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  • Module: TRM Name always "TE Series Name" +TRM
    Example: "TE0728 TRM"

Template Change history:

DateVersionChangesAuthor

4.2
  • Changes Xilinx to AMD
ED

4.1
  • Minor changes
    • Notes
    • Tables
ED

4.0
  • Rework for smaller TRM which can be generated faster
    • Reduce Signal Interfaces Pin
    • Reduce On Board Perihery
    • Reduce Power
    • Move Configuration Signals from Overview to own section
JH

3.12
  • Version History
    • changed from list to table
  • all
    • changed title-alignment for tables from left to center
ma

3.11
  • update "Recommended Operating Conditions" section


3.1
  • New general notes for temperature range to "Recommended Operating Conditions"


3.02
  • add again fix table of content with workaround to use it for pdf and wiki
  • Export Link for key features examples
    • Notes for different Types (with and without Main FPGA)
  • Export Link for Signals, Interfaces and Pins examples
    • Notes for different Types (Modul, Modul Hypride, Evalboard, Carrier)


3.01
  • remove fix table of content and page layout ( split page layout make trouble with pdf export)
  • changed and add note to signal and interfaces, to on board periphery section
  • ...(not finished)


3.00
  • → separation of Carrier/Module and evaluation kit TRM


2.15
  • add excerpt macro to key features


2.14
  • add fix table of content
  • add table size as macro



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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:

        Scroll Title
        anchorFigure_anchorname
        title-alignmentcenter
        titleText


        Scroll Ignore

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


        Scroll Only

        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

      • Scroll Title
        anchorTable_tablename
        title-alignmentcenter
        titleText

        Scroll Table Layout
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        repeatTableHeadersdefault
        sortByColumn1
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        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>



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


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Note for Download Link of the Scroll ignore macro:


Scroll Ignore

Download PDF version of this document.

Overview

The Trenz Electronic TE0808 is an industrial grade MPSoC SOM integrating an AMD Zynq UltraScale+ MPSoC, DDR4 SDRAM with 64-Bit width data bus connection, SPI Boot Flash memory for configuration and operation, transceivers and powerful switch-mode power supplies for all on-board voltages. A large number of configurable I/Os is provided via rugged high-speed stacking connections in a compact 5.2 cm x 7.6 cm form factor.

Refer to http://trenz.org/te0808-info for the current online version of this manual and other available documentation.

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Notes :

Key Features

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

See examples fro different types <Series Name> TRM Template section examples#%3CSeriesName%3ETRMTemplatesectionexamples-KeyFeatures


Excerpt
  • SoC
    • Device: ZU6 / ZU9 / ZU15 1) 2)
    • Engine: CG / EG  1)
    • Speedgrade: -1 / -2  1)
    • Temperature Range: Extended / Industrial 1)
    • Package: FFVC900
  • RAM/Storage
    • 4 GByte DDR4 SDRAM 3)
    • 2 x 64 MByte Serial Flash 4)
    • EEPROM with MAC address
  • On Board
    • Oscillator
  • Interface
    • 4 x B2B Connector (ST5)
      • up to 204 PL IO

        • HP: 156
        • HD: 48
      • up to 65 PS MIO

      • 4 GTR
      • 16 GTH
      • I2C, JTAG, CONFIG
  • Power
    • 3.3 V power supply via B2B Connector needed 5).
  • Dimension
    • 76 mm x 52 mm
  • Notes
    1) Please, take care of the possible assembly options. Furthermore, check whether the power supply is powerful enough for your FPGA design.
    2) without PCIe Core on PL, see XMP104
    3) Up to 8 GByte are possible with a maximum bandwidth of 2400 MBit/s.
    4) Please, take care of the possible assembly options.
    5) Dependent on the assembly option a higher input voltage may be possible

Block Diagram

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add drawIO object in Scroll Ignore section and add reference image in Scroll Only.

Note

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


Note

Title (not anchor) of all Scroll Title such as DrawIOs and Tables should be changed according to the Module name.

Example: TE0812 Block Diagram


Note

All created DrawIOs  should be named according to the Module name:

Example: DrawIO of TE0812 Block Diagram should be named TE0812_OV_BD



Scroll Title
anchorFigure_OV_BD
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titleTE0808 block diagram


Scroll Ignore

draw.io Diagram
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Image Added


Main Components

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Notes :

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


Note

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



Scroll Title
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titleTE0808 main components


Scroll Ignore

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Image Added


  1. SoC, U1
  2. DDR4, U2, U3, U9, U12
  3. Quad SPI Flash, U7, U17
  4. Connector, J1, J2, J3, J4
  5. EEPROM, U4
  6. Clock Generator, U5
  7. Oscillator, U25, U32
  8. Done LED D1

Initial Delivery State

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Note

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



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titleInitial delivery state of programmable devices on the module

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Storage device name

Content

Notes

DDR4 SDRAMnot programmed
Quad SPI Flashnot programmed
EEPROMnot programmed besides factory programmed MAC address
Programmable Clock Generatornot programmed


Signals, Interfaces and Pins

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For subsection examples see: <Series Name> TRM Template section examples#%3CSeriesName%3ETRMTemplatesectionexamples-Signals,InterfacesandPins

Note
  • Table with all connectors and Designtor
  • List of different interfaces per connector
  • IO CNT (for FPGA IOs where functionality can be changed by customer)


Connectors

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Connector TypeDesignatorInterfaceIO CNTNotes
B2BJM1MGT PL12 x MGT (RX/TX)
B2BJM1HP52 SE / 24 DIFF
B2BJM2MGT PS2 x MGT CLK
B2BJM2CLK4 x DIFF CLKPLL
B2BJM2MGT PL4 x MGT (RX/TX)
B2BJM2MGT PS4 x MGT (RX/TX)
B2BJM2CFG1)1 x JTAG
B2BJM2CFG1)4 x MODE
B2BJM2CFG1)1 x I2CPLL, EEPROM
B2BJM2CFG1)34 CTRL/Status
B2BJM3HD48 SE / 24 DIFF
B2BJM3MGT PL3 x MGT CLK
B2BJM3CLKDIFF CLKPLL
B2BJM3MIO65 PS GPIO
B2BJM4HP104 SE / 48 DIFF

1) see Configuration and System Control Signals


Test Points

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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 PointSignalNotes1)
TP1PWR_PL_OK

1) Direction:

    • IN: Input from the point of view of this board.
    • OUT: Output from the point of view of this board.


Scroll Title
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Test PointSignalNotes
TP1PLL_SCLpulled-up to PS_1V8
TP2PLL_SDApulled-up to PS_1V8
TP3LP_DCDC
TP4DCDCIN
TP5GND
TP6TCK
TP7PL_DCIN
TP8GND
TP9GT_DCDC
TP10GND
TP11TDI
TP12TDO
TP13TMS
TP14PS_1V8
TP15No Net NameREF3312AIDCKT (U33) ouput voltage
TP16FP_0V85
TP17DDR_2V5
TP18DDR_PLL
TP19PL_VCCINT
TP20AUX_R
TP21AVTT_R
TP22AUX_L
TP24AVCC_R
TP26AVTT_L
TP28AVCC_L
TP30PS_PLL
TP31PS_AVTT
TP32LP_0V85
TP33PS_AUX
TP34PS_AVCC
TP36POR_Bpulled-up to PS_1V8


On-board Peripherals

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Notes :

In the on-board peripheral table "chip/Interface" must be linked to the corresponding chapter or subsection by assigning advance link using: #NameOfTheSection

Example:

Chip/InterfaceDesignatorConnected ToNotes
ETH PHYU10
  • B2B connector J1
  • SoC MIO
Gigabit ETH PHY



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Chip/InterfaceDesignatorConnected ToNotes

DDR4 SDRAM

U2, U3, U9, U12SoC - PS

Quad SPI Flash

U7, U17SoC - PSBooting.

EEPROM

U4B2B - J2

Clock Generator

U5B2B - J2
SoC, - MGT

Oscillator

U25Clock Generator25 MHz

Oscillator

U32SoC - PS33.333333 MHz



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For example subsections see: <Series Name> TRM Template section examples#%3CSeriesName%3ETRMTemplatesectionexamples-On-boardPeripherals

Configuration and System Control Signals

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  • Overview  all Controller signals, like Reset, Boote Mode, JTAG Interface(Connector or USB In case of FTDI)...
  • In case it's connected to CPLD always link to CPLD description and add not from the  current implementation here(in case it's available)


Scroll Title
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titleController signal.

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Connector+Pin

Signal Name

Direction1)Description
JM2-77EN_PLL_PWRINEnable PLL power supply.
JM2-79EN_GT_LINEnable left GTH transceiver power-up.
JM2-80PG_PLL_1V8OUTSI_PLL_1V8 power rail powered-up.
JM2-81PLL_FINCINPLL Frequency incrementation.
JM2-82PG_PSGTOUTGTR transceivers powered-up.
JM2-83MRINManual reset.
JM2-84EN_PSGTINEnable GTR transceiver power-up.
JM2-85PLL_LOLnOUTLoss of lock status.
JM2-86ERR_STATUSOUTPS error status 2).
JM2-87PLL_SEL1INPLL clock selection.
JM2-88ERR_OUTOUTPS error indication 2).
JM2-89PLL_RSTINPLL reset.
JM2-90PLL_SCLINI2C clock. Pulled up to PS_1V8.
JM2-91PG_GT_ROUTRight GTH Transceivers powered-up.
JM2-92PLL_SDAIN/OUTI2C data. Pulled up to PS_1V8.
JM2-93PLL_SEL0INPLL clock selection.
JM2-94PLL_FDECINPLL Frequency decrementation.
JM2-95EN_GT_RINEnable right GTH transceiver power-up.
JM2-96SRST_BINSystem reset 2). Pulled-up to PS_1V8.
JM2-97PG_GT_LOUTLeft GTH Transceivers powered-up.
JM2-98INIT_BIN/OUTInitialization completion indicator after POR 2). Pulled-up to PS_1V8.
JM2-100PROG_BIN/OUTPower-on reset 2). Pulled-up to PS_1V8.
JM2-101EN_PLINEnable programable logic power-up.
JM2-102EN_FPDINEnable full-power domain power-up.
JM2-103 / JM2-105 / JM2-107 / JM2-109MODE3..0INBoot mode selection 2):
  • JTAG
  • QUAD-SPI (32 Bit)
  • SD1 (2.0)
  • eMMC (1.8 V)
  • SD1 LS (3.0)

Supported Modes depends also on used Carrier.

JM2-104PG_PLOUTProgrammable logic powered-up. Pulled-up to PL_DCIN.
JM2-106LP_GOODOUTLow-power domain powered-up. Pulled up to LP_DCDC.
JM2-108EN_LPDINEnable low-power domain power-up.
JM2-110PG_FPDOUTFull-power domain powered-up. Pulled-up to DCDCIN.
JM2-112EN_DDRINEnable DDR power-up.
JM2-114PG_DDROUTDDR power supply powered-up. Pulled-up to DCDCIN.
JM2-116DONEOUTPS done signal 2). Pulled-up to PS_1V8.
JM2-119 / JM2-121DX_P / DX_N-SoC temperatur sensing diode pins 2).
JM2-120 / JM2-122 /
JM2-124 / JM2-126
TCK / TDI / TDO / TMSSignal-dependent

JTAG configuration and debugging interface.

JTAG reference voltage: PS_1V8

JM2-125PSBATTINPS RTC Battery supply voltage 2) 3).
JM2-127PUDC_BINConfiguration pull-ups setting 2). Pulled-up to PL_1V8.

1) Direction:

    • IN: Input from the point of view of this board.
    • OUT: Output from the point of view of this board.

2) See UG1085 for additional information.

3) See Recommended Operating Conditions.

Power and Power-On Sequence

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Enter the default value for power supply and startup of the module here.

  • Order of power provided Voltages and Reset/Enable signals

Link to Schematics, for power images or more details


Power Rails

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List of all Powerrails which are accessible by the customer

  • Main Power Rails and Variable Bank Power



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Power Rail Name/ Schematic NameConnector + PinDirection1)Notes
VCCO_66JM1-90 / JM1-120IN
VREF_66JM1-108IN

PL_1V8

JM1-91 / JM1-121OUT
PL_DCINJM1-151 / JM1-153 / JM1-155 / JM1-157 / JM1-159IN
LP_DCDCJM2-138 / JM2-140 / JM2-142 / JM2-144IN
DCDCINJM2-153 / JM2-154 / JM2-155 / JM2-156 / JM2-157 / JM2-158 / JM2-159 / JM2-160IN
PS_1V8JM2-99 / JM3-147 / JM3-148OUT
PS_BATTJM2-125IN
DDR_1V2JM2-135OUT
VCCO_48JM3-15 / JM3-16IN
VCCO_47JM3-43 / JM3-44IN
PLL_3V3JM3-152IN
SI_PLL_1V8JM3-151OUT
GT_DCDCJM3-157 / JM3-158 / JM3-159 / JM3-160IN
VCCO_64JM4-58 / JM4-106IN
VREF_64JM4-88IN
VCCO_65JM4-69 / JM4-105IN
VREF_65JM4-15IN

1) Direction:

    • IN: Input from the point of view of this board.
    • OUT: Output from the point of view of this board.

Recommended Power up Sequencing

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List baseboard design hints for final baseboard development.

The power up sequencing highly depends on the use case. In general, it should be possible to enable/disable the processing system (PS) / programmable logic (PL) independently. Furthermore, within the processing logic it should be possible to enable/disable only low-power domain and/or low-power and full-power domain. Additionally, usage of GTR for PS side and GTH for PL side should be possible. GTH transceivers on left and right side are usable independently. Because of this flexibility the needed parts of the following table needs to be selected individually. For detailed information take a look into schematics. Attention: PL usage is not completely independent of PS side. For PL usage it is necessary to enable PS low-power domain.

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SequenceNet nameRecommended Voltage RangePull-up/downDescriptionNotes
0---Configuration signal setup.See Configuration and System Control Signals.
1 1)PSBATT1.2 V ... 1.5 V-Battery connection.Battery Power Domain usage. When not used, tie to GND.
2Processing System (PS):

Procedure for PS starting.
2.1Low-power domain:Bring-up for low-power domain PS.
2.1.1LP_DCDC3.3 V (± 5 %) 2)-Low-power domain power supply.Main module power supply for low-power domain. 5.5 A recommended. Power consumption depends mainly on design and cooling solution.
2.1.2EN_LPD--Low-power domain power enable.
2.1.3LP_GOOD-PU 3), LP_DCDCLow-power domain power good status.Module power-on sequencing for low-power domain finished.
2.2Full-power domain:Bring-up for full-power domain PS.Full-power PS domain needs powered low-power PS domain.
2.2.1DCDCIN3.3 V (± 5 %) 2)
Full-power domain and GTR transceiver power supply.Main module power supply for full-power domain. 7 A recommended. Power consumption depends mainly on design and cooling solution.
2.2.2EN_FPDDCDCIN-Full-power domain power enable.
2.2.3PG_FPD-PU 3), DCDCINFull-power domain power good status.Module power-on sequencing for full-power domain finished.
2.2.4EN_DDRDCDCIN-DDR memory power enable.
2.2.5PG_DDR-PU 3), DCDCINDDR memory power good status.Module power-on sequencing for DDR memory finished.

2.3

GTR TransceiverProcedure for GTR transceiver starting.PS transceiver usage needs powered PS (low- and full-power domain).
2.3.1EN_PSGTDCDCIN-GTR transceiver power enable.
2.3.2PG_PSGT--GTR transceiver power good status.Module power-on sequencing for GTR transceiver finished.
2Programmable Logic (PL)Procedure for PL starting.PL usage needs powered PS low-power domain.
2.1PL_DCIN3.3 V (± 5 %) 2)-Programmable logic power supply.Main module power supply for programmable logic. 12 A recommended. Power consumption depends mainly on design and cooling solution.
2.2EN_PL-PU 3), PL_DCINProgrammable logic power enable.
2.3PG_PL-PU 3), PL_DCINProgrammable logic power good status.Module power-on sequencing for programmable logic finished. Periphery and variable bank voltages can be enabled on carrier.
2.4VCCO_47 / VCCO_48 / VCCO_64 / VCCO_65 / VCCO_66 4)-Module bank voltages.Enable bank voltages after PG_PL deassertion.
3GTH / GTY TransceiverProcedure for GTH / GTY transceiver starting.PL transceiver usage needs powered PL and low-power PS domain.
3.1GT_DCDC3.3 V (± 5 %) 2)-GTH transceiver power supply.Main module power supply for GTH transceiver. 5 A recommended. Power consumption depends mainly on design and cooling solution.
3.21)EN_PLL_PWR--PLL power enable.
3.21)PG_PLL_1V8--PLL power good status.
3.21)PLL_3V33.3 V (± 5 %)
PLL power supply
3.3EN_GT_L / EN_GT_RGT_DCDC-GTH / GTY left / right transceiver power enable.Transceivers on left / right side can be used independently.
3.4PG_GT_L / PG_GT_R--GTH / GTY transceiver power good status.
4MR

Manual ResetLow active release after all needed power domains are enabled. 

1) Optional

2) Dependent on the assembly option a higher input voltage may be possible. 

3) On module

4) See DS925 for additional information.

Board to Board Connectors

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  • 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

    Include Page
    6 x 6 SoM LSHM B2B Connectors
    6 x 6 SoM LSHM B2B Connectors

Include Page
5.2 x 7.6 UltraSoM+ ST5 and SS5 B2B Connectors
5.2 x 7.6 UltraSoM+ ST5 and SS5 B2B Connectors

Technical Specifications

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List of all Powerrails which are accessible by the customer

  • Main Power Rails and Variable Bank Power add boarder one time maximum Rating (Board will damaged)

Absolute Maximum Ratings *)

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Power Rail Name/ Schematic NameDescriptionMinMaxUnit
LP_DCDCMicromodule Power-0.3004.0V
DCDCINMicromodule Power-0.3006.0V
GT_DCDCMicromodule Power-0.3006.0V
PL_DCINMicromodule Power-0.300

3.6

V
PLL_3V3PLL power supply-0.5003.8V
PS_BATTRTC / BBRAM-0.5002.000V
VCCO_47HD IO Bank power supply-0.5003.400V
VCCO_48HD IO Bank power supply-0.5003.400V
VCCO_64HP IO Bank power supply-0.5002.000V

VCCO_65

HP IO Bank power supply-0.5002.000V
VCCO_66HP IO Bank power supply-0.5002.000V
VREF_64Bank input reference voltage-0.5002.000V
VREF_65Bank input reference voltage-0.5002.000V
VREF_66Bank input reference voltage-0.5002.000V


*) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only, which do not imply functional operation of the device at these
   or any other conditions beyond those indicated under Recommended Operating Condition. Exposure to absolute-maximum rated conditions for extended periods may affect device reliability.

Recommended Operating Conditions

This TRM is generic for all variants. Temperature range can be differ depending on the assembly version.  Voltage range is mostly the same during variants (exceptions are possible, depending on custom request)

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

  • Variants of modules are described here: Article Number Information
  • Modules with commercial temperature grade are equipped with components that cover at least the range of 0°C to 75°C
  • Modules with extended temperature grade are equipped with components that cover at least the range of 0°C to 85°C
  • Modules with industrial temperature grade are equipped with components that cover at least the range of -40°C to 85°C
  • The actual operating temperature range will depend on the FPGA / SoC design / usage and cooling and other variables.


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ParameterMinMaxUnitsReference Document
LP_DCDC 1)3.1353.465V
DCDCIN 1)3.1353.465V
GT_DCDC 1)3.1353.465V
PL_DCIN 1)3.135

3.465

V
PLL_3V33.143.465V
PS_BATT1.2001.500VSee FPGA datasheet.
VCCO_471.1403.400VSee FPGA datasheet.
VCCO_481.1403.400VSee FPGA datasheet.
VCCO_640.9501.900VSee FPGA datasheet.

VCCO_65

0.9501.900VSee FPGA datasheet.
VCCO_660.9501.900VSee FPGA datasheet.
VREF_640.61.2VSee FPGA datasheet.
VREF_650.61.2VSee FPGA datasheet.
VREF_660.61.2VSee FPGA datasheet.

1) Higher values may possible. For more information consult schematic and according datasheets.


Physical Dimensions

  • Module size: 76 mm × 52 mm.  Please download the assembly diagram for exact numbers.

  • Mating height with standard connectors: 5 mm.

PCB thickness: 1.6 mm (± 10 %).

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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

Note

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



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Currently Offered Variants 

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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


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Trenz shop TE0808 overview page
English pageGerman page


Revision History

Hardware Revision History

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

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Note:

  • Date format:  YYYY-MM-DD
  • Example: 

    DateRevisionChangesDocumentation Link
    2020-11-25REV02
    • Resistors R14 and R15 was replaced by 953R (was 5K1)
    • Resistor R5 was replaced by 5K1, R8 by 953R (was 9K09 and 1K69 respectively)
    REV02



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DateRevisionChangesDocumentation Link
-05Second production silicon:
  • revised PL_VCCINT power supply. PCB: revised routing and components placement;
  • added signal BG1 for DDP DDR4 IC. Added support of new packages. PCB: revised routing and components placement;
  • R5 pulled up to 1.2V. R5 value changed to 49.9R;
  • added test points;
  • added MAC EEPROM U48. I2C bus PLL_SCL/SDA. Added pull up resistor to I2C bus;
  • PCB - revised FPGA location. Package placed 1.5mm closer to connector J3;
  • PCB - updated silckscreen. Added company address, CE and WEEE symbols;
  • PCB - updated signal trace lengths.
  • (29.11.2022) Changed note near J2.97 and net PG_GT_L from "On board pull-up R" to "External pull-up R Required"
TE0808-05
-04First production silicon:
  • Added resistors R65,R82,R86,R87 (240R) for each DDR4-chip for supporting DDP DDR4 chips
  • Full library update
  • (09.06.2020) R19 value was changed to 10K (was: 4K99) to set PS_MGTRAVCC 0.85V
TE0808-04
-03Second ES production releaseTE0808-03
2016-03-0902First ES production releaseTE0808-02
-01Prototypes-


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

Document Change History

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 Date

Revision

ContributorsDescription

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  • change default RAM size on key feature section
  • typo and revision history update

2024-09-18

v.48

John Hartfiel

  • Review and Public Update

2023-10-13

v.44

ED 

  • Updated to new TRM style

2022-09-13

v.41Vadim Yunitski
  • Updated PG_PL pull-up resistor requirements
2021-09-07V.39John Hartfiel
  • Correction Power section
2021-05-17v.37John Hartfiel
  • typo correction in DDR section
2021-03-11v.35Antti Lukats
  • typo correction in PLL_RST
  • add pin on power rails table
  • correction MGT Lane assignment
  • correction MGT CLK assignment

2019-01-27

v.30Martin Rohrmüller
  • Corrected clock connection to J2

2018-11-20

v.29

John Hartfiel
  • Notes for power supply

2018-08-27

v.27John Hartfiel
  • typo correction SI5345 I2C address

2028-06-28

v.26John Hartfiel
  • typo SI5348 B2B IOs + link correction

2017-11-13

v.24Ali Naseri
  • updated B2B connector max. current rating per pin

2017-11-13


v.22


John Hartfiel
  • rework B2B section
2017-10-20

v.21

Ali Naseri
  • Update links (pdf, documentation) to revision 4
  • ES silicon note removed
2017-08-28
v.15
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Table of Contents

Table of Contents

Overview

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Refer to https://wiki.trenz-electronic.de/display/PD/TE0808+TRM for downloadable version of this manual and the rest of available documentation.
 

The Trenz Electronic TE0808 is an industrial-grade MPSoC SoM integrating a Xilinx Zynq UltraScale+ MPSoC, up to 8 GBytes of DDR4 SDRAM via 64-bit wide data bus, max. 512 MByte Flash memory for configuration and operation, 20 Gigabit transceivers and powerful switch-mode power supplies for all on-board voltages. A large number of configurable I/Os are provided via rugged high-speed stacking connections. All this in a compact 5.2 x 7.6 cm form factor, at the competitive price.

Key Features

  • MPSoC: ZYNQ UltraScale+ ZU9EG 900 pin package
  • Memory
    - 64-Bit DDR4, 8 GByte maximum
    - Dual SPI boot Flash in parallel, 512 MByte maximum
  • User I/Os
    - 65 x PS MIOs, 48 x PL HD GPIOs,  156 x PL HP GPIOs (3 banks)
    - Serial transceivers: 4 x GTR + 16 x GTH
    - Transceiver clocks inputs and outputs
    - PLL clock generator inputs and outputs
  • Si5345 - 10 output PLL
  • All power supplies on board, single 3.3V power source required
    - 14 on-board DC-DC regulators and 13 LDOs
    - LP, FP, PL separately controlled power domains
  • Support for all boot modes (except NAND) and scenarios
  • Support for any combination of PS connected peripherals
  • Size: 52 x 76 mm, 3 mm mounting holes for skyline heat spreader
  • B2B connectors: 4 x 160 pin

Block Diagram

Image Removed

Figure 1: TE0808-04 Block Diagram.

Main Components

     Image Removed        Image Removed

Figure 2: TE0808 MPSoC module.

  1. Xilinx ZYNQ UltraScale+ XCZU9EG MPSoC, U1
  2. Low-power programmable oscillator @ 33.333333 MHz (PS_CLK), U32
  3. Red LED (DONE), D1
  4. 256Mx16 DDR4-2400 SDRAM, U12
  5. 256Mx16 DDR4-2400 SDRAM, U9
  6. 256Mx16 DDR4-2400 SDRAM, U2
  7. 256Mx16 DDR4-2400 SDRAM, U3
  8. 12A PowerSoC DC-DC converter, U4
  9. Quartz crystal, Y1
  10. Low-power programmable oscillator @ 25.000000 MHz (IN0 for U5), U25
  11. 10-channel programmable PLL clock generator, U5
  12. Ultra fine 0.50 mm pitch, Razor Beam™ LP Slim Terminal Strip with 160 contacts, J4
  13. Ultra fine 0.50 mm pitch, Razor Beam™ LP Slim Terminal Strip with 160 contacts, J2
  14. Ultra fine 0.50 mm pitch, Razor Beam™ LP Slim Terminal Strip with 160 contacts, J3
  15. Ultra fine 0.50 mm pitch, Razor Beam™ LP Slim Terminal Strip with 160 contacts, J1
  16. Quartz crystal, Y2
  17. 256 Mbit serial NOR Flash memory, U7
  18. 256 Mbit serial NOR Flash memory, U17

Initial Delivery State

...

Content

...

Notes

...

SPI Flash main array

...

Not programmed

...

eFUSE Security

...

Not programmed

...

Table 1: Initial Delivery State of the flash memories.

Signals, Interfaces and Pins

Board to Board (B2B) connectors

The TE0808 MPSoC SoM has four Board to Board (B2B) connectors with 160 contacts per connector.

Each connector has a specific arrangement of the signal pins, which are grouped together in categories related to their functionalities and to their belonging to particular units of the Zynq UltraScale+ MPSoC like I/O banks, interfaces and Gigabit transceivers
or to the on-board peripherals.

Following table lists the I/O-bank signals, which are routed from the MPSoC's PL and PS banks as LVDS pairs or single ended I/O's to the B2B connectors.

...

B47_L1_P ... B47_L12_P
B47_L1_N ... B47_L12_N

...

VCCO47
pins J3-43, J3-44

...

VCCO max. 3.3V
usable as single-ended I/Os

...

B48_L1_P ... B48_L12_P
B48_L1_N ... B48_L12_N

...

VCCO48
pins J3-15, J3-16

...

VCCO max. 3.3V
usable as single-ended I/Os

...

B64_L1_P ... B64_L24_P
B64_L1_N ... B64_L24_N

B_64_T0 ... B_64_T3

...

VCCO64
pins J4-58, J4-106

...

VCCO max. 1.8V
usable as single-ended I/Os

...

B65_L1_P ... B65_L24_P
B65_L1_N ... B65_L24_N

B_65_T0 ... B_65_T3

...

VCCO65
pins J4-69, J4-105

...

VCCO max. 1.8V
usable as single-ended I/Os

...

B66_L1_P ... B66_L24_P
B66_L1_N ... B66_L24_N

B_66_T0 ... B_66_T3

...

VCCO66
pins J1-90, J1-120

...

VCCO max. 1.8V
usable as single-ended I/Os

...

Table 2: B2B connector pin-outs of available PL and PS banks of the TE0808-04 SoM.

 

All MIO banks are powered from on-module DC-DC power rail. All PL I/O Banks have separate VCCO pins in the B2B connectors, valid VCCO should be supplied from the baseboard.

For detailed information about the B2B pin-out, please refer to the Pin-out table. 

The configuration of the I/O's MIO13 - MIO77 are depending on the base-board peripherals connected to these pins.

MGT Lanes

The B2B connector J1 and J2 provide also access to the MGT banks of the Zynq UltraScale+ MPSoC. There are 20 high-speed data lanes (Xilinx GTH / GTR transceiver) available composed as differential signaling pairs for both directions (RX/TX).

The MGT banks have also clock input-pins which are exposed to the B2B connectors J2 and J3. Following MGT lanes are available on the B2B connectors:

...

4 GTH lanes

(4 RX / 4 TX)

...

B228_RX3_P, B228_RX3_N, pins J1-27, J1-29
B228_TX3_P, B228_TX3_N, pins J1-26, J1-28

B228_RX2_P, B228_RX2_N, pins J1-33, J1-35
B228_TX2_P, B228_TX2_N, pins J1-32, J1-34

B228_RX1_P, B228_RX1_N, pins J1-39, J1-41
B228_TX1_P, B228_TX1_N, pins J1-38, J1-40

B228_RX0_P, B228_RX0_N, pins J1-45, J1-47
B228_TX0_P, B228_TX0_N, pins J1-44, J1-46

...

1 reference clock signal (B228_CLK0) from B2B connector
J3 (pins J3-60, J3-62) to bank's pins R8/R7

1 reference clock signal (B228_CLK1) from programmable
PLL clock generator U5 to bank's pins N8/N7

...

4 GTH lanes

(4 RX / 4 TX)

...

B229_RX3_P, B229_RX3_N, pins J1-27, J1-29
B229_TX3_P, B229_TX3_N, pins J1-26, J1-28

B229_RX2_P, B229_RX2_N, pins J1-33, J1-35
B229_TX2_P, B229_TX2_N, pins J1-32, J1-34

B229_RX1_P, B229_RX1_N, pins J1-39, J1-41
B229_TX1_P, B229_TX1_N, pins J1-38, J1-40

B229_RX0_P, B229_RX0_N, pins J1-45, J1-47
B229_TX0_P, B229_TX0_N, pins J1-44, J1-46

...

1 reference clock signal (B229_CLK0) from B2B connector
J3 (pins J3-65, J3-67) to bank's pins L8/L7

1 reference clock signal (B229_CLK1) from programmable
PLL clock generator U5 to bank's pins J8/J7

...

4 GTH lanes

(4 RX / 4 TX)

...

B230_RX3_P, B230_RX3_N, pins J1-3, J1-5
B230_TX3_P, B230_TX3_N, pins J1-2, J1-4

B230_RX2_P, B230_RX2_N, pins J1-9, J1-11
B230_TX2_P, B230_TX2_N, pins J1-8, J1-10

B230_RX1_P, B230_RX1_N, pins J1-15, J1-17
B230_TX1_P, B230_TX1_N, pins J1-14, J1-16

B230_RX0_P, B230_RX0_N, pins J1-21, J1-23
B230_TX0_P, B230_TX0_N, pins J1-20, J1-22

...

1 reference clock signal (B230_CLK1) from B2B connector
J3 (pins J3-59, J3-61) to bank's pins G8/G7

1 reference clock signal (B230_CLK0) from programmable
PLL clock generator U5 to bank's pins E8/E7

...

4 GTH lanes

(4 RX / 4 TX)

...

B128_RX3_N, B128_RX3_P, pins J2-28, J2-30
B128_TX3_N, B128_TX3_P, pins J2-25, J2-27

B128_RX2_N, B128_RX2_P, pins J2-34, J2-36
B128_TX2_N, B128_TX2_P, pins J2-31, J2-33

B128_RX1_N, B128_RX1_P, pins J2-40, J2-42
B128_TX1_N, B128_TX1_P, pins J2-37, J2-39

B128_RX0_N, B128_RX0_P, pins J2-46, J2-48
B128_TX0_N, B128_TX0_P, pins J2-43, J2-45

...

1 reference clock signal (B128_CLK1) from B2B connector
J2 (pins J2-22, J2-24) to bank's pins D25/D26

1 reference clock signal (B128_CLK0) from programmable
PLL clock generator U5 to bank's pins F25/F26

...

4 GTR lanes

(4 RX / 4 TX)

...

B505_RX3_N, B505_RX3_P, pins J2-52, J2-54
B505_TX3_N, B505_TX3_P, pins J2-49, J2-51

B505_RX2_N, B505_RX2_P, pins J2-58, J2-60
B505_TX2_N, B505_TX2_P, pins J2-55, J2-57

B505_RX1_N, B505_RX1_P, pins J2-64, J2-66
B505_TX1_N, B505_TX1_P, pins J2-61, J2-63

B505_RX0_N, B505_RX0_P, pins J2-70, J2-72
B505_TX0_N, B505_TX0_P, pins J2-67, J2-69

...

2 reference clock signals (B505_CLK0, B505_CLK1) from B2B connector
J2 (pins J2-10/J2-12, J2-16/J2-18) to bank's pins P25/P26, M25/M26

2 reference clock signal (B505_CLK2, B505_CLK3) from programmable
PLL clock generator U5 to bank's pins K25/K26, H25/H26

Table 3: B2B connector pin-outs of available MGT lanes of the MPSoC.

JTAG Interface

JTAG access is provided through the MPSoC's PS configuration bank 503 with bank voltage PS_1V8.

...

Table 4: B2B connector pin-out of JTAG interface.

Configuration Bank Control Signals

The Xilinx Zynq UltraScale+ MPSoC's PS configuration bank 503 control signal pins are accessible through B2B connector J2.

For further information about the particular control signals and how to use and evaluate them, refer to the  Xilinx Zynq UltraScale+ MPSoC TRM and UltraScale Architecture Configuration - User Guide.

...

4-bit boot mode pins.

For further information about the boot modes refer to the Xilinx Zynq UltraScale+ MPSoC TRM section 'Boot and Configuration'.

...

ERR_OUT signal is asserted for accidental loss of power, an error, or an exception in the MPSoC's Platform Management Unit (PMU).

ERR_STATUS indicates a secure lock-down state.

...

Table 5: B2B connector pin-out of MPSoC's PS configuration bank.

Analog Input

The Xilinx Zynq UltraScale+ MPSoC provides differential pairs for analog input values. The pins are exposed to B2B-connector J2.

...

Table 6: B2B connector pin-out of analog input pins

Quad SPI Interface

Quad SPI Flash memory ICs U7 and U17 are connected to the Zynq MPSoC PS QSPI0 interface via PS MIO bank 500, pins MIO0 ... MIO5 and MIO7 ... MIO12.

...

Table 7: PS MIO pin assignment of the Quad SPI Flash memory ICs.

Boot Process

The boot device and mode of the Zynq UltraScale+ MPSoC can be selected via 4 dedicated pins accessible on B2B connector J2:

...

Table 8: Boot mode pins on B2B connector J2.

...

Configured on module with dual QSPI Flash Memory.

32-bit addressing.
Supports single and dual parallel
configurations.
Stack and dual stack is not
supported.

...

Supports SD 3.0 with a required SD 3.0 compliant level shifter.

Table 9: Selectable boot modes by dedicated boot mode pins.

For functional details see  ug1085 - Zynq UltraScale+ TRM (Boot Modes Section).

On-board Peripherals

Flash

The TE0808 SoM can be configured with max. 512 MByte Flash memory for configuration and operation.

...

Table 10: Peripherals connected to the PS MIO pins.

DDR4 SDRAM

The TE0808-04 SoM is equipped with with four DDR4-2400 SDRAM modules with up to 8 GByte memory density. The SDRAM modules are connected to the Zynq MPSoC's PS DDR controller (bank 504) with a 64-bit data bus.

Refer to the Xilinx Zynq UltraScale+ datasheet DS925 for more information on whether the specific package of the Zynq UltraScale+ MPSoC supports the maximum data transmission rate of 2400 MByte/s.

Programmable PLL Clock Generator

Following table illustrates on-board Si5345A programmable clock multiplier chip inputs and outputs:

...

Table 11: Programmable PLL clock generator input/output.

 

The Si5345A programmable clock generator's control interface pins are exposed to B2B connector J2. For further information refer to the Si5345A data sheet.

...

Device reset (active-low)

...

I2C interface, external pull-ups needed for SCL / SDA lines.

I2C address in current configuration: 1101000b.

Table 12: B2B connector pin-out of Si5345A programmable clock generator.

Note

Si5345 OTP ROM is not programmed by default at delivery, so it is customers responsibility to either configure Si5345 during FSBL or then use SiLabs programmer and program the OTP ROM with customer fixed clock setup.

Si5345 OTP can only be programmed two times, as different user configurations may required different setup TE0808 is normally shipped with blank OTP.
For more information refer to Si5345 at SiLabs.

Oscillators

The TE0808-04 SoM is equipped with two on-board oscillators to provide the Zynq's MPSoC's PS configuration bank 503 with reference clock signals.

...

Table 13: Reference clock-signals to PS configuration bank 503.

On-board LEDs

...

LED

...

Table 14: LED's description.

Power and Power-On Sequence

Power Consumption

The maximum power consumption of a module mainly depends on the design which is running on the FPGA.

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.

...

Table 15: Maximum current of power supplies. *to be determined soon with reference design setup.

Power supply with minimum current capability of 3A for system startup is recommended. For the lowest power consumption and highest efficiency of on board DC/DC regulators it is recommended to powering the module from one single 3.3V supply. Except 'PS_BATT', all input power supplies have a nominal value of 3.3V. Although the input power supplies can be powered up in any order, it is recommended to power them up simultaneously.

The TE0808 module equipped with the Xilinx Zynq UltraScale+ MPSoC delivers a heterogeneous multi-processing system with integrated programmable logic and independently operable elements and is designed to meet embedded system power management requirement by advanced power management features. This features allow to offset the power and heat constraints against overall performance and operational efficiency.

This features allowing highly flexible power management are achieved by establishing Power Domains for power isolation. The Zynq UltraScale+ MPSoC has multiple power domains, whereby each power domain requires its own particular external DC-DC converters.

The Processing System contains three Power Domains:

  • Battery Power Domain (BBRAM and RTC)
  • Full-Power Domain (Application Processing Unit, DDR Controller, Graphics Processing Unit and High-Speed Connectivity)
  • Low-Power Domain (Real-Time Processing Unit, Security and Configuration Unit, Platform Management Unit, System Monitor and General Connectivity)

The fourth Power Domain is for the Programmable Logic (PL). If individual Power Domain control is not required, power rails can be shared between domains.

On the TE0808-04 SoM, following power domains can be powered up individually with power rails available on the B2B connectors:

  • Full-power domain, supplied by power rail DCDCIN
  • Low-power domain, supplied by power rail LP_DCDC
  • Programmable logic, supplied by power rail PL_DCIN
  • Battery power domain, supplied by power rail PS_BATT

Each power domain has its own enable and power good signals. The power rail GT_DCDC is needed to generate the voltages for the Multi Gigabit Transceiver units of the Zynq UltraScale+ MPSoC.

Power Distribution Dependencies

The power rails DCDCIN, LP_DCDC, PL_DCIN, PS_BATT have to be powered up on the assigned pins of the B2B connectors as listed on the section "Power Rails". Except 'PS_BATT' (see section "Recommended Operation Conditions"), all power-rails can be powered from 3.3V power sources (also share the same source, if power domain control is not required).

There are following dependencies how the initial voltages of the power rails on the B2B connectors are distributed to the on-board DC-DC converters, which power up further DC-DC converters and the particular on-board voltages:

Image Removed

Figure 3: Power Distribution Diagram.

Note

Current rating of  Samtec Razor Beam™ LSHM B2B connectors is 2.0A per pin (2 adjacent pins powered).

Power-On Sequence Diagram

The TE0808 SoM meets the recommended criteria to power up the Xilinx Zynq UltraScale+ MPSoC properly by keeping a specific sequence of enabling the on-board DC-DC converters dedicated to the particular Power Domains and powering up the on-board voltages.

The on-board voltages of the TE0808 SoM will be powered-up in order of a determined sequence by activating the above-mentioned power rails and the Enable-Signals of the DC-DC converters. The on-board voltages will be powered up at three steps.

  1. Low-Power Domain (LPD) and on-board Si5345A programmable clock generator supply voltage
  2. Programmable Logic (PL) and Full-Power Domain (FPD)
  3. GTH, PS GTR transceiver and DDR memory

Hence, those three power instances will be powered up consecutively and the Power-Good-Signals of the previous instance has to be asserted.

Following diagram describes the sequence of enabling the three power instances utilizing the DC-DC converter control signals (Enable, Power-Good), which will power-up in descending order as listed in the blocks of the diagram.

Image Removed

Figure 4: Power-On Sequence Utilizing DC-DC Converter Control Signals.

Operation Conditions of the DC-DC Converter Control Signals

The control signals have to be asserted on the B2B connector J2, whereby some of the Power-Good signals need external pull-up resistors.

...

TPS82085SIL /
NC7S08P5X data sheet

...

Table 16: Recommended operation conditions of DC-DC converter control signals.

Warning
To avoid any damage to the MPSoC module, check for stabilized on-board voltages in steady state before powering up the MPSoC's I/O bank voltages VCCOx. All I/Os should be tri-stated during power-on sequence.

Core voltages and main supply voltages have to reach stable state and their "Power Good"-signals have to be asserted before other voltages like bank's I/O voltages (VCCOx) can be powered up.

It is important that all PS and PL I/Os are tri-stated at power-on until the "Power Good"-signals are high, meaning that all on-module voltages have become stable and module is properly powered up.

See Xilinx datasheet DS925 for additional information. User should also check related base board documentation when intending base board design for TE0808 SoM.

Voltage Monitor Circuit

The voltages LP_DCDC and LP_0V85 are monitored by the voltage monitor circuit U41, which generates the POR_B reset signal at power-on. A manual reset is also possible by driving the MR-pin (J2-83) to GND. Leave this pin unconnected or connect to VDD (LP_DCDC) when unused.

Image Removed

Figure 5: Voltage monitor circuit

Power Rails

...

Power Rail Name

...

Directions

...

-

...

154, 156, 158, 160,
153, 155, 157, 159

...

Internal voltage level
1.8V nominal output

...

Internal voltage level
1.8V nominal output

...

Internal voltage level
1.2V nominal output

Table 17: Power rails of the MPSoC module on accessible connectors.

Bank Voltages

...

Table 18: Range of MPSoC module's bank voltages.

B2B connectors

...

Variants Currently In Production

...

(1) Note: Lower B2B connector profile,check distance bolt of between module and carrier

Table 19: Differences between variants of Module TE0808-04

Technical Specifications

Absolute Maximum Ratings

...

Parameter

...

Unit

...

Notes / Reference Document

...

Receiver (RXP/RXN) and transmitter
(TXP/TXN) absolute input voltage

...

Voltage on input pins of
NC7S08P5X 2-Input AND Gate

...

Voltage on input pins (nMR) of
TPS3106K33DBVR Voltage Monitor, U41

...

TPS3106 data sheet,
VDD = LP_DCDC

...

Storage temperature (ambient)

...

-40

...

°C

...

Note
Assembly variants for higher storage temperature range are available on request.

Recommended Operating Conditions

...

NC7S08P5X data sheet,
see schematic for VCC

...

Voltage on input pin 'MR' of
TPS3106K33DBVR Voltage Monitor, U41

...

TPS3106 data sheet,
VDD = LP_DCDC

Note
Please check Xilinx datasheet DS925 for complete list of absolute maximum and recommended operating ratings.

Operating Temperature Ranges

Commercial grade: 0°C to +70°C.

Industrial grade: -40°C to +85°C.

Extended grade: 0°C to +85°C.

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

Physical Dimensions

  • Module size: 52 mm × 76 mm.  Please download the assembly diagram for exact numbers

  • Mating height with standard connectors: 4mm

  • PCB thickness: 1.6mm

  • Highest part on PCB: approx. 3mm. Please download the step model for exact numbers

All dimensions are given in millimeters.

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Revision History

Hardware Revision History

...

Notes

...

Hardware revision number is written on the PCB board together with the module model number separated by the dash.

Image Removed

Document Change History

...

Revision

...

John Hartfiel
  • Update section: Variants Currently In Production

2017-08-28v.14Jan Kumann
  • Block diagram changed.
  • SPI flash section fixed.
  • Few smaller improvements.
2017-08-15v.12Vitali TsiukalaChanged signals count in the B2B connectors table
2017-08-15

v.11

John Hartfiel, Ali Naseri
  • PCB REV04 Initial release
  • update boot mode section
2017-02-06v.1Jan KumannInitial document

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