameNotes
ULPIMIO52..63-Zynq USB0 MIO pins are connected to the USB PHY.
REFCLK--52.00 MHz from on-board oscillator (U14).
REFSEL[0..2]--Reference clock frequency select, all set to GND selects 52.00 MHz.
RESETBMIO25-Active low reset.
CLKOUTMIO52-Connected to 1.8V, selects reference clock operation mode.
DP, DM-OTG_D_P, OTG_D_NUSB data lines routed to B2B connector JM3 pins 47 and 49.
CPEN-VBUS_V_ENExternal USB power switch active high enable signal, routed to JM3 pin 17.
VBUS-USB_VBUSConnect to USB VBUS via a series of resistors, see reference schematics, routed to JM3 pin 55.
ID-OTG_IDFor an A-device connect to ground, for a B-device left floating. routed from JM3 pin 23.


I2C Interface

On-board I2C devices are connected to MIO38 (SCL) and MIO39 (SDA) which are configured as I2C0 by default. Addresses for on-board I2C slave devices are listed in the table below:

I2C DeviceI2C AddressNotes

Si5338A PLL

0x70-
EEPROM0x50-


MIO Pins

you must fill the table below with group of MIOs which are connected to a specific components or peripherals, you do not have to specify pins in B2B, Just mention which B2B is connected to MIOs. The rest is clear in the Schematic.

Example:

MIO PinConnected toB2BNotes
MIO12...14

SPI_CS , SPI_DQ0... SPI_DQ3, SPI_SCK

J2QSPI



MIO PinConnected toB2BNotes
0...5QSPI Flash, U7-SPI Flash
7...12QSPI Flash, U17-SPI Flash
13...23eMMC, U6

24ETH Transceiver, U8-ETH_RST
25USB2.0 Transceiver, U18-OTG_RST
26...33User MIOJM1
34...37N.C-N.C
38...39EEPROM, U25-I2C_SDA/SCL
40...45N.C
N.C
46...51SD CardJM1
52...63USB2.0 Transceiver, U18-
63...77Ethernet Transceiver, U8-


Test Points

you must fill the table below with group of Test Point which are indicated as TP in a schematic. If there is no Test Point remarked in the schematic, delet the Test Point section.

Example:

Test PointSignalB2BNotes
10PWR_PL_OKJ2-120



Test PointSignalConnected toNotes
1I2C_SCLEEPROM, U25
2I2C_SDAEEPROM, U25
3SRST_BFPGA Bank 503PSCONFIG
4PS_CLKFPGA Bank 503PSCONFIG
5PROG_BFPGA Bank 503PSCONFIG
6INIT_BFPGA Bank 503PSCONFIG
7DONERed LED, D1
8PS_LP0V85Voltage Regulator, U12
9DDR_2V5Voltage Regulator, U4
10PS_AVCCVoltage Regulator, U9
11DDR_1V2Voltage Regulator, U15
12PS_AVTTVoltage Regulator, U13
13PS_FP0V85Voltage Regulator, U26
14POR_BVoltage Translator, U19
15PS_PLLVoltage Regulator, U23
16PL_VCCINTVoltage Regulator, U5


On-board Peripherals

Notes :

  • add subsection for every component which is important for design, for example:
    • Two 100 Mbit Ethernet Transciever PHY
    • USB PHY
    • Programmable Clock Generator
    • Oscillators
    • eMMCs
    • RTC
    • FTDI
    • ...
    • DIP-Switches
    • Buttons
    • LEDs


Notes :

In the on-board peripheral table "chip/Interface" must be linked to the corresponding chapter or subsection


Chip/InterfaceDesignatorNotes
QSPI FlashU7, U17
EEPROMU25
DDR4 SDRAMU2,U3
GigaBit EthernetU8
USB2.0 TransceiverU18
eMMC MemoryU6
OscillatorsU32, U14, U11
Programmable Clock GeneratorU10
CPLDU21
LEDsD1...3


Quad SPI Flash Memory

Notes :

Minimum and Maximum density of quad SPI flash must be mentioned for other assembly options.

The TE0821 is equipped with dual Flash Memory, U7, U17.  Two quad SPI compatible serial bus flash MT25QU512ABB8E12-0SIT memory chips are provided for FPGA configuration file storage. After configuration completes the remaining free memory can be used for application data storage. All four SPI data lines are connected to the FPGA allowing x1, x2 or x4 data bus widths to be used. The maximum data transfer rate depends on the bus width and clock frequency.

PinSchematicNotes
U7 PinU17 Pin
nCSMIO5MIO7
CLKMIO0MIO12
DI/IO0MIO4MIO8
DO/IO1MIO1MIO9
nHOLD/IO3MIO3MIO11
WP/IO2MIO2MIO10


EEPROM

There is a 2Kb EEPROM provided on the module TE0821.

MIO PinSchematicU25 PinNotes
MIO39I2C_SDASDA
MIO38I2C_SCLSCL



MIO PinI2C AddressDesignatorNotes
MIO38...390x50U25


LEDs

DesignatorColorConnected toActive LevelNote
D1RedDONELow
D2GreenUSR_LEDHigh
D3RedERR_OUTHigh
D4GreenERR_STATUSHigh


DDR4 SDRAM

Notes :

Minimum and Maximum density of DDR3 SDRAM must be mentioned for other assembly options. (pay attention to supported address length for DDR3)

The TE0821 SoM has dual 8 Gb volatile DDR4 SDRAM IC for storing user application code and data.

System Controller CPLD

The System Controller CPLD (U21) is provided by Lattice Semiconductor LCMXO2-256HC (MachXO2 product family). It is the central system management unit with module specific firmware installed to monitor and control various signals of the FPGA, on-board peripherals, I/O interfaces and module as a whole.

See also TE0821 System Controller CPLD page

GigaBit Ethernet

On-board Gigabit Ethernet PHY (U8) is provided with Marvell Alaska 88E1512 IC (U8). The Ethernet PHY RGMII interface is connected to the ZynqMP Ethernet3 PS GEM3. I/O voltage is fixed at 1.8V for HSTL signaling. The reference clock input of the PHY is supplied from an on-board 25.00 MHz oscillator (U11).

PinSchematicConnected toNote
MDIP0...3

PHY_MDI0...3

B2B, JM1


MDC

ETH_MDC

MIO76


MDIOETH_MDIOMIO77
S_INS_INB2B, JM3
S_OUTS_OUTB2B, JM3
TXD0..3ETH_TXD0...3MIO65...68
TX_CTRLETH_TXCTLMIO69
TX_CLKETH_TXCKMIO64
RXD0...3ETH_RXD0...3MIO71...74
RX_CTRLETH_RXCTLMIO75
RX_CLKETH_RXCKMIO70
LED0...2PHY_LED0...2FPGA Bank 66
RESETnETH_RSTMIO24


USB2.0 Transceiver

Hi-speed USB ULPI PHY (U18) is provided with USB3320 from Microchip. The ULPI interface is connected to the Zynq PS USB0 via MIO52..63, bank 502. The I/O voltage is fixed at 1.8V and PHY reference clock input is supplied from the on-board 52.00 MHz oscillator (U14).

eMMC Flash Memory

eMMC Flash memory device(U6) is connected to the ZynqMP PS MIO bank 500 pins MIO13..MIO23. eMMC chips IS21ES08G-JCLI (FLASH - NAND Speicher-IC (64 Gb x 1) MMC ) is used.

Clock Sources

DesignatorDescriptionFrequencyNote
U11MEMS Oscillator25 MHz
U14MEMS Oscillator52 MHz
U32MEMS Oscillator80 MHz


Programmable Clock Generator

There is a Silicon Labs I2C programmable clock generator Si5338A (U10) chip on the module. It's output frequencies can be programmed using the I2C bus address 0x70 or 0x71. Default address is 0x70, IN4/I2C_LSB pin must be set to high for address 0x71.

A 25.00 MHz oscillator is connected to the pin IN3 and is used to generate the output clocks. The oscillator has its output enable pin permanently connected to 1.8V power rail, thus making output frequency available as soon as 1.8V is present. Three of the Si5338 clock outputs are connected to the FPGA. One is connected to a logic bank and the other two are connected to the GTR banks.

Once running, the frequency and other parameters can be changed by programming the device using the I2C bus connected between the FPGA (master) and clock generator (slave). For this, proper I2C bus logic has to be implemented in FPGA.

U25 PinSignalConnected toDirectionNote

IN0..1

CLK_INJM3IN
IN2CLK_25MOscillator, U11IN
SCLI2C_SCLEEPROM,U25INOUT
SDAI2C_SDAEEPROM,U25INOUT
CLK0CLK0JM3OUT
CLK1B505_CLK3FPGA Bank 505IN
CLK2B505_CLK1FPGA Bank 505IN
CLK3CLK3_N
IN


Power and Power-On Sequence

In 'Power and Power-on Sequence' section there are three important digrams which must be drawn:

  • Power on-sequence
  • Power distribution
  • Voltage monitoring circuit


For more information regarding how to draw diagram, Please refer to "Diagram Drawing Guidline" .


Power Supply

Power supply with minimum current capability of 3 A for system startup is recommended.

Power Consumption

Power Input PinTypical Current
VINTBD*
3.3VINTBD*


* TBD - To Be Determined

Power Distribution Dependencies




Power-On Sequence




Power Rails

Power Rail Name

B2B JM1 Pin

B2B JM2 Pin

B2B JM3 Pin

Direction

Notes
VIN

1, 3, 5

2, 4, 6, 8-InputSupply voltage from the carrier board
3.3V-10, 12-OutputInternal 3.3V voltage level
VCCO_HD25_269,11
-Input0 to 3.3V Voltage
3.3VIN13, 15--InputSupply voltage from the carrier board
1.8V39--OutputInternal 1.8V voltage level
JTAG VREF-91-OutputJTAG reference voltage.
Attention: Net name on schematic is "3.3VIN"
VCCO_HD24_44-7, 9-Input0 to 3.3V Voltage
VCCO_65-5-Input0 to 1.8V Voltage
PSBATT79--Input1.2 to 1.5V Voltage


Bank Voltages

FPGA BankSchematicVoltageNote
Bank 24 HDVCCO_HD24_44Variable Max voltage 3.3V
Bank 25 HDVCCO_HD25_26Variable Max voltage 3.3V
Bank 26 HDVCCO_HD25_26Variable Max voltage 3.3V
Bank 44 HDVCCO_HD24_44VariableMax voltage 3.3V
Bank 64 HPVCCO_64N.CNot Connected
Bank 65 HP

VCCO_65

VariableMax voltage 1.8V
Bank 66 HPVCCO_661.8V
Bank 500 PSMIOVCCO_PSIO0_5001.8V

Bank 501 PSMIO

VCCO_PSIO1_501

3.3V


Bank 502 PSMIOVCCO_PSIO2_5021.8V
Bank 503 PSCONFIGVCCO_PSIO3_5031.8V
Bank 504 PSDDRDDR_1V21.2V



Board to Board Connectors

  • This section is optional and only for modules.
  • use "include page" macro and link to the general B2B connector page of the module series,

    For example: 6 x 6 SoM LSHM B2B Connectors

Technical Specifications

Absolute Maximum Ratings

DescriptionMinMaxUnitNotes

VIN supply voltage

-0.3

7

V

See EN6347QI and TPS82085SIL datasheets
3.3VIN supply voltage-0.13.630VXilinx DS925 and TPS27082L datasheet
PS I/O supply voltage, VCCO_PSIO-0.53.630VXilinx document DS925
PS I/O input voltage-0.5VCCO_PSIO + 0.55VXilinx document DS925
HP I/O bank supply voltage, VCCO-0.52.0VXilinx document DS925
HP I/O bank input voltage-0.55VCCO + 0.55VXilinx document DS925
HD I/O bank supply voltage, VCCO-0.53.4VXilinx document DS925
HD I/O bank input voltage-0.55VCCO + 0.55VXilinx document DS925
PS GTR reference clocks absolute input voltage-0.51.1VXilinx document DS925
PS GTR absolute input voltage-0.51.1VXilinx document DS925

Voltage on SC CPLD pins

-0.5

3.75

V

Lattice Semiconductor MachXO2 datasheet

Storage temperature

-40

+85

°C

See eMMC datasheet


Recommended Operating Conditions

Operating temperature range depends also on customer design and cooling solution. Please contact us for options.

ParameterMinMaxUnitsReference Document
VIN supply voltage3.36VSee TPS82085S datasheet
3.3VIN supply voltage3.33.465VSee LCMXO2-256HC, Xilinx DS925 datasheet
PS I/O supply voltage, VCCO_PSIO1.7103.465VXilinx document DS925
PS I/O input voltage–0.20VCCO_PSIO + 0.20VXilinx document DS925
HP I/O banks supply voltage, VCCO0.9501.9VXilinx document DS925
HP I/O banks input voltage-0.20VCCO + 0.20VXilinx document DS925
HD I/O banks supply voltage, VCCO1.143.4VXilinx document DS925
HD I/O banks input voltage-0.20VCCO + 0.20VXilinx document DS925
Voltage on SC CPLD pins-0.33.6VLattice Semiconductor MachXO2 datasheet
Operating Temperature Range085°CXilinx document DS925, extended grade Zynq temperarure range


Physical Dimensions

PCB thickness: 1.74 mm.

In 'Physical Dimension' section, top and bottom view of module must be inserted, information regarding physical dimensions can be obtained through webpage for product in Shop.Trenz, (Download> Documents> Assembly part) for every SoM.

For Example: for Module TE0728, Physical Dimension information can be captured by snipping tools from the link below:

https://www.trenz-electronic.de/fileadmin/docs/Trenz_Electronic/Modules_and_Module_Carriers/5.2x7.6/TE0745/REV02/Documents/AD-TE0745-02-30-1I.PDF

For more information regarding how to draw diagram, Please refer to "Diagram Drawing Guidline" .






Currently Offered Variants 

Set correct link to the shop page overview table of the product on English and German.

Example for TE0706:

    ENG Page: https://shop.trenz-electronic.de/en/search?sSearch=TE0706

    DEU Page: https://shop.trenz-electronic.de/de/search?sSearch=TE0706


Trenz shop TE0821 overview page
English pageGerman page


Revision History

Hardware Revision History

Set correct links to download  arrier, e.g. TE0706 REV02:

  TE0706-02  ->   https://shop.trenz-electronic.de/Download/?path=Trenz_Electronic/Modules_and_Module_Carriers/4x5/4x5_Carriers/TE0706/REV02/Documents

Note:

  • Date format:  YYYY-MM-DD


DateRevisionChangesDocumentation Link
2019-04-26REV01
  • Initial Release
REV01


Hardware revision number can be found on the PCB board together with the module model number separated by the dash.




Document Change History

  • Note this list must be only updated, if the document is online on public doc!
  • It's semi automatically, so do following
    • Add new row below first

    • Copy "Page Information Macro(date)" Macro-Preview, Metadata Version number, Author Name and description to the empty row. Important Revision number must be the same as the Wiki document revision number Update Metadata = "Page Information Macro (current-version)" Preview+1 and add Author and change description. --> this point is will be deleted on newer pdf export template

    • Metadata is only used of compatibility of older exports


DateRevisionContributorDescription

  • bugfix boot mode

2021-07-05v.61John Hartfiel
  • Update download Link

  • Update Change history
2021-06-07v.59Vadim Yunitski
  • Added missing text in Bank Voltages
  • Fixed typo in Bank Voltages
2020-07-15v.50Pedram Babakhani
  • Initial Release

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all

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