Draft:CRUVI
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CRUVI is an expansion bus interface designed to create an open ecosystem of function modules for high-performance peripheral connectivity. Its main focus is on supporting FPGA and FPGA SoC devices from all major manufacturers like Intel ®, Lattice, Microchip and Xilinx.
The word "CRUVI" is a combination of the Estonian word "KRUVI" for screw and the letter "C", which refers to the half of the hexagonal screw head. In this case, the "K" was replaced with "C" to emphasize the reference to the screw head.
Übersicht
[edit]The CRUVI open standard coexists between low speed, low pin-count like Pmod Interface devices and high-performance, high pin-count (HPC), 400 I/O FPGA Mezzanine Card (FMC) peripherals.
It can be used to build high performance prototypes, for system integration and testing to build complex systems from smaller building blocks to iterate quickly and reduce cost. Create custom test systems for production functional testing. It's a perfect platform for your next high-performance semiconductor evaluation boards and systems.
Interface bridging to or from other coexistence ecosystem is possible to do with peripheral modules or boards.
Three board-to-board connectors are specified: CRUVI-LS (Low Speed), CRUVI-HS (High Speed) and CRUVI-GT (Gigabit Transceiver) PCIe Gen 5.0 capable.
Peripheral CRUVI-HS and CRUVI-GT test board with loopback, scope or logic analyzer functions can verify the i.e. high speed connector performance or to be probed signals.[1]
History of CRUVI specification
[edit]International contributors to define the open source CRUVI specification are Trenz Electronic GmbH, Arrow Electronics, Samtec, Flinders University, Synaptic Laboratories Ltd, Symbiotic EDA and MicroFPGA UG.
History of CRUVI open source specification – FREE to use Apache License 2.0
Year | Version | Notes | Refs |
---|---|---|---|
2021 | 1.0.7 -alpha | first release | [1] |
2024 | 2.0.1 -alpha | coming soon |
Carrier host board specification
[edit]Carrier board or host board delivers power supplies, IO voltage and controls the functions of peripheral modules.
Single, double or triple width modules are allowed and they have more mounting holes.
A triple size of space on carrier board (PCB template CR99201) is 2.666 inches by 2.264 inches (67.72 mm × 57.5 mm) with LS and HS connectors. There are 3 slots named: AX, BY, and CZ. The mounting holes (1 to 6) for M2 screws are 2.2 mm (0.0866 inch) diameter and need SMD spacer for mechanically fixing.[1]
It is recommended for all FPGA host boards with CRUVI slots provide LiteX platform support files.[2]
Host and carrier boards are available with FPGA´s from Intel ® (TEI0050, TEI0185[3], CR00010, CR00100, CR00109), Lattice (TEL003, CR00103), Microchip (TEMB0005) and Xilinx (TEBF0707, CR00107).[4]
Bridging adapter exists to convert signals from Pmod to CRUVI-LS (CR00025), from FMC to CRUVI-HS (CR00101, CR00111) and FMC to CRUVI-GT (CR00112).[1]
Peripheral board specification
[edit]There are different single peripheral module possible, flexible and scalable by size LS, HS and GT connectors. Mounting holes are for M2 screws 2.2 millimeters (0.087 in) diameter.
It is recommended to have EEPROM with I2C for identification of peripheral module with a specific address number.
L × H | speed | PCB template[5] | Note |
---|---|---|---|
14 mm × 14 mm (0.55 in × 0.55 in) |
LS | CR99001 |
identification EEPROM is included; This template is usefull for I2C, I3C, SPI sensor, I2S PDM MEMS microphones, programmable oscillator, ADC, DAC or SPI (QSPI) Flash memory device in BGA24 or SO-8 package. |
14 mm × 14 mm (0.55 in × 0.55 in) |
LS | CR99002 | same as CR99001 with added u.Fl connectors for I/O |
22 mm × 32 mm (0.87 in × 1.26 in) |
LS | CR99003 |
maximum size one-wide half-length, identification EEPROM is included |
18 mm × 32 mm (0.71 in × 1.26 in) |
LS | CR99004 |
This template is useful to convert into Pmod compatible connector. |
22 mm × 30 mm (0.87 in × 1.18 in) |
LS | CR99005 |
is half-length LS module with two SMA connectors |
18 mm × 20 mm (0.71 in × 0.79 in) |
HS | CR99101 |
minimal size HS Module; good for HyperRAM or HyperFlash, eMMC or loopback adapter for CRUVI-HS |
22 mm × 57.5 mm (0.87 in × 2.26 in) |
HS | CR99102 |
maximum sized single-width HS module; good for signal test adapter to probed with scope or logic analyzer, for high speed interfaces like USB-C, HDMI, MIPI CSI/DSI, SDIO, xGMII Ethernet and LVDS ADC (1 to 4 data lane) |
LS Low Speed, HS High Speed and GT Gigabit Transceiver connector
[edit]Connector | LS Low Speed | HS High Speed | GT Gigabit Transceiver |
---|---|---|---|
Carrier side connector | CLT-106-02-F-D-A-K | SS4-30-3.50-L-D-K | ADF6-20-03.5-L-4-2 |
Peripheral side connector | TMMH-106-04-F-DV-A-M | ST4-30-1.50-L-D-P | ADM6-20-01.5-L-4-2 |
Pin no | 12 (6 per row) | 60 (30 per row) | 80 (20 per row) |
pitch | 2 mm (0.079 in) | 0.4 mm (0.016 in) | 0.635 mm (0.0250 in) |
stacked height | 4.78 mm (0.188 in) to 5.29 mm (0.208 in) | 5 mm (0.20 in) | |
speed rating [GHz] / [Gbps] | 5.5 / 11 | 13.5 / 27 (single ended)
15.5 / 31 (differential) |
32 |
Single ended I/O pins (VCCIO) | 8 | 37 (28 adj.) + (9 fixed 3.3V) | 8 + I2C |
max. differential I/O | no | max. 12 LVDS | max. 4 lanes + REFCLK |
Power Supply | adj., 3.3V, 5V | ||
Current rating per pin [A] | 4.1 (2-pin powered) | 1.6 (2-pin powered) | 1.34 (4-pin powered) |
max. Temperatur range [°C] | −55 to 125 |
CRUVI-LS pinout and signal description
[edit]Pin | Primäre | Signal | Pin | Primäre | Signal |
---|---|---|---|---|---|
1 | SDA | I2C(SDA), SMBUS(SDA) | 7 | D1 | UART(RXD1), SD(D1), SPI(MISO), QSPI(D1), JTAG(TDI) |
2 | SCL | I2C(SCL), SMBUS(SCL) | 8 | CLK | UART(RTS), SD(CLK), SPI(CLK), QSPI(CLK), JTAG(TCK) |
3 | D3 | UART(RST), SD(TXD0), QSPI(D3), JTAG(nRST) | 9 | D0 | UART(TXD1), SD(D0), SPI(MOSI), QSPI(D0) JTAG(TDO) |
4 | SEL | UART(CTS), SD(CMD), SPI(SEL), QSPI(SEL), JTAG(TMS) | 10 | VCC | Power 3.3V |
5 | D2 | SMBUS(INT), UART(RXD0), SD(D2), QSPI(D2), JTAG(RFU) | 11 | RFU | tbd |
6 | GND | Ground | 12 | VBUS | Power 5V |
CRUVI-HS pinout and signal description
[edit]Pin | Primary Function | Note | Pin | Primary Function | Note | Pin | Primary Function | Note | Pin | Primary Function | Note |
---|---|---|---|---|---|---|---|---|---|---|---|
1 | RFU1 | 16 | A0_N | Transceiver I/O | 31 | GND | Ground | 46 | A5_N | Transceiver I/O | |
2 | HSIO | 17 | B0_N | Transceiver I/O | 32 | A3_P | 47 | B5_N | Transceiver I/O | ||
3 | ALERT/IRQ | 18 | GND | Ground | 33 | B3_P | Transceiver I/O | 48 | GND | Ground | |
4 | VCC | 3,3V | 19 | GND | Ground | 34 | A3_N | 49 | GND | Ground | |
5 | SDA | 20 | A1_P | Transceiver I/O | 35 | B3_N | Transceiver I/O | 50 | RFU2_P | ||
6 | HSO | 21 | B1_P | Transceiver I/O | 36 | VADJ | 1.2 to 3.3V | 51 | DI/TDI | JTAG, SPI(MISO) | |
7 | SCL | 22 | A1_N | Transceiver I/O | 37 | GND | Ground | 52 | RFU2_N | ||
8 | HSRST | 23 | B1_N | Transceiver I/O | 38 | A4_P | Transceiver I/O | 53 | DO/TDO | JTAG, SPI(MOSI) | |
9 | VCC | 3.3V | 24 | GND | Ground | 39 | B4_P | Transceiver I/O | 54 | GND | Ground |
10 | HSI | 25 | GND | Ground | 40 | A4_N | Transceiver I/O | 55 | SEL/TMS | JTAG, SPI(SEL) | |
11 | REFCLK | 26 | A2_P | 41 | B4_N | Transceiver I/O | 56 | RFU_P | |||
12 | GND | Ground | 27 | B2_P | Transceiver I/O | 42 | GND | Ground | 57 | MODE | JTAG EN |
13 | GND | Ground | 28 | A2_N | 43 | GND | Ground | 58 | RFU_N | ||
14 | A0_P | Transceiver I/O | 29 | B2_N | Transceiver I/O | 44 | A5_P | Transceiver I/O | 59 | SCK/TCK | JTAG, SPI(CLK) |
15 | B0_P | Transceiver I/O | 30 | GND | Ground | 45 | B5_P | Transceiver I/O | 60 | VBUS | 5V |
References
[edit]- ^ a b c d e f g h "CRUVI specification v1.0 (2021)" (PDF). GitHub. 2021-11-30. Retrieved 2023-12-19.
- ^ "LiteX platform support files for FPGA host boards with CRUVI slots". GitHub. Retrieved 2023-12-19.
- ^ "(TEI0185) Intel ® Agilex 5 E Series AXE5 Eagle Development Platform". GitHub. Retrieved 2024-01-24.
- ^ "FPGA host boards with CRUVI slots". Retrieved 2024-01-07.
- ^ "PCB template CRUVI peripheral boards". GitHub. Retrieved 2023-12-19.
External links
[edit]- Official website retrieved 2024-01-07
- CRUVI FPGA (SoC) modules for business and science retrieved 2024-01-07
- Trenz Electronic and their partners created a new FPGA expansion bus called CRUVI published 2023-05-11
- Arrow reveals first Dev Board for Intel Agilex 5 FPGAs, with two more boards planned published 2023-11-27
- Software is integrated into VHDPlus IDE for CRUVI solutions retrieved 2024-01-07
- CRUVI standard for memory controller and related technologies. i.e. HyperBus and JEDEC xSPI memory retrieved 2024-01-07