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This pipeline is the same as pyannote/speaker-diarization-3.0
except it removes the problematic use of onnxruntime
.
Both speaker segmentation and embedding now run in pure PyTorch. This should ease deployment and possibly speed up inference.
It requires pyannote.audio version 3.1 or higher.
It ingests mono audio sampled at 16kHz and outputs speaker diarization as an Annotation
instance:
- stereo or multi-channel audio files are automatically downmixed to mono by averaging the channels.
- audio files sampled at a different rate are resampled to 16kHz automatically upon loading.
- Install
pyannote.audio
3.1
withpip install pyannote.audio
- Accept
pyannote/segmentation-3.0
user conditions - Accept
pyannote/speaker-diarization-3.1
user conditions - Create access token at
hf.co/settings/tokens
.
# instantiate the pipeline
from pyannote.audio import Pipeline
pipeline = Pipeline.from_pretrained(
"pyannote/speaker-diarization-3.1",
use_auth_token="HUGGINGFACE_ACCESS_TOKEN_GOES_HERE")
# run the pipeline on an audio file
diarization = pipeline("audio.wav")
# dump the diarization output to disk using RTTM format
with open("audio.rttm", "w") as rttm:
diarization.write_rttm(rttm)
pyannote.audio
pipelines run on CPU by default.
You can send them to GPU with the following lines:
import torch
pipeline.to(torch.device("cuda"))
Pre-loading audio files in memory may result in faster processing:
waveform, sample_rate = torchaudio.load("audio.wav")
diarization = pipeline({"waveform": waveform, "sample_rate": sample_rate})
Hooks are available to monitor the progress of the pipeline:
from pyannote.audio.pipelines.utils.hook import ProgressHook
with ProgressHook() as hook:
diarization = pipeline("audio.wav", hook=hook)
In case the number of speakers is known in advance, one can use the num_speakers
option:
diarization = pipeline("audio.wav", num_speakers=2)
One can also provide lower and/or upper bounds on the number of speakers using min_speakers
and max_speakers
options:
diarization = pipeline("audio.wav", min_speakers=2, max_speakers=5)
This pipeline has been benchmarked on a large collection of datasets.
Processing is fully automatic:
- no manual voice activity detection (as is sometimes the case in the literature)
- no manual number of speakers (though it is possible to provide it to the pipeline)
- no fine-tuning of the internal models nor tuning of the pipeline hyper-parameters to each dataset
... with the least forgiving diarization error rate (DER) setup (named "Full" in this paper):
- no forgiveness collar
- evaluation of overlapped speech
Benchmark | DER% | FA% | Miss% | Conf% | Expected output | File-level evaluation |
---|---|---|---|---|---|---|
AISHELL-4 | 12.2 | 3.8 | 4.4 | 4.0 | RTTM | eval |
AliMeeting (channel 1) | 24.4 | 4.4 | 10.0 | 10.0 | RTTM | eval |
AMI (headset mix, only_words) | 18.8 | 3.6 | 9.5 | 5.7 | RTTM | eval |
AMI (array1, channel 1, only_words) | 22.4 | 3.8 | 11.2 | 7.5 | RTTM | eval |
AVA-AVD | 50.0 | 10.8 | 15.7 | 23.4 | RTTM | eval |
DIHARD 3 (Full) | 21.7 | 6.2 | 8.1 | 7.3 | RTTM | eval |
MSDWild | 25.3 | 5.8 | 8.0 | 11.5 | RTTM | eval |
REPERE (phase 2) | 7.8 | 1.8 | 2.6 | 3.5 | RTTM | eval |
VoxConverse (v0.3) | 11.3 | 4.1 | 3.4 | 3.8 | RTTM | eval |
@inproceedings{Plaquet23,
author={Alexis Plaquet and Hervé Bredin},
title={{Powerset multi-class cross entropy loss for neural speaker diarization}},
year=2023,
booktitle={Proc. INTERSPEECH 2023},
}
@inproceedings{Bredin23,
author={Hervé Bredin},
title={{pyannote.audio 2.1 speaker diarization pipeline: principle, benchmark, and recipe}},
year=2023,
booktitle={Proc. INTERSPEECH 2023},
}