SSA-HuBERT-base-60k / README.md
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metadata
license: cc-by-nc-4.0
tags:
  - speech processing
  - self-supervision
  - african languages

Model description

This self-supervised speech model (a.k.a. SSA-HuBERT-base-60k) is based on a HuBERT Base architecture (~95M params) [1].
It was trained on nearly 60 000 hours of speech segments and covers 21 languages and variants spoken in Sub-Saharan Africa.

Pretraining data

  • Dataset: The training dataset was composed of both studio recordings (controlled environment, prepared talks) and street interviews (noisy environment, spontaneous speech).

  • Languages: Bambara (bam), Dyula (dyu), French (fra), Fula (ful), Fulfulde (ffm), Fulfulde (fuh), Gulmancema (gux), Hausa (hau), Kinyarwanda (kin), Kituba (ktu), Lingala (lin), Luba-Lulua (lua), Mossi (mos), Maninkakan (mwk), Sango (sag), Songhai (son), Swahili (swc), Swahili (swh), Tamasheq (taq), Wolof (wol), Zarma (dje).

ASR fine-tuning

The SpeechBrain toolkit (Ravanelli et al., 2021) is used to fine-tune the model.
Fine-tuning is done for each language using the FLEURS dataset [2].
The pretrained model (SSA-HuBERT-base-60k) is considered as a speech encoder and is fully fine-tuned with two 1024 linear layers and a softmax output at the top.

License

This model is released under the CC-by-NC 4.0 conditions.

Publication

This model were presented at AfricaNLP 2024. The associated paper is available here: Africa-Centric Self-Supervised Pre-Training for Multilingual Speech Representation in a Sub-Saharan Context

Citation

Please cite our paper when using SSA-HuBERT-base-60k model:

Caubrière, A., & Gauthier, E. (2024). Africa-Centric Self-Supervised Pre-Training for Multilingual Speech Representation in a Sub-Saharan Context. In 5th Workshop on African Natural Language Processing (AfricaNLP 2024).

Bibtex citation:

@inproceedings{caubri{\`e}re2024ssaspeechssl,    
    title={Africa-Centric Self-Supervised Pretraining for Multilingual Speech Representation in a Sub-Saharan Context},    
    author={Antoine Caubri{\`e}re and Elodie Gauthier},    
    booktitle={5th Workshop on African Natural Language Processing},    
    year={2024},    
    url={https://openreview.net/forum?id=zLOhcft2E7}}

Results

The following results are obtained in a greedy mode (no language model rescoring).
Character error rates (CERs) and Word error rates (WERs) are given in the table below, on the 20 languages of the SSA subpart of the FLEURS dataset.

Language CER CER (joint finetuning) WER WER (joint finetuning)
Afrikaans 23.3 20.3 68.4 62.6
Amharic 15.9 14.9 52.7 49.0
Fula 21.2 17.8 61.9 56.4
Ganda 11.5 10.7 52.8 50.3
Hausa 10.5 9.0 32.5 29.4
Igbo 19.7 17.2 57.5 52.9
Kamba 16.1 15.6 53.9 53.7
Lingala 8.7 6.9 24.7 20.9
Luo 9.9 8.2 38.9 34.9
Northen-Sotho 13.5 11.7 43.2 38.9
Nyanja 13.3 10.9 54.2 48.3
Oromo 22.8 20.1 78.1 74.8
Shona 11.6 8.3 50.2 39.3
Somali 21.6 19.7 64.9 60.3
Swahili 7.1 5.5 23.8 20.3
Umbundu 21.7 18.8 61.7 54.2
Wolof 19.4 17.0 55.0 50.7
Xhosa 11.9 9.9 51.6 45.9
Yoruba 24.3 23.5 67.5 65.7
Zulu 12.2 9.6 53.4 44.9
Overall average 15.8 13.8 52.3 47.7

Reproductibilty

We propose a notebook to reproduce the ASR experiments mentioned in our paper. See SB_ASR_FLEURS_finetuning.ipynb.
By using the ASR_FLEURS-swahili_hf.yaml config file, you will be able to run the recipe on Swahili.

References

[1] Wei-Ning Hsu, Benjamin Bolte, Yao-Hung Hubert Tsai, Kushal Lakhotia, Ruslan Salakhutdinov, and Abdelrahman Mohamed. HuBERT: Self-Supervised Speech Representation Learning by Masked Prediction of Hidden Units. In 2021 IEEE/ACM Transactions on Audio, Speech, and Language Processing, vol. 29, pp.3451–3460, 2021. doi: 10.1109/TASLP.2021.3122291.
[2] Alexis Conneau, Min Ma, Simran Khanuja, Yu Zhang, Vera Axelrod, Siddharth Dalmia, Jason Riesa, Clara Rivera, and Ankur Bapna. Fleurs: Few-shot learning evaluation of universal representations of speech. In 2022 IEEE Spoken Language Technology Workshop (SLT), pp. 798–805, 2022. doi: 10.1109/SLT54892.2023.10023141.