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arxiv: 2302.14597 · v1 · pith:BG4DC76I · submitted 2023-02-28 · cs.SD · eess.AS

deHuBERT: Disentangling Noise in a Self-supervised Model for Robust Speech Recognition

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classification cs.SD eess.AS
keywords noisespeechcleandehubertframeworkmatrixmodelmodels
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Existing self-supervised pre-trained speech models have offered an effective way to leverage massive unannotated corpora to build good automatic speech recognition (ASR). However, many current models are trained on a clean corpus from a single source, which tends to do poorly when noise is present during testing. Nonetheless, it is crucial to overcome the adverse influence of noise for real-world applications. In this work, we propose a novel training framework, called deHuBERT, for noise reduction encoding inspired by H. Barlow's redundancy-reduction principle. The new framework improves the HuBERT training algorithm by introducing auxiliary losses that drive the self- and cross-correlation matrix between pairwise noise-distorted embeddings towards identity matrix. This encourages the model to produce noise-agnostic speech representations. With this method, we report improved robustness in noisy environments, including unseen noises, without impairing the performance on the clean set.

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  1. StableToken: A Noise-Robust Semantic Speech Tokenizer for Resilient SpeechLLMs

    cs.CL 2025-09 unverdicted novelty 6.0

    StableToken introduces a multi-branch architecture with bit-wise voting to create noise-robust semantic speech tokens, achieving lower Unit Edit Distance and better SpeechLLM robustness than prior single-path tokenizers.