Distil Whisper v0.2
Collection
Language-specific distilled Whisper models for speech recognition.
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Whisper-Large-V3-Distil-French-v0.2
A distilled version of Whisper with 2 decoder layers, optimized for French speech-to-text.
Compared to v0.1, this version extends the training to 30-second audio segments to maintain long-form transcription abilities. The training process used a "patient" teacher during distillation - meaning longer training times and more aggressive data augmentation - which improved overall performance.
The model uses openai/whisper-large-v3 as the teacher model while keeping the encoder architecture unchanged. This makes it suitable as a draft model for speculative decoding, potentially getting 2x inference speed while maintaining identical outputs by only adding 2 extra decoder layers and running the encoder just once. It can also serve as a standalone model to trade some accuracy for better efficiency, running 5.8x faster while using only 49% of the parameters. This paper also suggests that the distilled model may actually produce fewer hallucinations than the full model during long-form transcription.
The model has been converted into multiple formats to ensure broad compatibility across libraries including transformers, openai-whisper, faster-whisper, whisper.cpp, candle, mlx.
Performance
The model was evaluated on both short and long-form transcriptions, using in-distribution (ID) and out-of-distribution (OOD) datasets to assess accuracy, generalizability, and robustness.
Note that Word Error Rate (WER) results shown here are post-normalization, which includes converting text to lowercase and removing symbols and punctuation.
All evaluation results on the public datasets can be found here.
Short-Form Transcription
Italic indicates in-distribution (ID) evaluation, where test sets correspond to data distributions seen during training, typically yielding higher performance than out-of-distribution (OOD) evaluation. Italic and strikethrough denotes potential test set contamination - for example, when training and evaluation use different versions of Common Voice, raising the possibility of overlapping data.
Due to the limited availability of out-of-distribution (OOD) and long-form French test sets, evaluation was also performed using internal test sets from Zaion Lab - consisting of human-annotated call center conversations with significant background noise and domain-specific terminology.
Long-Form Transcription
Long-form transcription evaluation used the 🤗 Hugging Face pipeline with both chunked (chunk_length_s=30) and original sequential decoding methods.
Usage
Hugging Face Pipeline
The model can be easily used with the 🤗 Hugging Face pipeline class for audio transcription. For long-form transcription (over 30 seconds), it will perform sequential decoding as described in OpenAI's paper. If you need faster inference, you can use the chunk_length_s argument for chunked parallel decoding, which provides 9x faster inference speed but may slightly compromise performance compared to OpenAI's sequential algorithm.
import torch
from datasets import load_dataset
from transformers import AutoModelForSpeechSeq2Seq, AutoProcessor, pipeline
device = "cuda:0" if torch.cuda.is_available() else "cpu"
torch_dtype = torch.float16 if torch.cuda.is_available() else torch.float32
# Load model
model_name_or_path = "bofenghuang/whisper-large-v3-distil-fr-v0.2"
processor = AutoProcessor.from_pretrained(model_name_or_path)
model = AutoModelForSpeechSeq2Seq.from_pretrained(
model_name_or_path,
torch_dtype=torch_dtype,
low_cpu_mem_usage=True,
)
model.to(device)
# Init pipeline
pipe = pipeline(
"automatic-speech-recognition",
model=model,
feature_extractor=processor.feature_extractor,
tokenizer=processor.tokenizer,
torch_dtype=torch_dtype,
device=device,
# chunk_length_s=30, # for chunked decoding
max_new_tokens=128,
)
# Example audio
dataset = load_dataset("bofenghuang/asr-dummy", "fr", split="test")
sample = dataset[0]["audio"]
# Run pipeline
result = pipe(sample)
print(result["text"])
Hugging Face Low-level APIs
You can also use the 🤗 Hugging Face low-level APIs for transcription, offering greater control over the process, as demonstrated below:
import torch
from datasets import load_dataset
from transformers import AutoModelForSpeechSeq2Seq, AutoProcessor
device = "cuda:0" if torch.cuda.is_available() else "cpu"
torch_dtype = torch.float16 if torch.cuda.is_available() else torch.float32
# Load model
model_name_or_path = "bofenghuang/whisper-large-v3-distil-fr-v0.2"
processor = AutoProcessor.from_pretrained(model_name_or_path)
model = AutoModelForSpeechSeq2Seq.from_pretrained(
model_name_or_path,
torch_dtype=torch_dtype,
low_cpu_mem_usage=True,
)
model.to(device)
# Example audio
dataset = load_dataset("bofenghuang/asr-dummy", "fr", split="test")
sample = dataset[0]["audio"]
# Extract feautres
input_features = processor(
sample["array"], sampling_rate=sample["sampling_rate"], return_tensors="pt"
).input_features
# Generate tokens
predicted_ids = model.generate(
input_features.to(dtype=torch_dtype).to(device), max_new_tokens=128
)
# Detokenize to text
transcription = processor.batch_decode(predicted_ids, skip_special_tokens=True)[0]
print(transcription)
Speculative Decoding
Speculative decoding can be achieved using a draft model, essentially a distilled version of Whisper. This approach guarantees identical outputs to using the main Whisper model alone, offers a 2x faster inference speed, and incurs only a slight increase in memory overhead.
Since the distilled Whisper has the same encoder as the original, only its decoder need to be loaded, and encoder outputs are shared between the main and draft models during inference.
Using speculative decoding with the Hugging Face pipeline is simple - just specify the assistant_model within the generation configurations.
import torch
from datasets import load_dataset
from transformers import (
AutoModelForCausalLM,
AutoModelForSpeechSeq2Seq,
AutoProcessor,
pipeline,
)
device = "cuda:0" if torch.cuda.is_available() else "cpu"
torch_dtype = torch.float16 if torch.cuda.is_available() else torch.float32
# Load model
model_name_or_path = "openai/whisper-large-v3"
processor = AutoProcessor.from_pretrained(model_name_or_path)
model = AutoModelForSpeechSeq2Seq.from_pretrained(
model_name_or_path,
torch_dtype=torch_dtype,
low_cpu_mem_usage=True,
)
model.to(device)
# Load draft model
assistant_model_name_or_path = "bofenghuang/whisper-large-v3-distil-fr-v0.2"
assistant_model = AutoModelForCausalLM.from_pretrained(
assistant_model_name_or_path,
torch_dtype=torch_dtype,
low_cpu_mem_usage=True,
)
assistant_model.to(device)
# Init pipeline
pipe = pipeline(
"automatic-speech-recognition",
model=model,
feature_extractor=processor.feature_extractor,
tokenizer=processor.tokenizer,
torch_dtype=torch_dtype,
device=device,
generate_kwargs={"assistant_model": assistant_model},
max_new_tokens=128,
)
# Example audio
dataset = load_dataset("bofenghuang/asr-dummy", "fr", split="test")
sample = dataset[0]["audio"]
# Run pipeline
result = pipe(sample)
print(result["text"])
OpenAI Whisper
You can also employ the sequential long-form decoding algorithm with a sliding window and temperature fallback, as outlined by OpenAI in their original paper.
First, install the openai-whisper package:
pip install -U openai-whisper
Then, download the converted model:
huggingface-cli download --include original_model.pt --local-dir ./models/whisper-large-v3-distil-fr-v0.2 bofenghuang/whisper-large-v3-distil-fr-v0.2
Now, you can transcirbe audio files by following the usage instructions provided in the repository:
import whisper
from datasets import load_dataset
# Load model
model_name_or_path = "./models/whisper-large-v3-distil-fr-v0.2/original_model.pt"
model = whisper.load_model(model_name_or_path)
# Example audio
dataset = load_dataset("bofenghuang/asr-dummy", "fr", split="test")
sample = dataset[0]["audio"]["array"].astype("float32")
# Transcribe
result = model.transcribe(sample, language="fr")
print(result["text"])
Faster Whisper
Faster Whisper is a reimplementation of OpenAI's Whisper models and the sequential long-form decoding algorithm in the CTranslate2 format.
Compared to openai-whisper, it offers up to 4x faster inference speed, while consuming less memory. Additionally, the model can be quantized into int8, further enhancing its efficiency on both CPU and GPU.
First, install the faster-whisper package:
pip install faster-whisper
Then, download the model converted to the CTranslate2 format:
huggingface-cli download --include ctranslate2/* --local-dir ./models/whisper-large-v3-distil-fr-v0.2 bofenghuang/whisper-large-v3-distil-fr-v0.2
Now, you can transcirbe audio files by following the usage instructions provided in the repository:
from datasets import load_dataset
from faster_whisper import WhisperModel
# Load model
model_name_or_path = "./models/whisper-large-v3-distil-fr-v0.2/ctranslate2"
model = WhisperModel(model_name_or_path", device="cuda", compute_type="float16") # Run on GPU with FP16
# Example audio
dataset = load_dataset("bofenghuang/asr-dummy", "fr", split="test")
sample = dataset[0]["audio"]["array"].astype("float32")
segments, info = model.transcribe(sample, beam_size=5, language="fr")
for segment in segments:
print("[%.2fs -> %.2fs] %s" % (segment.start, segment.end, segment.text))
Whisper.cpp
Whisper.cpp is a reimplementation of OpenAI's Whisper models, crafted in plain C/C++ without any dependencies. It offers compatibility with various backends and platforms.
Additionally, the model can be quantized to either 4-bit or 5-bit integers, further enhancing its efficiency.
First, clone and build the whisper.cpp repository:
git clone https://github.com/ggerganov/whisper.cpp.git
cd whisper.cpp
# build the main example
make
Next, download the converted ggml weights from the Hugging Face Hub:
# Download model quantized with Q5_0 method
huggingface-cli download --include ggml-model* --local-dir ./models/whisper-large-v3-distil-fr-v0.2 bofenghuang/whisper-large-v3-distil-fr-v0.2
Now, you can transcribe an audio file using the following command:
./main -m ./models/whisper-large-v3-distil-fr-v0.2/ggml-model-q5_0.bin -l fr -f /path/to/audio/file --print-colors
Candle
Candle-whisper is a reimplementation of OpenAI's Whisper models in the candle format - a lightweight ML framework built in Rust.
First, clone the candle repository:
git clone https://github.com/huggingface/candle.git
cd candle/candle-examples/examples/whisper
Transcribe an audio file using the following command:
cargo run --example whisper --release -- --model large-v3 --model-id bofenghuang/whisper-large-v3-distil-fr-v0.2 --language fr --input /path/to/audio/file
In order to use CUDA add --features cuda to the example command line:
cargo run --example whisper --release --features cuda -- --model large-v3 --model-id bofenghuang/whisper-large-v3-distil-fr-v0.2 --language fr --input /path/to/audio/file
MLX
MLX-Whisper is a reimplementation of OpenAI's Whisper models in the MLX format - a ML framework on Apple silicon. It supports features like lazy computation, unified memory management, etc.
First, clone the MLX Examples repository:
git clone https://github.com/ml-explore/mlx-examples.git
cd mlx-examples/whisper
Next, install the dependencies:
pip install -r requirements.txt
Download the pytorch checkpoint in the original OpenAI format and convert it into MLX format (We haven't included the converted version here since the repository is already heavy and the conversion is very fast):
# Download
huggingface-cli download --include original_model.pt --local-dir ./models/whisper-large-v3-distil-fr-v0.2 bofenghuang/whisper-large-v3-distil-fr-v0.2
# Convert into .npz
python convert.py --torch-name-or-path ./models/whisper-large-v3-distil-fr-v0.2/original_model.pt --mlx-path ./mlx_models/whisper-large-v3-distil-fr-v0.2
Now, you can transcribe audio with:
import whisper
result = whisper.transcribe("/path/to/audio/file", path_or_hf_repo="mlx_models/whisper-large-v3-distil-fr-v0.2", language="fr")
print(result["text"])
Training details
We built a French speech recognition dataset of over 22,000 hours of annotated and semi-annotated speech. After decoding this dataset through Whisper-Large-V3 and filtering out segments with WER above 20%, we retained approximately 10,000 hours of high-quality audio.
| Dataset | Total Duration (h) | Filtered Duration (h) <20% WER |
|---|---|---|
| mcv | 800.37 | 687.02 |
| mls | 1076.58 | 1043.87 |
| voxpopuli | 199.03 | 177.11 |
| mtedx | 170.31 | 147.48 |
| african_accented_french | 7.69 | 7.69 |
| yodas-fr000 | 2395.82 | 1502.82 |
| yodas-fr100 | 4978.16 | 1887.36 |
| yodas-fr101 | 4966.07 | 1882.39 |
| yodas-fr102 | 4992.84 | 1877.40 |
| yodas-fr103 | 3161.39 | 1189.32 |
| total | 22748.26 | 10402.46 |
Most data were first concatenated into 30-second segments, primarily preserving the same speaker, then inferred together. 50% of segments were trained with timestamps to ensure good timestamp prediction, and only 20% of segments were trained with previous context since we don't expect the 2-layer decoder to excel at this task.
This model was trained for a fairly long schedule of 160 epochs using aggressive data augmentation, with eval WER continuing to decrease. Some hyperparameter choices were made to favor long-form over short-form transcription. For further details, please refer to the Distil-Whisper repository.
All model training was conducted on the Jean-Zay supercomputer at GENCI. Special thanks to the IDRIS team for their excellent support throughout this project.
Acknowledgements
- OpenAI for developing and open-sourcing the Whisper model
- 🤗 Hugging Face for implementing Whisper in the Transformers library and creating Distil-Whisper
- Genci for generously providing the GPU computing resources for this project
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