Skip to content

Latest commit

 

History

History
306 lines (161 loc) · 10 KB

README.md

File metadata and controls

306 lines (161 loc) · 10 KB

LED to believe

LibreCores

This project aims to provide LED blinking examples for all the FPGA dev boards in the world.

The goal is to provide a quick way to test your new FPGA board and get acquainted with using FuseSoC in your design flow.

Each FPGA board is implemented as a separate FuseSoC target and users are highly encouraged to add support for their any board at their disposal so that we can have a large collection.

How to use

This project is available in the FuseSoC base library, so if you have FuseSoC installed, you likely already have this project as well.

To check if it's available run fusesoc core list and check for a core called fusesoc:utils:blinky.

If it's not there, try to run fusesoc library update to refresh the core libraries and look again.

If it's still not there, or if you want to modify the project, e.g. to add support for an additional board, you can add LED to believe as a new core library with fusesoc library add blinky https://github.com/fusesoc/blinky. LED to believe will now be added as a new library and downloaded to fusesoc_libraries/blinky

To build for your particular board, run fusesoc run --target=<board> fusesoc:utils:blinky where <board> is one of the boards listed in the Board support section below.

Alternatively, run fusesoc core show fusesoc:utils:blinky to find all available targets.

There is also a simulation target available to test the core without any hardware. To use this, run fusesoc run --target=sim fusesoc:utils:blinky.

The simulation target has a number of target-specific configuration parameters that can be set. All target-specific parameters goes on the end of the command line (after the core name).

To list all simulation parameters, run fusesoc run --target=sim fusesoc:utils:blinky --help.

Example: To run four pulses with a simulated clock frequency of 4MHz and creating a VCD file, run fusesoc run --target=sim fusesoc:utils:blinky --pulses=4 --clk_freq_hz=4000000 --vcd.

The default simulator to use is Icarus Verilog, but other simulators can be used by setting the --tool parameter after the run command.

Currently supported simulators for this target are icarus, modelsim and xsim. To use e.g. modelsim run fusesoc run --target=sim --tool=modelsim fusesoc:utils:blinky.

What to do next

That was fun, wasn't it? And did you know that once you have gotten a LED to blink in this way, you are actually 90% of the way already to run a small SoC with a RISC-V CPU on the same board. Maybe your board is already supported? Or maybe you're up to the challenge of adding support for it. All it takes is to create a 16MHz clock and allocate an output pin to connect a UART. For more info, move on to learn about and run SERV, the world's smallest RISC-V CPU

Board support

The following boards are currently supported:

AC701

https://www.xilinx.com/products/boards-and-kits/ek-a7-ac701-g.html

AnalogMax

https://www.arrow.com/en/products/tei0001-03-16-c8/trenz-electronic-gmbh

afp27

http://www.armadeus.org/wiki/index.php?title=APF27

afp51

http://www.armadeus.org/wiki/index.php?title=APF51

Alhambra II

https://alhambrabits.com/alhambra/

arty_a7_35t

https://store.digilentinc.com/arty-a7-artix-7-fpga-development-board-for-makers-and-hobbyists/

ax309

http://www.alinx.com/en/index.php/default/content/143.html

bemicro_max10

https://www.arrow.com/en/products/bemicromax10/arrow-development-tools

cmod_a7

This are two variants for this board:

  • 15t has ~10K LUTs. Use --target=cmod_a7_15t
  • 35t has ~20K LUTs. Use --target=cmod_a7_35t

https://digilent.com/reference/programmable-logic/cmod-a7/reference-manual

basys3

https://store.digilentinc.com/basys-3-artix-7-fpga-beginner-board-recommended-for-introductory-users/

c10lp_refkit

https://shop.trenz-electronic.de/en/TEI0009-02-055-8CA-Cyclone-10-LP-RefKit-10CL055-Development-Board-32-MByte-SDRAM-16-MByte-Flash

Chameleon96 (Arrow 96 CV SoC Board)

https://github.com/SoCFPGA-learning/Chameleon96

colorlight_5a75b

https://fr.aliexpress.com/item/32281130824.html

crosslink_nx_evn

https://www.latticesemi.com/en/Products/DevelopmentBoardsAndKits/CrossLink-NXEvaluationBoard

cyc1000

https://shop.trenz-electronic.de/en/TEI0003-02-CYC1000-with-Cyclone-10-FPGA-8-MByte-SDRAM

Cisco HWIC-3G-CDMA

https://github.com/tomverbeure/cisco-hwic-3g-cdma

Waveshare CoreEP4CE10

https://www.waveshare.com/wiki/CoreEP4CE10

de0_nano

https://www.terasic.com.tw/cgi-bin/page/archive.pl?No=593

de1_soc

https://www.terasic.com.tw/cgi-bin/page/archive.pl?Language=English&CategoryNo=165&No=836

de10_nano

https://www.terasic.com.tw/cgi-bin/page/archive.pl?Language=English&CategoryNo=205&No=1046

DECA

https://www.terasic.com.tw/cgi-bin/page/archive.pl?Language=English&CategoryNo=&No=944&PartNo=1

EBAZ4205 'Development' Board

This development board featuring Zynq 7010 was the control card of Ebit E9+ BTC miner.

Note: The Zynq PL on this board doesn't have a reference clock without involving the Zynq PS. To workaround this problem, the onboard 33MHz clock oscillator can be physically bridged to the PL clock input pin. To do this, solder a fine wire from R2340 (the clock output of X8) to the PL clock input on the pad for the missing R1372 near X5.

https://github.com/xjtuecho/EBAZ4205

ecp5_evn

https://www.latticesemi.com/en/Products/DevelopmentBoardsAndKits/ECP5EvaluationBoard

EP2C5T144 Development Board

http://land-boards.com/blwiki/index.php?title=Cyclone_II_EP2C5_Mini_Dev_Board

Fomu

https://tomu.im/fomu.html

FPC-III

https://repo.or.cz/fpc-iii.git

Nandland Go Board

https://www.nandland.com/goboard/introduction.html

ice40hx1k_evb

https://www.olimex.com/wiki/ICE40HX1K-EVB

ice40-hx8k_breakout

http://www.latticesemi.com/en/Products/DevelopmentBoardsAndKits/iCE40HX8KBreakoutBoard.aspx

iCEBreaker FPGA

https://www.crowdsupply.com/1bitsquared/icebreaker-fpga

iceFUN

https://www.robot-electronics.co.uk/products/fpga/icefun.html

iceWerx

https://www.robot-electronics.co.uk/icewerx.html

lx9_microboard

https://www.avnet.com/shop/us/products/avnet-engineering-services/aes-s6mb-lx9-g-3074457345628965461/

kcu1500

https://www.xilinx.com/products/boards-and-kits/dk-u1-kcu1500-g.html

machXO2_breakout

https://www.latticesemi.com/en/Products/DevelopmentBoardsAndKits/MachXO2BreakoutBoard

machXO3_breakout

https://www.latticesemi.com/products/developmentboardsandkits/machxo3lfstarterkit

max1000

https://shop.trenz-electronic.de/en/TEI0001-03-08-C8-MAX1000-IoT-Maker-Board-8KLE-8-MByte-RAM

Microsemi Polarfire Evaluation Kit

https://www.microsemi.com/existing-parts/parts/150789

MYIR FZ3 - Deep Learning Accelerator Card

http://www.myirtech.com/list.asp?id=630

nexys_4

https://reference.digilentinc.com/reference/programmable-logic/nexys-4/start

nexys_a7

https://store.digilentinc.com/nexys-a7-fpga-trainer-board-recommended-for-ece-curriculum

nexys_video

https://reference.digilentinc.com/reference/programmable-logic/nexys-video/start

opos6ul_sp

http://www.armadeus.org/wiki/index.php?title=OPOS6UL_SP

pipistrello

http://pipistrello.saanlima.com/index.php?title=Welcome_to_Pipistrello

QMTECH Wukong Board Artix-7 XC7A100T & XC7A200T

The Wukong board have two revisions : Artix-7 XC7A100T and Artix-7 XC7A100T-200T . The first revision have the 50 MHz clock on the wrong pin and don't have micro sd.

Targets are Wukong_v1 for revision 1 , Wukong_100t_v2 and Wukong_200t_v2 for revision 2. Those boards can be programmed with openFPGALoader.

RZ-EasyFPGA A2.x

http://fpga.redliquid.pl/

S7 Mini

https://shop.trenz-electronic.de/en/TE0890-01-25-1C-S7-Mini-Fully-Open-Source-Module-with-Xilinx-Spartan-7-7S25-64-MBit-HyperRAM

SoCKit Development Kit

https://www.terasic.com.tw/cgi-bin/page/archive.pl?Language=English&CategoryNo=167&No=816

spartan_edge_accelerator_board

https://wiki.seeedstudio.com/Spartan-Edge-Accelerator-Board/

tang_nano

https://tangnano.sipeed.com/en/

tinyfpga_bx

https://www.crowdsupply.com/tinyfpga/tinyfpga-bx

ultra96_v2

https://www.avnet.com/wps/portal/us/products/avnet-boards/avnet-board-families/ultra96-v2/

Note: There is no on-board clock for Zynq PL. Therefore, in this example PL clock is generated and supplied from Zynq PS in the block design. Block design tcl script is generated on Vivado 2020.2. If you have an other version of Vivado installation, you should just create and export the block design bd_ultra96_v2.tcl with fabric clock PL0 is enabled and made external.

ulx3s_*

https://radiona.org/ulx3s

ULX3S comes in different sizes. The targets ulx3s_45 and ulx3s_85 are defined for different FPGA sizes

Upduino 2

http://www.gnarlygrey.com/

xc6sl9_hseda_eda6.1

http://www.hseda.com/product/xilinx/XC6SLX9COREV1.0/XC6SLX9CORE.htm

zcu102

https://www.xilinx.com/products/boards-and-kits/zcu102.html

zcu106

https://www.xilinx.com/products/boards-and-kits/zcu106.html

zrtech_v2

http://land-boards.com/blwiki/index.php?title=Cyclone_IV_FPGA_EP4CE6E22C8N_Development_Board_USB_V2

Zybo Z7-10 & Zybo Z7-20

https://store.digilentinc.com/zybo-z7-zynq-7000-arm-fpga-soc-development-board/

Zybo Z7 comes with two variants of the Zynq SoC. The targets zybo_z7-10 and zybo_z7-20 are defined for different SoC configurations.