|Version 14 (modified by rogerdpack, 4 years ago) (diff)|
FFmpeg can basically stream through one of two ways: It either streams to a some "other server", which restreams for it, or it can stream via UDP directly to some destination host, or possibly multicast destination. Servers which can receive from ffmpeg (to restream) include ffserver (linux only, though cygwin might work), or wowza, or flash media server. Even VLC can pick up the stream, then redistribute it, acting as server. Since ffmpeg is sometimes more efficient than VLC at doing the raw encoding, this can be a useful option compared to doing it all in VLC.
How to stream with several different simultaneous bitrates is described here.
NB that when you are testing your streams, you may want to test them with both VLC and ffplay, as ffplay sometimes introduces its own artifacts when it is scaled (it has poor quality scaling). Don't use ffplay as your baseline for determining quality.
Also note that encoding it to the x264 "baseline" is basically for older iOS devices or the like, see here.
The ffmpeg "-re" flag means to "Read input at native frame rate. Mainly used to simulate a grab device." i.e. if you want to play a video file, but at realtime, then use this. My guess is you typically don't want this flag when streaming from a live device.
Here's how one guy broadcast a live stream:
$ ffmpeg -y -loglevel warning -f dshow -i video="screen-capture-recorder" -vf crop=690:388:136:0 -r 30 -s 962x388 -threads 2 -vcodec libx264 -vpre baseline -vpre my_ffpreset -f flv rtmp:///live/myStream.sdp Here is my ffmpeg preset (libx264-my_ffpreset.ffpreset): coder=1 flags2=+wpred+dct8x8 level=31 maxrate=1200000 bufsize=200000 wpredp=0 g=60 refs=1 subq=3 trellis=0 bf=0 rc_lookahead=0
Here is what another person did:
Ffmpeg -f dshow -I video="Virtual-Camera" -vcodec libx264 -tune zerolatency -b 900k -f mpegts udp://10.1.0.102:1234
And here is what another person did:
ffmpeg -f dshow -i video="screen-capture-recorder":audio="Stereo Mix (IDT High Definition" -vcodec libx264 -preset ultrafast -tune zerolatency -r 10 -async 1 -acodec libmp3lame -ab 24k -ar 22050 -bsf:v h264_mp4toannexb -maxrate 750k -bufsize 3000k -f mpegts udp://192.168.5.215:48550
NB that they also had to adjust the rtbufsize in that example. I'm also not entirely sure which presets are "best" or what the available options are. Also note that newer version of ffmpeg may need a different syntax for specifying preset/tune.
You can decrease latency by specify that I-frames come "more frequently" (or always, in the case of x264's zerolatency), though this can increase frame size/decrease quality, see here for some alternatives. To decrease cpu usage required to stream, you could (if capturing from live source) instruct the live source to feed a "smaller stream" (ex: webcam stream 640x480 instead of 1024x1280), or you could set a lower "output quality" setting, or specify a lower output bitrate. Or try a different output codec, or specify new parameters (for instance, different profile for libx264). Also specifying $ -threads 0 (the default) instructs the encoder to use all available cpu cores, which can speed up processing. You could also resize your input first, before transcoding it, so it's not as large. Applying a smoothing filter like hqdn3d before encoding might help it compress better.
You can of course, also set a lower frame rate to decrease cpu usage.
You could set a "maximum bit rate" or a lower "q rating" (quality level). If you're able to capture with a pixel format that matches your output format, that might help, since it avoids a conversion. Using 64-bit instead of 32-bit executables (for those that have a choice) can result in a slight speedup.
In general the more cpu you use to compress, the better the output image will be, or the large of an image you can handle.
Streaming a simple RTP audio stream from ffmpeg
FFmpeg can stream a single stream using the RTP protocol. In order to avoid buffering problems on the other hand, the streaming should be done through the -re option, which means that the stream will be streamed in real-time.
For example the following command will generate a signal, and will stream it to the port 1234 on localhost:
ffmpeg -re -f lavfi -i aevalsrc="sin(400*2*PI*t)" -ar 8000 -f mulaw -f rtp rtp://127.0.0.1:1234
To play the stream with ffplay, run the command: