Open source hardware FPGA-based Baseboard Management Controller (BMC) platform, compliant with the DC-SCM specification developed by the Open Compute Project. Designed to help increase the security, configurability and flexibility of server management and monitoring infrastructure, the module offers a feature-packed Secure Control Interface for communication with the host platform, including PCI Express, USB, QSPI, SGPIO, NCSI and more. The board has been adopted by the LibreBMC Workgroup of the OpenPOWER Foundation. Read more about Artix DC-SCM in this Antmicro blog note.

The Arty MPW Tester is a simple expansion board compatible with Digilent Arty A7 development kit. This board connects IO signals from the Xilinx Artix FPGA located on the Arty board to an open hardware Caravel breakout board. The Caravel breakout board allows testing ASIC designs prepared for Multi Project Wafer (MPW) shuttles and fabricated with the SkyWater Process Design Kit (PDKs). You can learn more about the OpenMPW Shuttle Program by visiting this link. The Arty MPW Tester board routes the interfaces from Caravel and provides the necessary power buses.

Audio latency processing board that allows driving an external speaker and collecting audio samples from a pair of PDM or I2S microphones.

Baseboard supporting System on Modules (SoMs) with Raspberry Pi Compute Module rev. 4.0 (CM4) pinout.

Open source low-voltage differential signaling (LVDS) display adapter designed for bridging Antmicro’s CM4 Baseboard and an LCD panel with a touchscreen interface. The adapter converts MIPI DSI video input into single channel LVDS output and provides additional circuitry for integrating custom displays.

The Baseboard supports Type 7 COM Express modules. The board breaks out major communications and peripheral interfaces as defined by the COM Express standard. It also provides a backplane connector, making it possible to integrate the board into larger systems. The SolidRun LX2160A COM Express module has been used in this project. The LX2160A features 16 Arm Cortex-A72 processors, 4 x 10GbE and 18x PCIe Gen 3.0 lanes and is fully supported in Linux.

An open source video bridge converting the analog composite video (CVBS) standard into MIPI CSI-2. The video conversion is handled with Analog Devices ADV7828-M 10-bit 4x Oversampled SDTV Video Decoder. This video accessory is electrically compatible with several video processing platforms created by Antmicro, such as Jetson Baseboards, Google Coral Baseboard, Snapdragon Baseboards and the AMD-Xilinx Kria K26 DevBoard.

Power Supply Unit (PSU) breakout board compatible with Dell D1600E-S0 PSU.

An experimental platform for development of RAM controllers supporting RDIMM DDR4 RAM modules commonly used in data centers, built around the Xilinx Kintex-7 FPGA. This hardware platform is used in Antmicro's and Google's Rowhammer testing framework which can be used to perform (and potentially mitigate) Rowhammer-type attacks on DRAM memories. You can learn more about Rowhammer and our work towards mitigating it in a Google Open Source blog note describing a related platform. You can read more about this board in this Antmicro blog note.

This board allows you to develop and customize RAM controllers to implement countermeasures against Rowhammer attacks and to experiment with RDIMM DDR5 RAM modules used in data centers. The latest revision of the board contains AMD (Xilinx) Artix UltraScale Plus series FPGA in a 676-BGA package. The previous revision of the board was based on AMD (Xilinx) Kintex-7 FPGA. The on-board configuration flash can store the bitstream that is loaded at startup. In addition, a 1Gb Ethernet interface is provided to access the DDR5 Tester over the local network infrastructure. The RDIMM DDR5 Tester includes on-board 64Mb HyperRAM for storing critical runtime data. The RDIMM DDR5 Tester is one of the DRAM testing platforms supported in the open source Rowhammer Tester framework. You can learn more about the RDIMM DDR5 Tester in this Antmicro blog note.

This board targets a single DDR5 DRAM IC. It is compatible with the LPDDR4 Test Board and allows custom DRAM controller development and testing targeting single DDR5 ICs using the mature LPDDR4 test platform. The board is designed to target the Micron MT60B2G8HB-48B:A 16Gb DRAM. It can be connected to a test board to simulate Rowhammer attacks on the embedded memory module.

Experimental adapter board based on FTDI FT2232H/FT4232H IC. The board exposes the programmable IO buses from the FT2232H/FT4232H on a 2.54 mm goldpin header, allowing the implementation of many popular IO interfaces which are useful during hardware debugging.

This adapter can be used to connect Antmicro's OV5640 Dual Camera Board to a GMSL setup. The board is designed to receive two MIPI CSI-2 x2 signals from the OV5640 Dual Camera Board and output them to two GMSL Serializer Boards, which enables streaming video from both sensors over two separate GMSL links. The on-board power distribution circuit allows the Dual Camera Board to be powered by one of the selected serializer boards.

Open source hardware FPGA-based Baseboard Management Controller (BMC) platform based on Lattice ECP5 FPGA family. Compliant with the DC-SCM specification developed by the Open Compute Project. Designed to help increase the security, configurability and flexibility of server management and monitoring infrastructure, the module offers a feature-packed Secure Control Interface for communication with the host platform, including PCI Express, USB, QSPI, SGPIO, NCSI and more.

Open source board equipped with temperature, humidity and pressure sensors, designed to help monitor conditions in server rooms. The sensors are placed on a separate island that is detachable from the main PCB and can be installed directly in the required place. It provides a local storage for data logging and a battery backup for protection against data loss. The board can be used as a building block for PoC solutions for monitoring environmental parameters.

Open source board build around Antmicro's Myra SiP, equipped with temperature, humidity and pressure sensors, designed to help monitor conditions in server rooms. The sensors are placed on a separate island that is detachable from the main PCB and can be installed directly in the required place. It provides a local storage for data logging and a battery backup for protection against data loss. The board can be used as a building block for PoC solutions for monitoring environmental parameters.

PCB supporting a pair of LEDs in the LZ1 LuxiGen package from OSRAM. The PCB includes a flickerless LED driver allowing it to adjust LED brightness with a potentiometer. This design can be easily adopted to other LEDs and eventually can become a custom LED driver providing precise lighting for machine vision applications.

This small and lightweight board connects to the FRAMOS Sensor Module Adapter (FSA) and exposes a 30-wire I-PEX micro coax cable. The adapter board is the same size as the FSA and can be stacked with it. The adapter board can be interfaced with a variety of video processing platforms created by Antmicro using the Dual I-PEX CSI Interposer. The I-PEX connector can be optionally replaced with an FFC. Additionally, the FRAMOS CSI Adapter includes circuitry which makes it electrically compatible with the MIPI camera interfaces exposed on Antmicro’s platforms. You can learn more about the adapter on Antmicro's blog

GMSL Deserializer Board capable of translating up to 4 GMSL signals into 2x 4-lane MIPI CSI-2 interface. The board is designed to connect to a baseboard, e.g. Jetson Orin Baseboard, via 50pin FFC.

Board accepting MIPI CSI-2 signals from Antmicro's 50-pin FFC video interface and transmitting the video data over GMSL2. The GMSL Serializer Board is powered over GMSL coaxial cable.

Compute Cluster Backplane board allowing for connection up to 8 Thunderbolt GPU adapters. PCB is compatible with Dell D1599E-S0 PSU.

Open source board for converting HDMI video stream into MIPI CSI-2. It includes two independent conversion channels supporting up to two HDMI streams. The board exposes MIPI CSI-2 data on a unified 50-pin FFC connector which is electrically compatible with a variety of processing platforms designed by Antmicro.

Simple detector of infrared (IR) radiation. It features two photodiodes with peak sensitivity of 900nm and 940nm, and signal-forming circuitry with adjustable gain. The board can be used for measuring relative intensity of IR radiation and for probing dynamic illumination parameters of infrared LEDs and laser modules.

Open source CSI camera adapter designed to be used with Nvidia Jetson AGX platform devkits (Orin, Xavier). This device separates the camera module interface connector into two 50-pin flat cable connectors, which are compatible with a variety of video accessories developed by Antmicro.

Open source baseboard supporting the NVIDIA Jetson Nano, Xavier NX, and TX2 NX SoMs. The board will let you take advantage of the processing power the Jetson Nano offers in numerous possible ways by exposing several interfaces, e.g. the board can be interfaced with MIPI CSI-2 video devices through a unified Flexible Flat Cable (FFC) connector, supporting up to 4 sensors in a 2-lane configuration or 3 sensors in a 4-lane configuration. Read more about the Jetson Nano Baseboard on Antmicro’s blog.

World's first open-source baseboard supporting NVIDIA Jetson Orin Nano and Jetson Orin NX System-on-Modules, and successor to the greatly popular Jetson Nano Baseboard. The board will help you harness Orin NX's performance while offering plenty of flexibility - it can be powered using three possible sources (PoE included), features an array of interfaces, and offers compatibility with a range of video accessories developed by Antmicro (e.g. adapters for FRAMOS and Allied Vision cameras). All that while fitting within a 120 x 60 mm footprint. Read more about the Jetson Orin Baseboard on Antmicro's blog.

Expansion board compatible with Jetson Orin Baseboard. It ncludes a MicroSD card slot and an M.2 (key-M) slot intended for connecting additional storage solutions to the Jetson Orin Baseboard. The M.2 slot supports 2280 and 2242 M.2 NVMe discs.

A versatile development board employing one of the bigger FPGAs from the AMD-Xilinx Kintex-7 family. It includes additional external peripheral ICs and I/O connectors for fast-turnaround prototyping via expansion boards. The 10-layer PCB has a compact size of a nano-ITX board (120x120mm) and supports multiple power supply scenarios, including PoE (Power over Ethernet), USB-C PD (Power Delivery), and External PSU via DC Jack. The board also includes 8 indicator LEDs and multiple user inputs from 4 push buttons and 8 dip switches.

A devboard created for AMD-Xilinx Kria K26 System on Module (SoM), aimed at hardware accelerated vision AI and video analytics solutions. The board includes a 50-pin camera connector which exposes two 4-lane MIPI CSI-2 interfaces. This camera connector is electrically compatible with a broad range of open source video accessories created by Antmicro, such as OV9281 Dual Camera Board, SDI-MIPI bridge and HDMI-MIPI bridge. The board supports multiple power supply scenarios, including PoE (Power over Ethernet), USB-C PD (Power Delivery), and External PSU via DC Jack. You can read more about the devkit in this Antmicro blog note.

An experimental platform built around the Xilinx Kintex-7 FPGA intended for development and customization of RAM controllers supporting LPDDR4 ICs. The board is supported by the Rowhammer Tester platform developed for mitigating memory vulnerabilities. Read more about the open source LPDDR4 test platform on Antmicro’s blog.

An experimental breakout board for a single 200-ball WFBGA LPDDR4 chip in SO-DIMM DDR4 form factor. It’s one of the easily swappable testbeds for different memory types compatible with the LPDDR4 Test Board, which allows for easy, repeatable testing of multiple versions of the LPDDR4 IC with the same base platform. Please note that this board is not electrically compatible with off-the-shelf SO-DIMM DDR4 memory modules.

An experimental test module in a mechanical form of SO-DIMM DDR5. The module includes a standard 315-ball WFBGA (12.4mm × 15.0mm × 0.8mm, Ø0.42 SMD) LPDDR5 RAM footprint break-routed in the SO-DIMM edge connector. The design files were prepared in KiCad. Please note that this board is not electrically compatible with off-the-shelf SO-DIMM DDR5 memory modules. It is compatible with this test platform.

Adapter card, that fits into M.2 (key M) 2280 slot and exposes PCIe on a regular PCIe x4 edge card socket. This board has been designed as an extension of the Antmicro's Jetson Nano Baseboard. However it is also operable with other Antmicro's Baseboards whith M.2 slot (such as Jetson Orin Baseboard and CM4 Baseboard) It allows the use of regular PCIe expansion cards and accessories with the NVIDIA Jetson Nano and NVIDIA Jetson Xavier NX system on modules.

Microphone board with an SPH0644LM4H-1 PDM microphone. The board break-routes PDM signals from the microphone to a zero insertion force connector. Additionally, the board provides voltage filtering and ESD protection.

Compact system on chip inteposer, designed to replace MCU, FRAM and USB to UART converter with single chip. Features STM32G491REI6 MCU, 128kB FRAM, FTDI FT231XQ USB to UART converter.

Dual camera module equipped with a pair of 5-megapixel OmniVision OV5640 image sensors. The board includes mounting holes for standard S-Mount (M12) lens holders. Each image sensor can be connected to a host platform via a separate 2-lane MIPI CSI-2 interface.

Dual camera module equipped with a pair of 1-megapixel OmniVision OV9281 image sensors. The board includes mounting holes for standard S-Mount (M12) lens holders. Each image sensor can be connected to a host platform via a separate 2-lane MIPI CSI-2 interface.

Antmicro PolarFire System on Module (SoM) built around Microchip PolarFire MPFS250T RISC-V System on Chip. The SoM exposes two 100-pin high density connectors with signal assignment that is electrically compatible with Raspberry Pi Compute Module 4.

The QuickFeather development board is based on the QuickLogic EOS S3 Sensor Processing Platform. It was designed by Antmicro in cooperation with QuickLogic. The board has been designed to keep compatibility with the Adafruit Feather ecosystem of evaluation boards, which allows the user to explore functionalities of the EOS S3 platform.

The Snapdragon 845 Baseboard is a compact-sized (100x70mm/4x2.75 inch) carrier board for the Quectel SA800U-WF System on Module. The SA800U-WF features an octa-core Qualcomm Snapdragon 845 System on Chip based on the Kryo 385 64-bit CPU and the Adreno 630 GPU. The SoC also includes radio transceivers for dual-band (2.4GHz/5GHz) WiFi and Bluetooth 5.0, while the SoM includes on-board antenna ports which simplify the antenna integration process.

The Snapdragon 625 Baseboard is a compact-sized (100x80mm/4x3.1 inch) carrier board for the Quectel SC606T System on Module. The SC606T features an octa-core Qualcomm Snapdragon 625 System on Chip based on the ARM Cortex-A53 64-bit CPU and the Adreno 506 integrated GPU. The SoC also includes radio transceivers for dual-band (2.4GHz/5GHz) WiFi, Bluetooth 4.2 and LTE Cat 6 modem, while the SoM includes on-board antenna ports which simplify the antenna integration process.

A small and scalable open source compute node supporting System on Modules with pinout compatible with Raspberry Pi Compute Module 4 (CM4). Optimized for 19-inch rack mount installations for distributed multi-node computing systems, the board features an M.2 key M PCIe connector for SSD storage or add-on boards that can be used for AI acceleration. You can read more about the Scalenode CM4 Baseboard on Antmicro’s blog

Open source SDI to MIPI CSI-2 bridge. This device allows you to connect SDI inputs over long distances using a single coaxial cable to the otherwise short-range (but extremely popular and widely available) MIPI CSI-2 interface. Compatible with the (Jetson Nano Baseboard). You can read more about this board on Antmicro’s blog.

SDI-to-MIPI bridge based on the Lattice CrossLink-NX FPGA that allows SDI-based systems to harness the power of embedded AI platforms. It allows you to connect SDI inputs over long distances using a single coaxial cable to the otherwise short-range (but extremely popular and widely available) MIPI CSI-2 interface. The board has enabled various customer projects where the bridge is used together with Antmicro’s MIPI CSI-2 capable open hardware platforms, including the NVIDIA Jetson Baseboard or Snapdragon 845 Baseboard. You can read more about the board in this Antmicro blog note.

Test board implementing various routing topologies. The board can be used for calibrating and comparing measurements of signal propagation properties with Vector Network Analyzers (VNAs). It can also be used for SI, EMI or EMC simulations with field solvers.

This board allows you to develop and customize RAM controllers to implement countermeasures against Rowhammer attacks and to experiment with SO-DIMM DDR5 modules. The board contains a Xilinx Kintex-7 series FPGA in a 676-BGA package and a single USB 2.0 interface that provides access to a 4-channel FTDI transceiver to enable FPGA reconfiguration and access to the debug console. The on-board configuration flash can store the bitstream that is loaded at startup. In addition, the board provides a 1Gb Ethernet interface to enable access to the SO-DIMM DDR5 Tester over the local network infrastructure, as well as an on-board 64Mb HyperRAM for storing critical runtime data.

Adapter board wrapping 4-lane (i.e. 4x) PCIe Gen 3.0 devices into a Thunderbolt 3 uplink. It is based on the Intel/JHL6340SLLSQ Thunderbolt controller.

Open source adapter exposing PCIe over Thunderbolt. Offers high throughput and low latency and allows for range extension. It is based on the Intel/JHL6340SLLSQ Thunderbolt controller. Compatible with NVIDIA Jetson Orin SoMs through the Jetson Orin Baseboard.

The USB-C Power Delivery Adapter is a module providing 12V 55W continuous power output from a single USB-C PD power supply. The board was designed as a power option for Antmicro's Thunderbolt to GPU Adapter in stand-alone operation.