Reducing Geographic Disparities In Automatic Speech Recognition Via Elastic Weight Consolidation
2022 · Viet Anh Trinh, Pegah Ghahremani, Brian King, et al.
Abstract
We present an approach to reduce the performance disparity between geographic regions without degrading performance on the overall user population for ASR. A popular approach is to fine-tune the model with data from regions where the ASR model has a higher word error rate (WER). However, when the ASR model is adapted to get better performance on these high-WER regions, its parameters wander from the previous optimal values, which can lead to worse performance in other regions. In our proposed method, we utilize the elastic weight consolidation (EWC) regularization loss to identify directions in parameters space along which the ASR weights can vary to improve for high-error regions, while still maintaining performance on the speaker population overall. Our results demonstrate that EWC can reduce the word error rate (WER) in the region with highest WER by 3.2% relative while reducing the overall WER by 1.3% relative. We also evaluate the role of language and acoustic models in ASR fairne
Authors
(none)
Tags
Stats
Related papers
- Towards Fair ASR For Second Language Speakers Using Fairness Prompted Finetuning (2025)0.00
- Weighted Cross-entropy For Low-resource Languages In Multilingual Speech Recognition (2024)6.34
- Weight Averaging: A Simple Yet Effective Method To Overcome Catastrophic Forgetting In Automatic Speech Recognition (2022)6.34
- Debiased Automatic Speech Recognition For Dysarthric Speech Via Sample Reweighting With Sample Affinity Test (2023)6.34
- Ed-cec: Improving Rare Word Recognition Using Asr Postprocessing Based On Error Detection And Context-aware Error Correction (2023)6.34
- Residual Adapters For Parameter-efficient ASR Adaptation To Atypical And Accented Speech (2021)10.74
- Importance Of Smoothness Induced By Optimizers In FL4ASR: Towards Understanding Federated Learning For End-to-end ASR (2023)0.00
- Extreme Encoder Output Frame Rate Reduction: Improving Computational Latencies Of Large End-to-end Models (2024)5.84