This repository contains a KiCad PCB project for an open hardware board design that allows to improve the quality of HDMI video signals transmitted over long cables.
- HDMI signal preconditioning with a pair of PTN3363 HDMI level shifters.
- Signal equalization controlled with on-board DIP-Switch
- On-board SiLabs EFM32HG322F64 MCU for interactive control and board monitoring
- Supports different EDID connection scenarios
The board has been mechanically optimised for usage with the Numato Opsis open video capture device. It is possible to use it with different platforms using HDMI extender cables.
It follows the data flow diagram presented below:
Please refer to KiCad schematic files for more information regarding hardware functionalities implemented in the design.
The PCB layout has been defined with a 4-layer stackup.
Please check the geometry of differential traces implemented in the design with stackup offered by PCB vendor for optimal impedance match of HDMI traces.
There is a BOM document generated from the schematics and shared in this repository.
Please short the J5,J7,J8,J12
solder jumpers on the bottom side of the PCB.
This will relay the EDID signals on both HDMI channels from input to output.
Short the J11,J4
jumpers if you plan to experiment with the provided example MCU firmware.
This will make the on-board MCU accessible on EDID bus driven from J2
HDMI input connector.
Please check the schematics and software codebase for any other jumper configuration.
The EFM32 MCU used in the design comes with a factory programmed AN0042
bootloader.
In order to make the MCU compatible with the provided example firmware it is advisable to replace the default bootloader with Toboot
over SWD interface using OpenOCD.
The SWD signals from the MCU are exposed on test pads marked with IO
and CLK
on the bottom side of the Video Booster Board.
Additionally there are test pads with system ground and power supply exposed next to them.
To upload the Toboot
bootloader, please follow this instruction.
Be aware that the provided flashing instruction was originally created for a different hardware platform so the SWD connection wiring differs a little.
There is an example-firmware
folder included in this repository, which contains a sample firmware driven by the RTOS derived from the Zephyr project.
The firmware makes the on-board EFM32 MCU act as an EDID slave for the transmitting device.
In order to build the example firmware please use the following commands:
git clone https://github.com/antmicro/video-signal-booster-board cd video-signal-booster-board git submodule update --init --recursive cd example-firmware python3 -m pip install -r zephyr/scripts/requirements.txt wget https://github.com/zephyrproject-rtos/sdk-ng/releases/download/v0.10.3/zephyr-sdk-0.10.3-setup.run chmod +x zephyr-sdk-0.10.3-setup.run ./zephyr-sdk-0.10.3-setup.run -- -d <zephyr_installation_path> export ZEPHYR_TOOLCHAIN_VARIANT=zephyr export ZEPHYR_SDK_INSTALL_DIR=<zephyr_installation_path> source zephyr/zephyr-env.sh west init -l zephyr west update make
Once the firmware is compiled, connect the micro USB cable to the Video Booster Board and upload the firmware using the following command:
dfu-util -d 1209:70b1 -D build/zephyr/zephyr.bin
Please note that in this setup the firmware doesn't stick permanently. After a power cycle a bootloader will start again. This simplifies the developing process.
The example firmware makes the MCU on Video Booster Board accessible on I2C/EDID bus slave device under the address of 0x3a
(7-bit notation).
It's possible to test the I2C/EDID communication by connecting an I2C master device to TX source HDMI connector (J2
).
The example firmware makes MCU offer a single 8-bit configuration register.
Two least significant bits of this register control the states of the TX_EQ0
and TX_EQ1
signals that define the equalization settings of U3
HDMI level shifter.
The states of those signals are also displayed on D8
D9
LEDs installed on board.
A sample Python code that would drive the MCU over I2C bus is:
python import smbus bus = smbus.SMBus(<i2c_bus_number>) bus.write_byte_data(0x3a, 0x00, 0x03)
There is also a 3D-printable enclosure available in the 3d-models
directory.
The enclosure allows the electronics to be covered and attaches the Video Booster Board to the Numato board installed in a typical thin mini-ITX chassis.