Turn your Raspberry Pi, Nvidia Jetson, Orange Pi, Windows PC, Mac, Linux box, or nearly any Python-compatible system into a ninja-cam with hardware-acceleration enabled! This lets you publish live streaming video and audio directly to your web browser or OBS instance using VDO.Ninja. Achieve very low streaming latency over the Internet or a LAN; all for free.
It also has the ability to record remote VDO.Ninja streams to disk (no transcode step), it can broadcast a low-latency video stream to multiple viewers (with a built-in SFU) at time, and because it works with VDO.Ninja, you get access to its ecosystem and related features. There are other cool things available, such as AV1 support, NDI output, OpenCV output, WHIP, and fdsink output.
Table of Contents
The core concepts and code used in this project can be reused for other projects; most Linux systems, and a large variety of embedded systems; potentially even smartphones. There's a focus of supporting Raspberry Pis and Nvidia Jetson systems, which includes offering pre-built images and install scripts. Other Linux system users should still be able to use the code, but setup support will be limited.
Youtube video demoing: https://youtu.be/J0qqXxHNU_c
I also have another longer YouTube video here, which focuses on setting up the Raspberry_ninja for IRL-streaming.****
Recent updates to Raspberry Ninja have added improved error correction and video redundency, along with automated dynamic bitrate controls for congestion management. This has greatly improved stream reliabilty, reducing frame loss, and limiting buffer sizes. That said, having more than 5-megabites of upload bandwidth and having a solid connection is recommend if intending to use the default settings.
See below for different install options
See the raspberry_pi
sub-folder for instructions on installing and setting up a Raspberry Pi. Jump there now
A Raspberry Pi works fairly well with a CSI-connected camera, but USB-based cameras currently struggle a bit with older Raspberry Pi models. As a result, consider buying an Nvidia Jetson Nano 2GB instead of a Raspberry Pi if looking to jump into this all. Also, the RPI Zero W 1 and RPi 3 both don't have the greatest WiFi built-in, while the Raspberry Pi Zero 2 seems to work rather well. Without good connectivity, you may find yourself facing frame-drops and stutter. HDMI to CSI adapters do work, but they may be limited to 25-fps and can be finicky still with some camera sources; audio over HDMI is also a bit tricky to setup currently.
Please see the nvidia_jetson
folder for details on installation. Jump there now
Nvidia Jetsons work well with USB-connected cameras and have a selection of compatible CSI-cameras well. You may need to buy WiFi adapter if it is not included.
You can deploy Raspberry.Ninja to a desktop pretty quickly in most cases, without compiling anything. I have an installer for recent versions of Ubuntu if interested. Jump there now
For other distros, see below for requirements
You'll want to install Gstreamer 1.16 or newer; emphasis on the newer. You'll need to ensure libnice
, srtp
, sctp
, and webrtcbin
are part of that install, along with any media codecs you intend to use.
Python3 is also required, along with websockets
. If you have PIP installed, pip3 install websockets
can get you going there.
You can actually run Raspberry Ninja on a Windows PC via the WSL virtual machine interface. It's really quick and simple, except getting camera/hardware support going is tricky.
Still, it might be useful if you want to pull a stream from a remote Raspberry.Ninja system, recording the stream to disk or using it for local machine learning.
See the WSL install script here: Jump there now
It is possible to install Gstreamer for Windows natively, but due to the difficultly in that all, I'm not supporting it officially at present. The main challenge is cairo
fails to compile, so that needs to be fixed first.
Raspberry.Ninja can even run on a Mac! Although it's not as streamlined a process as it could be, I'd say the difficulty is 4/10.
See the Mac OS X install script here: Jump there now
Many modern versions of Linux distributions, such as Ubuntu 22, support Raspberry.Ninja with minimal installation effort.
The basic install script for Ubuntu-like systems is as below:
sudo apt-get update && sudo apt upgrade -y
# Use a virtual environment or delete the following file if having issues
sudo rm /usr/lib/python3.11/EXTERNALLY-MANAGED ## For Debian 12-based systems
sudo apt-get install python3-pip -y
sudo apt-get install -y libgstreamer1.0-dev libgstreamer-plugins-base1.0-dev libgstreamer-plugins-bad1.0-dev gstreamer1.0-plugins-base gstreamer1.0-plugins-good gstreamer1.0-plugins-bad gstreamer1.0-plugins-ugly gstreamer1.0-libav gstreamer1.0-tools gstreamer1.0-x python3-pyqt5 python3-opengl gstreamer1.0-alsa gstreamer1.0-gl gstreamer1.0-qt5 gstreamer1.0-gtk3 gstreamer1.0-pulseaudio gstreamer1.0-nice gstreamer1.0-plugins-base-apps
pip3 install websockets
pip3 install cryptography
sudo apt-get install -y libcairo-dev ## possibly optional
pip3 install PyGObject ## possibly optional
sudo apt-get install git -y
cd ~
git clone https://github.com/steveseguin/raspberry_ninja
cd raspberry_ninja
python3 publish.py --test
Package managers with old versions of Gstreamers, or with no hardware acceleration or limited codec support, may be limited in what Raspberry.Ninja can offer. For the most up-to-date and comprehensive feature set, compiling Gstreamer from scratch may be still needed.
If wanting to use AV1 streaming, you'll need to install gst-plugins-rs
as well (av1parse
and av1pay
are needed), plus whatever AV1 encoder you wish to use.
Major updates sometimes will require that the latest Rasbperry Pi or Jetson image be installed on your device, but most updates are minor and only require the publish.py
file to be updated. If you've just installed the latest device image, you will still want to update before going further, as the image is not updated with every new code release.
You can normally update by logging into your device, either via SSH, or via mouse/keyboard with the terminal app open.
cd ~
cd raspberry_ninja
git pull
That's it.
If you run into issues due making changes to the code, you can either git stash
your changes first, or you can just delete the raspberry_ninja folder and clone it again.
ie:
cd ~
rm raspberry_ninja -r
git clone https://github.com/steveseguin/raspberry_ninja
cd raspberry_ninja
Updates are usually optional, as they typically just focus on added features or improving video quality/stability. I do recommend checking for new updates every now and then.
You should be able to run the publshing script simply with python3 publish.py
, however lots of options are available for customizing as desired.
$ python3 publish.py
To get the list of supported commands with your version of the code, run python3 publish.py --help
.
Sample help output: ( what's shown below may not be up-to-date)
usage: publish.py [-h] [--streamid STREAMID] [--room ROOM] [--rtmp RTMP] [--whip WHIP] [--bitrate BITRATE]
[--audiobitrate AUDIOBITRATE] [--width WIDTH] [--height HEIGHT] [--framerate FRAMERATE]
[--server SERVER] [--puuid PUUID] [--test] [--hdmi] [--camlink] [--z1] [--z1passthru]
[--apple APPLE] [--v4l2 V4L2] [--libcamera] [--rpicam] [--format FORMAT] [--rotate ROTATE]
[--nvidiacsi] [--alsa ALSA] [--pulse PULSE] [--zerolatency] [--raw] [--bt601] [--h264] [--x264]
[--openh264] [--vp8] [--vp9] [--aom] [--av1] [--rav1e] [--qsv] [--omx] [--vorbis] [--nvidia] [--rpi]
[--multiviewer] [--noqos] [--nored] [--novideo] [--noaudio] [--led] [--pipeline PIPELINE]
[--record RECORD] [--view VIEW] [--save] [--midi] [--filesrc FILESRC] [--filesrc2 FILESRC2]
[--pipein PIPEIN] [--ndiout NDIOUT] [--fdsink FDSINK] [--framebuffer FRAMEBUFFER] [--debug]
[--buffer BUFFER] [--password [PASSWORD]] [--hostname HOSTNAME] [--video-pipeline VIDEO_PIPELINE]
[--audio-pipeline AUDIO_PIPELINE] [--timestamp] [--clockstamp]
options:
-h, --help show this help message and exit
--streamid STREAMID Stream ID of the peer to connect to
--room ROOM optional - Room name of the peer to join
--rtmp RTMP Use RTMP instead; pass the rtmp:// publishing address here to use
--whip WHIP Use WHIP output instead; pass the https://whip.publishing/address here to use
--bitrate BITRATE Sets the video bitrate; kbps. If error correction (red) is on, the total bandwidth used may be
up to 2X higher than the bitrate
--audiobitrate AUDIOBITRATE
Sets the audio bitrate; kbps.
--width WIDTH Sets the video width. Make sure that your input supports it.
--height HEIGHT Sets the video height. Make sure that your input supports it.
--framerate FRAMERATE
Sets the video framerate. Make sure that your input supports it.
--server SERVER Handshake server to use, eg: "wss://wss.vdo.ninja:443"
--puuid PUUID Specify a custom publisher UUID value; not required
--test Use test sources.
--hdmi Try to setup a HDMI dongle
--camlink Try to setup an Elgato Cam Link
--z1 Try to setup a Theta Z1 360 camera
--z1passthru Try to setup a Theta Z1 360 camera, but do not transcode
--apple APPLE Sets Apple Video Foundation media device; takes a device index value (0,1,2,3,etc)
--v4l2 V4L2 Sets the V4L2 input device.
--libcamera Use libcamera as the input source
--rpicam Sets the RaspberryPi CSI input device. If this fails, try --rpi --raw or just --raw instead.
--format FORMAT The capture format type: YUYV, I420, BGR, or even JPEG/H264
--rotate ROTATE Rotates the camera in degrees; 0 (default), 90, 180, 270 are possible values.
--nvidiacsi Sets the input to the nvidia csi port.
--alsa ALSA Use alsa audio input.
--pulse PULSE Use pulse audio (or pipewire) input.
--zerolatency A mode designed for the lowest audio output latency
--raw Opens the V4L2 device with raw capabilities.
--bt601 Use colormetery bt601 mode; enables raw mode also
--h264 Prioritize h264 over vp8
--x264 Prioritizes x264 encoder over hardware encoder
--openh264 Prioritizes OpenH264 encoder over hardware encoder
--vp8 Prioritizes vp8 codec over h264; software encoder
--vp9 Prioritizes vp9 codec over h264; software encoder
--aom Prioritizes AV1-AOM codec; software encoder
--av1 Auto selects an AV1 codec for encoding; hardware or software
--rav1e rav1e AV1 encoder used
--qsv Intel quicksync AV1 encoder used
--omx Try to use the OMX driver for encoding video; not recommended
--vorbis Try to use the OMX driver for encoding video; not recommended
--nvidia Creates a pipeline optimised for nvidia hardware.
--rpi Creates a pipeline optimised for raspberry pi hardware encoder. This wont work with the
Raspberry Pi 5, as it has no hardware encoder..
--multiviewer Allows for multiple viewers to watch a single encoded stream; will use more CPU and bandwidth.
--noqos Do not try to automatically reduce video bitrate if packet loss gets too high. The default
will reduce the bitrate if needed.
--nored Disable error correction redundency for transmitted video. This may reduce the bandwidth used
by half, but it will be more sensitive to packet loss
--novideo Disables video input.
--noaudio Disables audio input.
--led Enable GPIO pin 12 as an LED indicator light; for Raspberry Pi.
--pipeline PIPELINE A full custom pipeline
--record RECORD Specify a stream ID to record to disk. System will not publish a stream when enabled.
--view VIEW Specify a stream ID to play out to the local display/audio.
--save Save a copy of the outbound stream to disk. Publish Live + Store the video.
--midi Transparent MIDI bridge mode; no video or audio.
--filesrc FILESRC Provide a media file (local file location) as a source instead of physical device; it can be a
transparent webm or whatever. It will be transcoded, which offers the best results.
--filesrc2 FILESRC2 Provide a media file (local file location) as a source instead of physical device; it can be a
transparent webm or whatever. It will not be transcoded, so be sure its encoded correctly.
Specify if --vp8 or --vp9, else --h264 is assumed.
--pipein PIPEIN Pipe a media stream in as the input source. Pass `auto` for auto-decode,pass codec type for
pass-thru (mpegts,h264,vp8,vp9), or use `raw`
--ndiout NDIOUT VDO.Ninja to NDI output; requires the NDI Gstreamer plugin installed
--fdsink FDSINK VDO.Ninja to the stdout pipe; common for piping data between command line processes
--framebuffer FRAMEBUFFER
VDO.Ninja to local frame buffer; performant and Numpy/OpenCV friendly
--debug Show added debug information from Gsteamer and other aspects of the app
--buffer BUFFER The jitter buffer latency in milliseconds; default is 200ms. (gst +v1.18)
--password [PASSWORD]
Specify a custom password. If setting to false, password/encryption will be disabled.
--hostname HOSTNAME Your URL for vdo.ninja, if self-hosting the website code
--video-pipeline VIDEO_PIPELINE
Custom GStreamer video source pipeline
--audio-pipeline AUDIO_PIPELINE
Custom GStreamer audio source pipeline
--timestamp Add a timestamp to the video output, if possible
--clockstamp Add a clock overlay to the video output, if possible
Using gst-device-monitor-1.0
will list available devices and their 'caps', or settings. This can help determine what GStreamer pipeline changes need to be made in the script or getting info about what video format options are available for your device.
To help further debug, gst-launch-1.0
can be used to test a pipeline out before adding it to the script. For for added reference, here is an example Pipeline for the Rasbperry Pi to enable UVC-based MJPEG video capture support is:
gst-launch-1.0 v4l2src device=/dev/video0 io-mode=2 ! image/jpeg,framerate=30/1,width=1920,height=1080 ! jpegparse ! nvjpegdec ! video/x-raw ! nvvidconv ! "video/x-raw(memory:NVMM)" ! omxh264enc ! "video/x-h264, stream-format=(string)byte-stream" ! h264parse ! rtph264pay config-interval=-1 ! application/x-rtp,media=video,encoding-name=H264,payload=96 ! fakesink
Notice how we used device = OUR_AUDIO_DEVICE_NAME to specify the audio device we want to use, and we configure the device to read and decode JPEG, as that is what our device in this case supports.
The Raspberry_Ninja publish.py script automatically tries to create a pipeline for you, based on the command line arguments passed, but you can override that at a code level with your own pipeline if easier as well.
The script will use the default system ALSA audio output device, although you can override that using the command line arguments or via manually setting a gstreamer pipeline at the code level.
To get details of available audio devices, assuming pulseaudio is installed, running the following from the command line will give us access to audio device IDs
pactl list | grep -A2 'Source #' | grep 'Name: ' | cut -d" " -f2
resulting in..
alsa_input.usb-MACROSILICON_2109-02.analog-stereo
alsa_output.platform-sound.analog-stereo.monitor
alsa_input.platform-sound.analog-stereo
In this example, an HDMI audio source is the first in the list, so that is our device name. Your device name will likely vary.
Pulse audio and ALSA audio command-line arguments can be passed to setup audio, without needing to tweak Gstreamer pipelines manually. The defaults I think will use the system ALSA default device.
Ensure the pi/jetson is connected to the Internet, via Ethernet is recommended for best performance. You'll also very likely need to ensure a camera and/or microphone input are connected; this can also be a USB UVC device, supported CSI-based camera, or other selectable media inputs. It technically might be possible to even select a pipe to stream from, although this is a fairly advanced option.
Run using:
python3 publish.py --streamid SomeStreamID --bitrate 2000
In Chrome, open this link to view:
https://vdo.ninja/?password=false&view=SomeStreamID
You can have multiple viewers at a time, but you must enable that with a command-line argument.
Also note, if you run with sudo
, you might get a permissions error when using audio.
A guide on how to setup a RPI to auto-stream on boot can be found in the Rasbperry Pi folder, along with details on how to configure the WiFi SSID and password without needing to SSH in first.
RTMP support overrides WebRTC support at the moment, and the features that are support are pretty limited.
python3 publish.py --rtmp rtmp://a.rtmp.youtube.com/live2/z4a2-q14h-01gp-xhaw-3zvw --bitrate 6000
Things like bitrate, width, height, raw, framerate are also supported, but not a whole lot else.
RTMP support is currently experimental; example use with a Jetson here: https://www.youtube.com/watch?v=8JOn2sK4GfQ
You can't publish to vdo.ninja with RTMP, but rather a service like YouTube.
I have added SRT support to the Raspberry Pi image. You need to use it via Ffmpeg or Gstreamer via command line currently, as I haven't added it to the Raspberry Ninja code directly yet. Still, it's easy enough to publish via command line with SRT, and you get the benefits of an up-to-date Raspberry Pi image with drivers and software all pre-installed.
I added WHIP/WHEP dependencies to the Raspberry Pi x64 pre-built image already (av1-whip support excluded), but for other users you may need to ensure you have the gst-plugins-rs
installed to get WHIP out working. This may also mean you'll need Gstreamer 1.22 installed. If you want to use AV1, you'll also need to ensure you have an AV1 encoder available within Gstreamer; there's a few good options there.
The WHIP output support within Raspberry Ninja is added by means of the Gstreamer's whipsink whepsrc Rust-based plugins.
To use, you can just do:
python3 publish.py --whip "https://yourwhipurl.com/here" --test
The gst-launch-1.0 command line that's printed to screen can be run on its own after, without Raspberry Ninja in cases, as Raspberry Ninja doesn't need to make use of Websockets or other logic when dealing with WHIP.
You can test this out live using VDO.Ninja still, as VDO.Ninja supports WHIP playback without needing your own SFU or server. Just open https://vdo.ninja/alpha/?whip=XXXXXX123 in your browser FIRST, and then run the following command line:
python3 publish.py --whip "https://whip.vdo.ninja/XXXXXX123" --test
You should see your video play on the VDO.Ninja website within a few seconds after you start publishing, and there should be audio included.
Please note that you don't need Raspberry Ninja to use WHIP, but Raspberry Ninja will handle all the Gstreamer pipelining, audio/video device detection, and I am open to feature requests.
As noted above, you can just re-use the gstreamer pipelines outputted by Raspberry Ninja when using WHIP output, but below I offer you a few test pipelines you can try from the command line to get you started there without Raspberry Ninja:
# To view the stream, FIRSTLY, open this link:
https://vdo.ninja/alpha/?whip=XXXXXX123
# to publish h264 to that viewer, use the following
gst-launch-1.0 videotestsrc ! videoconvert ! x264enc ! rtph264pay ! whipsink whip-endpoint="https://whip.vdo.ninja/XXXXXX123"
# or to publish av1 to that viewer, use the following:
gst-launch-1.0 videotestsrc ! av1enc usage-profile=realtime ! av1parse ! rtpav1pay ! whipsink whip-endpoint="http://whip.vdo.ninja/XXXXXX123"
In this case, we're publishing direct to the browser, so it needs to be opened first, as we're using VDO.Ninja to do the WHIP playback without WHEP.
You can find many more WHIP/WHEP options within VDO.Ninja, and a great place to start playing is at https://vdo.ninja/alpha/whip. This page offers a web-based WHIP/WHEP player/publisher, as well as support for SVC, insertable streams, and all the advantages of VDO.Ninja in a simple to use web interface.
As for Meshcast support, Meshcast is getting WHIP-ingest support; the availability of this update is just peng some more testing and deployment.
You can set your own custom video and audio device, as shown below, if you want more control over the inputs. The encoder portion is still handled by the code.
python publish.py --rpi --video-pipeline "v4l2src device=/dev/video0 ! video/x-raw,framerate=30/1,format=UYVY" --noaudio --debug
Avoid apostrophes in your pipelines, as that can cause a syntax issue, and you shouldn't need to escape the brackets.
--video-pipeline and --audio-pipeline are available.
--format
can specify what the encoder should be expecting, if that's needed. ie: --format YUYV
I've added support to send VDO.Ninja streams to an NDI playout sink.
For Windows WSL, there's an install script here: https://github.com/steveseguin/raspberry_ninja/blob/main/wsl/install_ndi.sh, however please make sure Rust (cargo) is installed first.
You can access WSL on Window by typing wsl
into the Windows command prompt. Once you install Raspberry.Ninja, as per the WSL install instructions, you can install the NDI support, with the following:
curl --proto '=https' --tlsv1.2 -sSf https://sh.rustup.rs | sh
source ~/.bashrc
wget https://raw.githubusercontent.com/steveseguin/raspberry_ninja/main/wsl/install_ndi.sh
chmod +x install_ndi.sh
./install_ndi.sh
You'll also need NDI tools installed for Windows.
Once you have all that setup, you can run python3 publish.py --ndiout STREAMIDHERE
, and the remote VDO.Ninja media stream should be available via NDI afterwards. You may need to refresh your NDI viewer to get it working. As well, sometimes after you stop the NDI feed, and restart the stream, you'll need to wait one or two minutes, else it won't work. I don't know why yet, but there is a short cool down period needed before it will work again.
If nothing happens when you run python3 publish.py --ndiout someTestStream123
, check that Rust is actually installed, and then confirm gst-inspect-1.0 | grep "ndi"
lists NDISink.
NDI support should be something you can get working on vanilla Ubuntu and MacOS as well, but I don't have an install script for that yet.
Note: NDI support for publishing is yet to be added. H264/OPUS is tested mainly.
There's support for OpenCV/Framebuffer (--framebuffer STREAMIDHERE) and FDSink now. There's a Youtube video link below demoing how to use Raspberry.Ninja to bring raw BGR video frames into Numpy.
https://www.youtube.com/watch?v=LGaruUjb8dg
This should allow you to use Tensorflow, OpenCV, or whatever Python script to access the webRTC video stream as raw frames. You can also use it to turn a webRTC stream into a motion-JPEG stream, useful if needing to publish to a device that doesn't support webRTC. ie: Octoprint 3d printer server supports a MJPEG video preview link, but not a webRTC link.
Of the Raspberry Pi devices, the Raspberry Pi 4 or the Raspberry Pi Zero 2 are so far the best options on this front, depending on your needs. Any of the Nvidia Jetson devices should work fine, but only the Jetson Nano 2GB, 4GB, and NX have been tested and validated. If you wish to use other Jetson devices, you'll need to setup and install Gstreamer 1.19 yourself on those systems, as no pre-built image will be provided at this time. (Unless someone wishes to donate the hardware that is) Any other Linux system or SBC embedded system is on the user to setup and install at this point, but they should closely follow the same steps that the Nvidia Jetson uses.
It's rather hard to install everything needed on a Raspberry Pi Zero 2 directly, due to the limited memory, so I do recommend that if installing from scratch that you use a Raspberry Pi 4 with 4GB or greater.
There's plenty of options for the Rasbperry Pi and Nvidia Jetson when it comes to cameras and HDMI adapters. The easiest option for a Raspberry Pi is to use one of the official Raspberry Pi camera. These are normally just plug an play on both platforms and well supported.
USB cameras are options, but currently with Raspberry Pi devices these are only supported up to around 720p30. USB 3.0 devices are even less supported, as you need to ensure the Raspberry Pi you are using supports USB 3.0; for example, a Camlink will not work on a Raspberry Pi 3.
If low-light is important to you, the Sony IMX327 and IMX462 series of sensors might appeal to you. They are generally designed for security camera applications, but with the use of an IR Filter, you can make them adequate for use a standard video cameras. These options may require additional gstreamer and driver work to have work however, so they are for more advanced-users at this time.
I have gotten the low-light Arducam IMX462 to work with the newest image for RPI working (with the bullseye images). It might require a small change to the dtoverlay
line in the /boot/config.txt
file though to configure your specific camera, but I think I have most working now without any need drivers. (a few exceptions) , oh, and if you are changing dtoverlay
, you might need to also comment out the camera auto detect link that is also in the config.txt file. (else it might not work)
Links for such low-light cameras:
https://www.uctronics.com/arducam-for-raspberry-pi-ultra-low-light-camera-1080p-hd-wide-angle-pivariety-camera-module-based-on-1-2-7inch-2mp-starvis-sensor-imx462-compatible-with-raspberry-pi-isp-and-gstreamer-plugin.html (I own this camera and it works on a Raspberry Pi 4 with my newest created RPi image. It works if you do not use the pivariety daughterboard and just connecting directly; you'll need to change the config.txt file a bit and use --libcamera to use though)
https://www.amazon.ca/VEYE-MIPI-327E-forRaspberry-Jetson-XavierNX-YT0-95-4I/dp/B08QJ1BBM1
https://www.e-consystems.com/usb-cameras/sony-starvis-imx462-ultra-low-light-camera.asp (USB-based; more compatible with other devices)
You can buy IR Filters, or you can buy lenses that come with IR filters, if needed, for pretty cheap. Many are designed for security applications, so be aware. https://fulekan.aliexpress.com/store/1862644
Support for the Theta 4k 360 USB camera has been added. Has been tested with the Jetson. It is likely too slow to use with a Raspberry Pi though.
Install script and brief usage example found here: https://github.com/steveseguin/raspberry_ninja/blob/main/nvidia_jetson/theta_z1_install.sh
As per HDMI adapters, a 1080p30 USB 2.0 HDMI to MJPEG adapter can usually be had for $10 to $20, although there are many fake offerings out there. I've tested a $12 MACROSILICON HDMI to USB adapter, and it works pretty well with the Jetson (and OK with the RPI), although finding a legitimate one might be tricky. On a Raspberry Pi 4, 1080p30 is posssible with the HDMI to USB adapter, but audio currently then goes out of sync; at 720p though, audio stays in sync with the video more frequently. Audio sync issues might be resolved in the future with more system tuning.
There's another option though, and that is to use an HDMI to CSI adapter for Raspberry Pis, such as the C780A ($29 USD) https://www.aliexpress.com/item/1005002861310912.html, although the frame rate of an HDMI to CSI option is limited to 1080p25 (due to 2 CSI lanes only). It's also slightly more expensive than the HDMI to USB alternative. The RPi Compute Module boards seem to have four-lanes of CSI available though, so 30-fps might be achivable there if you buy the compatible board (C780B ?)
Audio is also more challenging when dealing with the HDMI to CSI adapters, as you need to connect audio from the board via I2S to the RPi. This isn't easy to do with some of the HDMI to CSI boards, but there are a couple options where this is a trival step.
Please note before buying that there are different HDMI to CSI2 boards, and they might look similar, but they are definitely not equal.
HDMI to CSI boards are not plug-and-play currently, as they do require a couple tweaks to the boot file at the very least, and maybe an update to the EDID file. (script provided for that). Depending on the video input signal, you might need to further tweak settings, such as colorimetery settings. This not really an issue with the HDMI to USB adapters, as they convert to a very standard MJPEG format, making them more plug and play friendly.
Please share with the community what works well for you and what did not.
When using the --midi
parameter, video and audio are disabled. Instead, the script can send and recieve MIDI commands over VDO.Ninja. Supports plug-and-play, although you may need to install python-rtmidi
using pip3 first.
Incoming MIDI messages will be forwarded to the first MIDI device connected to the Pi. Adding &midiout
to the viewer's view-link will have that remote browser send any MIDI messages (such as from a USB DJ Controller) to the raspberry_ninja publish.py script, which will then be forwarded to the first local MIDI device
Outgoing MIDI messages will be sent to connected viewers, and if those connected viewers have &midiin
added to their view-links, those MIDI commands will be forwarded to the connected MIDI devices.
If using a virtual MIDI device on the remote viewer's computer, such as loopMIDI
, you can target that as both a source and target for MIDI commands. This is especially useful for connecting VDO.Ninja to DJ software applilcations, like Mixxx or Serato DJ Pro, which supports mapping of MIDI inputs/outputs.
Please note, the raspberry_ninja publish.py script can both send and recieve MIDI commands over a single peer connection, which is a bit different than how video/audio work currently. It's also different than how browser to browser currently is setup, where a sender won't ever request MIDI data, yet the raspberry_ninja code does allow the sender to both send and receive MIDI data.
midi demo video: https://youtu.be/Gry9UFtOTmQ
Installation from source is pretty slow and problematic on a rpi; using system images makes using this so much easier.
Please use the provided backup server for development purposes; that wss server is wss://apibackup.vdo.ninja:443
and for viewing: https://backup.vdo.ninja
Passwords must be DISABLED explicitly as this code does not yet have the required crypto logic added yet. Things will not playback if you leave off &password=false
The current code does not dynamically adjust resolution to combat frame loss; rather it will just drop frames. As a result, having a high quality connection between sender and viewer is required. Consider lowering the bitrate or resolution if problems persist.
Speedify.com works on Linux and embedded devices, providing network bonding and fail-over connections. The install instructions are pretty easy and can be found here: https://support.speedify.com/article/562-install-speedify-linux (not sponsored)
If you want to do computer-vision / machine-learning with cv2 or tensorflow on the resulting webRTC video stream, I have an open-source project here that you can take snippets from that you can add to raspberry_ninja to do what you want: github.com/ooblex
If you wish to play a video back, using a Raspberry Pi, try this "kiosk" mode image that can be found here: https://awesomeopensource.com/project/futurice/chilipie-kiosk. Raspberry Pis seem to handle video playback in Chromium-based browsers OK. I'l try to have browser-free playback at some point in the future.
If needing to make a backup of your microSD, see: http://sigkillit.com/2022/10/13/shrink-a-raspberry-pi-or-retropie-img-on-windows-with-pishrink/
Fix VP8/VP9 recordings and add muxing to the H264 recordings (moderate)
Offer a Docker version
Have an option to "playback" an incoming stream full-screened on a pi or jetson, to use as an input to an ATEM mixer.
Add support for passwords and group rooms (steve - partially added)
Make easier to use for novice users; perhaps adding a local web-interface or config file accessible via an SD card reader via Windows. These options could then allow for setting of wifi passwords, device, settings, stream IDs, etc, without needing to SSH in or using nano/vim. (moderate)
Add a QR-code reader mode to the app, as to setup Stream ID, bitrate, and WiFi passwords using a little website tool. (moderate)
Have gstreamer/python automatically detect the input devices, settings, system, and configure things automatically. Allowing for burn, plug, and boot, without needing to log in via SSH at all.
Support is available on Discord at https://discord.vdo.ninja in channel #raspberry-ninja