I've more than 200 MP3 files and I need to split each one of them by using silence detection. I tried Audacity and WavePad but they do not have batch processes and it's very slow to make them one by one.

The scenario is as follows:

  • split track whereas silence 2 seconds or more
  • then add 0.5 s at the start and the end of these tracks and save them as .mp3
  • BitRate 192 stereo
  • normalize volume to be sure that all files are the same volume and quality

I tried FFmpeg but no success.

  • Have a look at How can I split a mp3 file?. – John1024 Aug 5 '17 at 22:51
  • I've used mp3DirectCut with reasonable success. Having said that, StackOverflow is a Q/A site for programming. It's not a site for requesting recommendations for software or other off-site resources. – rojo Aug 5 '17 at 23:04

I found pydub to be easiest tool to do this kind of audio manipulation in simple ways and with compact code.

You can install pydub with

pip install pydub

You may need to install ffmpeg/avlib if needed. See this link for more details.

Here is a snippet that does what you asked. Some of the parameters such as silence_threshold and target_dBFS may need some tuning to match your requirements. Overall, I was able to split mp3 files, although I had to try different values for silence_threshold.


# Import the AudioSegment class for processing audio and the 
# split_on_silence function for separating out silent chunks.
from pydub import AudioSegment
from pydub.silence import split_on_silence

# Define a function to normalize a chunk to a target amplitude.
def match_target_amplitude(aChunk, target_dBFS):
    ''' Normalize given audio chunk '''
    change_in_dBFS = target_dBFS - aChunk.dBFS
    return aChunk.apply_gain(change_in_dBFS)

# Load your audio.
song = AudioSegment.from_mp3("your_audio.mp3")

# Split track where the silence is 2 seconds or more and get chunks using 
# the imported function.
chunks = split_on_silence (
    # Use the loaded audio.
    # Specify that a silent chunk must be at least 2 seconds or 2000 ms long.
    min_silence_len = 2000,
    # Consider a chunk silent if it's quieter than -16 dBFS.
    # (You may want to adjust this parameter.)
    silence_thresh = -16

# Process each chunk with your parameters
for i, chunk in enumerate(chunks):
    # Create a silence chunk that's 0.5 seconds (or 500 ms) long for padding.
    silence_chunk = AudioSegment.silent(duration=500)

    # Add the padding chunk to beginning and end of the entire chunk.
    audio_chunk = silence_chunk + chunk + silence_chunk

    # Normalize the entire chunk.
    normalized_chunk = match_target_amplitude(audio_chunk, -20.0)

    # Export the audio chunk with new bitrate.
    print("Exporting chunk{0}.mp3.".format(i))
        bitrate = "192k",
        format = "mp3"

If your original audio is stereo (2-channel), your chunks will also be stereo. You can check the original audio like this:

>>> song.channels
| improve this answer | |
  • 1
    Note that split_on_silence() has keep_silence=100 which already includes 200ms of what was detected as silence (100ms at start and and). You could either add only 400ms of silence at beginning and end or do keep_silence=500 to use the silence from the file and avoid adding your own silence. – verbamour Sep 5 '18 at 17:04
  • 1
    Note that this library does not support streaming. i.e., it will attempt to load the whole sound file into memory. In the case of big files in 32bit systems, it may throw memory error. There're other library to consider, like pyAudioAnalysis, though. Also it's tricky to detect silence, especially when it's not completely no sound and it would be hard to tweak the parameters. – Silent Sojourner Jul 25 '19 at 19:20
  • @Anil_M how to tune min_silence_len and silence_thresh? – Aaditya Ura Aug 3 at 19:45
  • @AadityaUra - Answer has sample min_silence_len /silence_threshold values. You will need to try different values to see what combination suits your requirements. – Anil_M Aug 3 at 21:54

You can try using this for splitting audio on silence without the trouble of exploring possibilities for the silence threshold

def split(file, filepath):
    sound = AudioSegment.from_wav(filepath)
    dBFS = sound.dBFS
    chunks = split_on_silence(sound, 
        min_silence_len = 500,
        silence_thresh = dBFS-16,
        keep_silence = 250 //optional

Note that the silence_thresh value need not be adjusted after using this.

Additionally, if you want to split the audio by setting the min length of the audio chunk, you can add this after the above mentioned code.

target_length = 25 * 1000 //setting minimum length of each chunk to 25 seconds
output_chunks = [chunks[0]]
for chunk in chunks[1:]:
    if len(output_chunks[-1]) < target_length:
        output_chunks[-1] += chunk
        # if the last output chunk is longer than the target length,
        # we can start a new one

now we use output_chunks for further processing

| improve this answer | |
  • Just FWIW, can you delete the unused file argument to split? It will save someone else a minute scrunching their eyebrows wondering if that's used somewhere. Thanks for the post! – Dan Nissenbaum Jul 6 at 19:05

Having tested all of these solutions and none of them having worked for me I have found a solution that worked for me and is relatively fast.


  1. It works with ffmpeg
  2. It is based on code by Vincent Berthiaume from this post (https://stackoverflow.com/a/37573133/2747626)
  3. It requires numpy (although it doesn't need much from numpy and a solution without numpy would probably be relatively easy to write and further increase speed)

Mode of operation, rationale:

  1. The solutions provided here were based on AI, or were extremely slow, or loaded the entire audio into memory, which was not feasible for my purposes (I wanted to split the recording of all of Bach's Brandenburg Concertos into particular songs, the 2 LPs are 2 hours long, @ 44 kHz 16bit stereo that is 1.4 GB in memory and very slow). From the beginning when I stumbled upon this post I was telling myself that there must be a simple way as this is a mere threshold filter operation which doesn't need much overhead and could be accomplished on tiny chunks of audio at a time. A couple months later I stumbled upon https://stackoverflow.com/a/37573133/2747626 which gave me the idea to accomplish audio splitting relatively efficiently.
  2. The command line arguments give source mp3 (or whatever ffmpeg can read), silence duration and noise threshold value. For my Bach LP recording, 1 second junks of 0.01 of full amplitude did the trick.
  3. It lets ffmpeg convert the input to a lossless 16-bit 22kHz PCM and pass it back via subprocess.Popen, with the advantage that ffmpeg does so very fast and in little chunks which do not occupy much memory.
  4. Back in python, 2 temporary numpy arrays of the last and before last buffer are concatenated and checked if they surpass the given threshold. If they don't, it means there is a block of silence, and (naively I admit) simply count the time where there is "silence". If the time is at least as long as the given min. silence duration, (again naively) the middle of this current interval is taken as the splitting moment.
  5. The program actually doesn't do anything with the source file and instead creates a batch file that can be run that tells ffmpeg to take segments bounded by these "silences" and save them into separate files.
  6. The user can then run the output batch file, maybe filter through some repeating micro intervals with tiny chunks of silence in case there are long pauses between songs.
  7. This solution is both working and fast (none of the other solutions in this thread worked for me).

The little code:

import subprocess as sp
import sys
import numpy

FFMPEG_BIN = "ffmpeg.exe"

print 'ASplit.py <src.mp3> <silence duration in seconds> <threshold amplitude 0.0 .. 1.0>'

src = sys.argv[1]
dur = float(sys.argv[2])
thr = int(float(sys.argv[3]) * 65535)

f = open('%s-out.bat' % src, 'wb')

tmprate = 22050
len2 = dur * tmprate
buflen = int(len2     * 2)
#            t * rate * 16 bits

oarr = numpy.arange(1, dtype='int16')
# just a dummy array for the first chunk

command = [ FFMPEG_BIN,
        '-i', src,
        '-f', 's16le',
        '-acodec', 'pcm_s16le',
        '-ar', str(tmprate), # ouput sampling rate
        '-ac', '1', # '1' for mono
        '-']        # - output to stdout

pipe = sp.Popen(command, stdout=sp.PIPE, bufsize=10**8)

tf = True
pos = 0
opos = 0
part = 0

while tf :

    raw = pipe.stdout.read(buflen)
    if raw == '' :
        tf = False

    arr = numpy.fromstring(raw, dtype = "int16")

    rng = numpy.concatenate([oarr, arr])
    mx = numpy.amax(rng)
    if mx <= thr :
        # the peak in this range is less than the threshold value
        trng = (rng <= thr) * 1
        # effectively a pass filter with all samples <= thr set to 0 and > thr set to 1
        sm = numpy.sum(trng)
        # i.e. simply (naively) check how many 1's there were
        if sm >= len2 :
            part += 1
            apos = pos + dur * 0.5
            print mx, sm, len2, apos
            f.write('ffmpeg -i "%s" -ss %f -to %f -c copy -y "%s-p%04d.mp3"\r\n' % (src, opos, apos, src, part))
            opos = apos

    pos += dur

    oarr = arr

part += 1    
f.write('ffmpeg -i "%s" -ss %f -to %f -c copy -y "%s-p%04d.mp3"\r\n' % (src, opos, pos, src, part))
| improve this answer | |
  • Thanks a lot! After reading in the raw file, I was able to use stackoverflow.com/questions/24885092/… to find the silences – andrewdotn Feb 10 at 2:17
  • how do you argue that this is performant somehow ? and does not load all the audio file into memory ? – Curcuma_ May 1 at 0:03
  • 1
    Well I didn't put together a precise table of results (I was in a hurry), but the AI based and pydub-based solutions I came across here loaded the entire audio into memory AT ONCE which meant 2 GB of data for my long audio file and took ages just to decode the mp3. The solution I have provided is very fast (on my setup) and only a small part of the audio is loaded at a time, @Curcuma_ – mxl May 7 at 14:32

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.