Table of Contents
Overview
The Trenz Electronic TE0720 is an industrial-grade SoM (System on Module) based on Xilinx Zynq-7000 SoC (XC7Z020) with up to 1 GB of DDR3/L SDRAM, 32MB of SPI flash memory, Gigabit Ethernet PHY transceiver, a USB PHY transceiver and powerful switching-mode power supplies for all on-board voltages. A large number of configurable I/Os is provided via rugged high-speed stacking strips. See also Variants Currently in Production section.
Key Features
- Xilinx XC7Z SoC (XC7Z020)
- Processing System: Dual ARM Cortex-A9
Unified 512 KByte L2 cache
256 KByte on-chip memory
- Programmable Logic: Artix-7 FPGA
85 K logic cells
560 KByte extensible block RAM (140x 36 Kbit BRAM blocks)
220 programmable DSP slices
Dual 12-bit 1Msps AD converter - 54 multiplexed I/O pins (MIOs)
- 152 I/O pins (SelectIO interfaces)
- System Controller CPLD (Lattice LCMXO2-1200HC)
- 1 GByte DDR3/L memory, 2 x 256 Mbit x 16 (32-bit wide)
- 32 MByte Quad SPI Flash memory
- Gigabit Ethernet transceiver PHY (Marvell 88E1512)
- MAC address serial EEPROM with EUI-48™ node identity (11AA02E48)
- Highly integrated full-featured hi-speed USB 2.0 ULPI transceiver (Microchip USB3320C-EZK)
- 3-axis accelerometer and 3-axis magnetometer (ST Microelectronics LSM303DTR) (Optional!)
- Real time clock with embedded crystal (Intersil ISL12020M): ±5ppm accuracy
- Atmel CryptoAuthentication element (Atmel ATSHA204A)
- Up to 32 GByte eMMC, usually 4 GByte, depends on module variant and assembly option
- User LED 1 (Green), user LED 2 (Red), user LED 3 - FPGA DONE (Green)
- 1.5A, PowerSoC DC-DC step-down converter (Enpirion EP53F8QI) for 1.8V power supply
- 1.5A, PowerSoC DC-DC step-down converter (Enpirion EP53F8QI) for 1.5V power supply
- 4A PowerSoC DC-DC step-down converter (Enpirion EN6347) for 1.0V power supply
- Trenz 4 x 5 module socket connector (3 x Samtec LSHM series connectors)
Additional assembly options are available for cost or performance optimization upon request.
Block Diagram
Components and connections marked with dashed lines are optional or may be missing on some module variants, please contact us for additional information.
Main Components
- Xilinx Zynq XC7Z SoC, U5
- 4 Gbit DDR3/L SDRAM, U13
- 4 Gbit DDR3/L SDRAM, U12
- Low-power RTC with battery backed SRAM, U20
- 32 MByte Quad SPI Flash memory, U7
- Red LED (LED1), D5
- Green LED (LED2), D2
- System Controller CPLD, U19
- eMMC NAND Flash, U15
- 4A high-efficiency PowerSoC DC-DC step-down Converter (1V), U1
- Green LED (DONE), D4
- B2B connector Samtec Razor Beam™ LSHM-130, JM3
- B2B connector Samtec Razor Beam™ LSHM-150, JM1
- B2B connector Samtec Razor Beam™ LSHM-150, JM2
- Hi-speed USB 2.0 ULPI transceiver, U18
- Gigabit Ethernet (GbE) transceiver, U8
- Low-power programmable oscillator @ 52.000000 MHz (OTG-RCLK), U14
- Low-power programmable oscillator @ 33.333333 MHz (PS-CLK), U6
- Low-dropout regulator (VBATT), U24
- DDR termination regulator, U4
- 1.5A PowerSoC DC-DC step-down converter with integrated inductor (1.5V), U2
- Atmel CryptoAuthentication chip, U10
- 2Kbit UNI/O® serial EEPROM with EUI-48™ node identity, U17
- Low-power programmable oscillator @ 25.000000 MHz (ETH-CLK), U9
- 1.5A PowerSoC DC-DC step-down converter with integrated inductor (1.8V), U3
- 3A PFET load switch with configurable slew rate (3.3V), Q1
Initial Delivery State
Storage device name | IC | Content | Notes |
|---|---|---|---|
Quad SPI Flash | U7 | Empty | - |
| eMMC NAND Flash | U15 | Empty | - |
| 11AA02E48T EEPROM | U17 | Pre-programmed globally unique, 48-bit node address (MAC) | - |
| System Controller CPLD | U19 | Standard firmware. | Download firmware |
Signals, Interfaces and Pins
Board to Board (B2B) I/Os
PL I/O signal connections between Zynq SoC's I/O banks and B2B connectors, 152 total.
| Bank | Type | Voltage | B2B | I/O Count | Notes |
|---|---|---|---|---|---|
| 13 | HR GPIO | VCCIO13 | JM2 | 48 | 24 LVDS pairs |
| 13 | HR GPIO | VCCIO13 | JM2 | 2 | B13_IO0 and B13_IO25 |
| 33 | HR GPIO | VCCIO33 | JM2 | 18 | 9 LVDS pairs |
| 34 | HR GPIO | VCCIO34 | JM3 | 36 | 18 LVDS pairs |
| 35 | HR GPIO | VCCIO35 | JM1 | 48 | 24 LVDS pairs |
PS I/O signal connections between Zynq SoC's I/O banks and B2B connectors, 14 total.
| Bank | Type | Voltage | B2B | I/O Count | Notes |
|---|---|---|---|---|---|
| 500 | MIO | 3.3V | JM1 | 8 | |
| 501 | MIO | 1.8V | JM1 | 6 | SD0 |
For detailed information about the pin-out, please refer to the Pin-out tables.
JTAG Interface
JTAG access to the Xilinx Zynq and to the System Controller CPLD is provided through B2B connector JM2.
JTAG Signal | B2B Connector Pin |
|---|---|
| TMS | JM2-93 |
| TDI | JM2-95 |
| TDO | JM2-97 |
| TCK | JM2-99 |
JTAGMODE pin 89 in B2B connector JM1 is used to select which device is accessible. Low - Xilinx Zynq, High - System Controller CPLD.
System Controller I/O Pins
Special purpose pins are connected to System Controller CPLD and have following default configuration:
| Pin Name | Mode | Function | Default Configuration |
|---|---|---|---|
| RESIN | Input | Reset input | Active low reset input, default mapping forces POR_B reset to Zynq PS. |
| PGOOD | Output | Power good | Active high when all on-module power supplies are working properly. |
| MODE | Input | Boot mode | Force low for boot from the SD card. Latched at power-on only, not during soft reset! |
| EN1 | Input | Power enable | High enables the DC-DC converters and on-board supplies. Not used if NOSEQ is high. |
| NOSEQ | Input | Power sequencing | Forces the 1.0V and 1.8V DC-DC converters always ON when high. |
| JTAGMODE | Input | JTAG select | Keep low for FPGA JTAG access. |
Default PS MIO Pin Mapping
| MIO | Function | Wired to | Notes | MIO | Function | Wired to | Notes |
|---|---|---|---|---|---|---|---|
| 0 | - | JM1-87 | - | 27 | ETH0 | U8-43 | ETH-RXCTL |
| 1 | QSPI0 | U7-C2 | SPI-CS | 28 | USB0 | U18-7 | OTG-DATA4 |
| 2 | QSPI0 | U7-D3 | SPI-DQ0 | 29 | USB0 | U18-31 | OTG-DIR |
| 3 | QSPI0 | U7-D2 | SPI-DQ1 | 30 | USB0 | U18-29 | OTG-STP |
| 4 | QSPI0 | U7-C4 | SPI-DQ2 | 31 | USB0 | U18-2 | OTG-NXT |
| 5 | QSPI0 | U7-D4 | SPI-DQ3 | 32 | USB0 | U18-3 | OTG-DATA0 |
| 6 | QSPI0 | U7-B2 | SPI-SCK | 33 | USB0 | U18-4 | OTG-DATA1 |
| 7 | GPIO | U19-P11 | SC CPLD | 34 | USB0 | U18-5 | OTG-DATA2 |
| 8 | - | - | 3.3V pull-up | 35 | USB0 | U18-6 | OTG-DATA3 |
| 9 | - | JM1-91 | B2B, MIO9 | 36 | USB0 | U18-1 | OTG-CLK |
| 10 | - | JM1-95 | B2B, MIO10 | 37 | USB0 | U18-9 | OTG-DATA5 |
| 11 | - | JM1-93 | B2B, MIO11 | 38 | USB0 | U18-10 | OTG-DATA6 |
| 12 | - | JM1-99 | B2B, MIO12 | 39 | USB0 | U18-13 | OTG-DATA7 |
| 13 | - | JM1-97 | B2B, MIO13 | 40 | SD0 | JM1-27 | B2B, MIO40 |
| 14 | - | JM1-92, U19-M4 | B2B, MIO14 | 41 | SD0 | JM1-25 | B2B, MIO41 |
| 15 | - | JM1-85, U19-N4 | B2B, MIO15 | 42 | SD0 | JM1-23 | B2B, MIO42 |
| 16 | ETH0 | U8-53 | ETH-TXCK | 43 | SD0 | JM1-21 | B2B, MIO43 |
| 17 | ETH0 | U8-50 | ETH-TXD0 | 44 | SD0 | JM1-19 | B2B, MIO44 |
| 18 | ETH0 | U8-51 | ETH-TXD1 | 45 | SD0 | JM1-17 | B2B, MIO45 |
| 19 | ETH0 | U8-54 | ETH-TXD2 | 46 | SD1 | U15-H3 | MMC-D0 |
| 20 | ETH0 | U8-55 | ETH-TXD3 | 47 | SD1 | U15-W5 | MMC-CMD |
| 21 | ETH0 | U8-56 | ETH-TXCTL | 48 | SD1 | U15-W6 | MMC-CLK |
| 22 | ETH0 | U8-46 | ETH-RXCK | 49 | SD1 | U15-H4 | MMC-D1 |
| 23 | ETH0 | U8-44 | ETH-RXD0 | 50 | SD1 | U15-H5 | MMC-D2 |
| 24 | ETH0 | U8-45 | ETH-RXD1 | 51 | SD1 | U15-J2 | MMC-D3 |
| 25 | ETH0 | U8-47 | ETH-RXD2 | 52 | ETH0 | U8-7, U19-L14 | ETH-MDC |
| 26 | ETH0 | U8-48 | ETH-RXD3 | 53 | ETH0 | U8-8, U19-K14 | ETH-MDIO |
- MIO0 to MIO15 are bank 500 MIOs with corresponding VCCO_MIO0_500 of 3.3V.
- MIO16 to MIO53 are bank 501 MIOs with corresponding VCCO_MIO1_501 of 1.8V.
Gigabit Ethernet
The Marvell Alaska 88E1512 (U8) is a physical layer device containing a single Gigabit Ethernet transceiver and three separate major electrical interfaces: MDI interface to copper cable, SERDES/SGMII interface and RGMII interface. RGMII interface is connected to the Zynq SoC PS bank 501 MIO pins, see section Default PS MIO Pin Mapping.
SGMII (SFP copper or fiber) pins are routed to the B2B connector JM3 and MDI pins are routed to the B2B connector JM1 (see table below).
Ethernet PHY to B2B connections
| PHY Signal | B2B Connector Pin |
|---|---|
| SOUT_N | JM3-1 |
| SOUT_P | JM3-3 |
| SIN_N | JM3-2 |
| SIN_P | JM3-4 |
| PHY_MDI0_P | JM1-4 |
| PHY_MDI0_N | JM1-6 |
| PHY_MDI1_P | JM1-10 |
| PHY_MDI1_N | JM1-12 |
| PHY_MDI2_P | JM1-16 |
| PHY_MDI2_N | JM1-18 |
| PHY_MDI3_P | JM1-22 |
| PHY_MDI3_N | JM1-24 |
USB Interface
Hi-speed USB ULPI PHY is provided by USB3320 from Microchip. The ULPI interface is connected to the Zynq PS USB0 via MIO28..39, bank 501. The I/O voltage is fixed at 1.8V and PHY reference clock input is supplied from the on-board 52.000000 MHz oscillator (U14).
USB PHY connection
| USB PHY Pin | SC CPLD Pin | B2B Name | Notes |
|---|---|---|---|
| REFSEL0..2 | - | - | Reference clock frequency select, all set to GND = 52.000000 MHz. |
| RESETB | B14, bank 1 | - | Active low reset. |
| CLKOUT | - | - | ULPI output clock connected to Zynq PS MIO36. |
| DP, DM | OTG-D_P, OTG-D_N | USB data lines. | |
| CPEN | VBUS_V_EN | External USB power switch active high enable signal. | |
| VBUS | - | USB-VBUS | Connect to USB VBUS via a series of resistors, see reference schematic. |
| ID | - | OTG-ID | For A-device connect to the ground, for B-device leave floating. |
| SPK_L | M5, bank 2 | - | In USB audio mode a switch connects the DM pin to the SPK_L. |
| SPK_R | M8, bank 2 | - | In USB audio mode a switch connects the DP pin to the SPK_R. |
I2C Interface
On-board I2C devices are connected to the System Controller CPLD which acts as a I2C bus repeater for the Zynq SoC. System Controller CPLD signals X1, X3 and X7 are routed to Zynq SoC bank 34. Exact functionality depends on the System Controller CPLD firmware.
SoC to System Controller CPLD I2C bus
| Signal Name | SC CPLD Pin | SoC Pin | Notes |
|---|---|---|---|
| X1 | F1 | L16 | SCL, I2C clock. |
| X5 | J1 | P22 | SDA, I2C data out. |
| X7 | M1 | N22 | SDA, I2C data in. |
I2C devices slave addresses
| I2C Device | I2C Address | IC | Notes |
|---|---|---|---|
| ISL12020M RTC | 0x6F | U20 | RTC registers. |
| ISL12020M SRAM | 0x57 | U20 | Battery backed RAM in RTC IC. |
| LSM303D | 0x1D | U22 | Optional, not soldered on current production variants. |
Boot Process
By default the TE-0720 supports QSPI and SD Card boot modes which is controlled by the MODE input signal from the B2B JM1 connector.
MODE Signal State | Boot Mode |
|---|---|
High or open | SD Card |
Low or connected to the ground | QSPI |
On-board Peripherals
32 MByte Quad SPI Flash Memory
On-board QSPI flash memory S25FL256S (U7) is used to store initial FPGA configuration. Besides FPGA configuration, remaining free flash memory can be used for user application and data storage. All four SPI data lines are connected to the FPGA allowing x1, x2 or x4 data bus widths. Maximum data rate depends on the selected bus width and clock frequency used.
SPI Flash QE (Quad Enable) bit must be set to high or FPGA is unable to load its configuration from flash during power-on. By default this bit is set to high at the manufacturing plant.
eMMC Flash Memory
eMMC NAND Flash (U15) is connected to the Zynq PS MIO bank 501 pins MIO46..MIO51 (see also Variants Currently in Production for options). Depending on the module variant, different make and model of eMMC chips are available.
Gigabit Ethernet
On-board Gigabit Ethernet PHY is provided with Marvell Alaska 88E1512 IC (U8). The Ethernet PHY RGMII interface is connected to the Zynq Ethernet0 PS GEM0. I/O voltage is fixed at 1.8V for HSTL signalling. The reference clock input of the PHY is supplied from an on-board 25.000000 MHz oscillator (U9), the 125MHz output clock signal CLK_125MHZ is connected to the pin G13 of the System Controller CPLD chip (U19).
Ethernet PHY to SC CPLD connections
| PHY Signal | SC CPLD Pin |
|---|---|
| ETH-MDC | L14 |
| ETH-MDIO | K14 |
| PHY_LED0 | F14 |
| PHY_LED1 | D12 |
| PHY_LED2 | C13 |
| PHY_CONFIG | C14 |
| ETH-RST | E14 |
| CLK_125MHZ | G13 |
High-speed USB ULPI PHY
Hi-speed USB ULPI PHY is provided with USB3320 from Microchip. The ULPI interface is connected to the Zynq PS USB0 via MIO28..39, bank 501 (see also section. The I/O voltage is fixed at 1.8V and PHY reference clock input is supplied from the on-board 52.000000 MHz oscillator (U14).
RTC - Real Time Clock
Temperature compensated Intersil ISL12020M IC is used for Real Time Clock (U20). Battery voltage must be supplied to the module VBAT_IN pin from the carrier board to use battery backed functionality. Battery backed registers can be accessed over I2C bus at slave address of 0x6F. General purpose RAM is at I2C slave address 0x57. RTC IC is supported by Linux so it can be used as hwclock device.
MAC-Address EEPROM
A Microchip 2Kbit 11AA02E48 serial EEPROM (U17) is connected to the System Controller CPLD pin M14 via single-I/O UNI/O serial interface and contains pre-programmed globally unique 48-bit node address compatible with EUI-48TM specification. Chip is programmed at the factory with a globally unique node address stored in the upper 1/4 of the memory array and write-protected through the STATUS register. The remaining 1,536 bits are available for application use.
Atmel CryptoAuthentication Chip
The ATSHA204A Atmel CryptoAuthenticationTM chip (U10) is connected to the System Controller CPLD pin N14 via single-wire interface providing various security functions and features such as anti-counterfeiting, firmware/media protection, password validation, secure session key exchanging, secure data storage and more. Refer to the product datasheet for more information.
Clocking
| Source | Signal | Frequency | Destination | Pin Name | Notes |
|---|---|---|---|---|---|
| U6 | PS-CLK | 33.333333 MHz | U5 | PS_CLK_500 | Zynq SoC PS subsystem main clock. |
| U14 | OTG-RCLK | 52.000000 MHz | U18 | REFCLK | USB3320C PHY reference clock. |
| U9 | ETH-CLK | 25.000000 MHz | U8 | XTAL_IN | 88E1512 PHY reference clock. |
On-board LEDs
| LED | Color | Connected to | Description and Notes |
|---|---|---|---|
| D2 | Green | LED1 | Controlled by System Controller CPLD firmware. |
| D4 | Green | DONE | |
| D5 | Red | LED2 | Controlled by System Controller CPLD firmware. |
Power and Power-On Sequence
Power Supply
Power supply with minimum current capability of 3A for system startup is recommended.
Power Consumption
| Power Input Pin | Typical Current |
|---|---|
| VIN | TBD* |
| 3.3VIN | TBD* |
* TBD - To Be Determined soon with reference design setup.
Power Distribution Diagram
Current rating of Samtec Razor Beam™ LSHM B2B connectors is 2.0A per pin (2 adjacent pins powered).
Power-On Sequence
For highest efficiency of the on-board DC-DC regulators, it is recommended to use same 3.3V power source for both VIN and 3.3VIN power rails. Although VIN and 3.3VIN can be powered up in any order, it is recommended to power them up simultaneously.
It is important that all carrier board I/Os are 3-stated at power-on until System Controller CPLD sets PGOOD signal high (B2B connector JM1, pin 30), or 3.3V is present on B2B connector JM2 pins 10 and 12, meaning that all on-module voltages have become stable and module is properly powered up.
See also Xilinx datasheet DS187 for additional information. User should also check related carrier board documentation when choosing carrier board design for TE0720 module.
NOSEQ input signal
NOSEQ input signal from the carrier board can be used to control output of the two DC-DC converters U1 and U3. It works in conjunction with the System Controller CPLD firmware controlled ON_1V0 and ON_1V8 input signals of the U21 and U25 gate ICs.
|
|
| If NOSEQ input signal from the carrier board is low (logical 0), signals ON_1V0 and ON_1V8 can be driven by System Controller CPLD to control outputs of the U1 and U3 DC-DC converters. | If NOSEQ input signal from the carrier board is high (logical 1), state of the ON_1V0 and ON_1V8 signals is irrelevant and DC-DC converters U1 and U3 outputs are always enabled. |
Initial state of the ON_1V0 and ON_1V8 signals and therefore also functionality of the NOSEQ signal depend on the System Controller CPLD firmware.
Power Rails
B2B Name | B2B JM1 Pins | B2B JM2 Pins | Direction | Note |
|---|---|---|---|---|
| VIN | 1, 3, 5 | 2, 4, 6, 8 | Input | Supply voltage from carrier board. |
| 3.3VIN | 13, 15 | 91 | Input | Supply voltage from carrier board. JM2-91 is VREF_JTAG. |
| VCCIO35 | 9, 11 | - | Input | High range bank voltage from carrier board. |
| VCCIO33 | - | 5 | Input | High range bank voltage from carrier board. |
| VCCIO13 | - | 7, 9 | Input | High range bank voltage from carrier board. |
| VCCIO34 | - | 1, 3 | Input | High range bank voltage from carrier board. |
| VBAT_IN | 79 | - | Input | RTC battery-buffer supply voltage. |
| 3.3V | - | 10, 12 | Output | Internal 3.3V voltage level. |
| 1.8V | 39 | - | Output | Internal 1.8V voltage level. |
| 1.5V 1) | - | 19 | Output | Internal 1.5V voltage level. |
1) In case of module variant of TE0720-03-L1IF which uses Xilinx Zynq XC7Z020-L1CLG484I chip with lower power consumption, power rails named 1.5V and VCCO_DDR_502 voltage is actually 1.35V. To achieve this, a resistor with different value is used for R4 (see schematic of the TE0720-03-L1IF for more information).
Bank Voltages
Bank | Schematic Name | Voltage | Notes |
|---|---|---|---|
| 500 | 3.3V, VCCO_MIO0_500 | 3.3V | |
| 501 | 1.8V, VCCO_MIO1_501 | 1.8V | |
| 502 | 1.5V, VCCO_DDR_502 | 1.5V | |
| 0 Config | 3.3V | 3.3V | |
| 13 HR | VCCO13 | 1.2V to 3.3V | Supplied by the carrier board. |
| 33 HR | VCCIO33 | 1.2V to 3.3V | Supplied by the carrier board. |
| 34 HR | VCCIO34 | 1.2V to 3.3V | Supplied by the carrier board. |
| 35 HR | VCCIO35 | 1.2V to 3.3V | Supplied by the carrier board. |
Board to Board Connectors
Unable to render {include} The included page could not be found.
Variants Currently in Production
| Module Variant | Zynq SoC | RAM | eMMC Size | Temperature Range | B2B Connector Height |
|---|---|---|---|---|---|
| TE0720-03-2IF | XC7Z020-2CLG484I | 1 GByte | 4 GByte | Industrial | 4.0 mm |
| TE0720-03-2IFC3 | XC7Z020-2CLG484I | 1 GByte | 4 GByte | Industrial | 2.5 mm |
| TE0720-03-2IFC8 | XC7Z020-2CLG484I | 1 GByte | 32 GByte | Industrial | 4.0 mm |
| TE0720-03-L1IF | XC7Z020-L1CLG484I | 512 MByte | 4 GByte | Industrial | 4.0 mm |
| TE0720-03-1CF | XC7Z020-1CLG484C | 1 GByte | 4 GByte | Commercial | 4.0 mm |
| TE0720-03-1CR | XC7Z020-1CLG484C | 256 MByte | - | Commercial | 4.0 mm |
| TE0720-03-14S-1C | XC7Z014S-1CLG484C | 1 GByte | 4 GByte | Commercial | 4.0 mm |
| TE0720-03-1QF | XA7Z020-1CLG484Q | 1 GByte | 4 GByte | Automotive | 4.0 mm |
Technical Specifications
Absolute Maximum Ratings
Parameter | Min | Max | Units | Reference Document |
|---|---|---|---|---|
VIN supply voltage | -0.3 | 6.5 | V | EP53F8QI datasheet. |
| 3.3VIN supply voltage | -0.1 | 3.75 | V | TPS27082L and LCMXO2-1200HC datasheets. |
| Supply voltage for PS MIO banks | -0.5 | 3.6 | V | See Xilinx DS187 datasheet. |
| I/O input voltage for MIO banks | -0.4 | VCCO_MIO + 0.55 | V | See Xilinx DS187 datasheet. (VCCO_MIO0_500, VCCO_MIO1_501) |
| Supply voltage for HR I/Os banks | -0.5 | 3.6 | V | See Xilinx DS187 datasheet. (VCCIO13, VCCIO33, VCCIO34, VCCIO35) |
| I/O input voltage for HR I/O banks | -0.4 | VCCIO + 0.55 | V | See Xilinx DS187 datasheet. |
Storage temperature | -40 | +85 | °C | - |
| Storage temperature without the ISL12020MIRZ, eMMC Flash and 88E1512 PHY installed | -55 | +100 | °C | NB! Module variants using Nanya SDRAM chips, max temperature limit is +125 °C. |
Assembly variants for higher storage temperature range are available on request.
Please check Xilinx datasheet DS187 for complete list of absolute maximum and recommended operating ratings.
Recommended Operating Conditions
| Parameter | Min | Max | Units | Reference Document |
|---|---|---|---|---|
| VIN supply voltage | 2.5 | 5.5 | V | EN6347QI and EP53F8QI datasheets. |
| 3.3VIN supply voltage | 3.135 | 3.465 | V | 3.3V +/- 5%. |
| Supply voltage for PS MIO banks | 1.71 | 3.465 | V | See Xilinx DS187 datasheet. |
| I/O input voltage for PS MIO banks | -0.20 | VCCO_MIO + 0.20 | V | See Xilinx DS187 datasheet. |
| Supply voltage for HR I/Os banks | 1.14 | 3.465 | V | See Xilinx DS187 datasheet. |
| I/O input voltage for HR I/O banks | -0.20 | VCCIO + 0.20 | V | See Xilinx DS187 datasheet. |
Operating Temperature Ranges
Commercial grade: 0°C to +70°C.
Industrial and automotive grade: -40°C to +85°C.
Operating temperature range depends also on customer design and cooling solution. Please contact us for options.
Physical Dimensions
Module size: 50 mm × 40 mm. Please download the assembly diagram for exact numbers.
Mating height with standard connectors: 8 mm.
PCB thickness: 1.6 mm.
Highest part on PCB: approx. 2.5 mm. Please download the step model for exact numbers.
All dimensions are given in millimeters.
Weight
ca 23 g - Plain module
Revision History
Hardware Revision History
There is no hardware revision number marking on the module.
Document Change History
Date | Revision | Contributors | Description |
|---|---|---|---|
| 2017-06-21 | Jan Kumann | Initial document. |
Disclaimer
Data Privacy
Please also note our data protection declaration at https://www.trenz-electronic.de/en/Data-protection-Privacy
Document Warranty
The material contained in this document is provided “as is” and is subject to being changed at any time without notice. Trenz Electronic does not warrant the accuracy and completeness of the materials in this document. Further, to the maximum extent permitted by applicable law, Trenz Electronic disclaims all warranties, either express or implied, with regard to this document and any information contained herein, including but not limited to the implied warranties of merchantability, fitness for a particular purpose or non infringement of intellectual property. Trenz Electronic shall not be liable for errors or for incidental or consequential damages in connection with the furnishing, use, or performance of this document or of any information contained herein.
Limitation of Liability
In no event will Trenz Electronic, its suppliers, or other third parties mentioned in this document be liable for any damages whatsoever (including, without limitation, those resulting from lost profits, lost data or business interruption) arising out of the use, inability to use, or the results of use of this document, any documents linked to this document, or the materials or information contained at any or all such documents. If your use of the materials or information from this document results in the need for servicing, repair or correction of equipment or data, you assume all costs thereof.
Copyright Notice
No part of this manual may be reproduced in any form or by any means (including electronic storage and retrieval or translation into a foreign language) without prior agreement and written consent from Trenz Electronic.
Technology Licenses
The hardware / firmware / software described in this document are furnished under a license and may be used /modified / copied only in accordance with the terms of such license.
Environmental Protection
To confront directly with the responsibility toward the environment, the global community and eventually also oneself. Such a resolution should be integral part not only of everybody's life. Also enterprises shall be conscious of their social responsibility and contribute to the preservation of our common living space. That is why Trenz Electronic invests in the protection of our Environment.
REACH, RoHS and WEEE
REACH
Trenz Electronic is a manufacturer and a distributor of electronic products. It is therefore a so called downstream user in the sense of REACH. The products we supply to you are solely non-chemical products (goods). Moreover and under normal and reasonably foreseeable circumstances of application, the goods supplied to you shall not release any substance. For that, Trenz Electronic is obliged to neither register nor to provide safety data sheet. According to present knowledge and to best of our knowledge, no SVHC (Substances of Very High Concern) on the Candidate List are contained in our products. Furthermore, we will immediately and unsolicited inform our customers in compliance with REACH - Article 33 if any substance present in our goods (above a concentration of 0,1 % weight by weight) will be classified as SVHC by the European Chemicals Agency (ECHA).
RoHS
Trenz Electronic GmbH herewith declares that all its products are developed, manufactured and distributed RoHS compliant.
WEEE
Information for users within the European Union in accordance with Directive 2002/96/EC of the European Parliament and of the Council of 27 January 2003 on waste electrical and electronic equipment (WEEE).
Users of electrical and electronic equipment in private households are required not to dispose of waste electrical and electronic equipment as unsorted municipal waste and to collect such waste electrical and electronic equipment separately. By the 13 August 2005, Member States shall have ensured that systems are set up allowing final holders and distributors to return waste electrical and electronic equipment at least free of charge. Member States shall ensure the availability and accessibility of the necessary collection facilities. Separate collection is the precondition to ensure specific treatment and recycling of waste electrical and electronic equipment and is necessary to achieve the chosen level of protection of human health and the environment in the European Union. Consumers have to actively contribute to the success of such collection and the return of waste electrical and electronic equipment. Presence of hazardous substances in electrical and electronic equipment results in potential effects on the environment and human health. The symbol consisting of the crossed-out wheeled bin indicates separate collection for waste electrical and electronic equipment.
Trenz Electronic is registered under WEEE-Reg.-Nr. DE97922676.
Overview
Content Tools