Phonetic posteriorgram-based voice conversion system to improve speech intelligibility of dysarthric patients

Wei-Zhong Zheng; Ji-Yan Han; Chen-Kai Lee; Yu-Yi Lin; Shu-Han Chang; Ying-Hui Lai

doi:10.1016/j.cmpb.2021.106602

Phonetic posteriorgram-based voice conversion system to improve speech intelligibility of dysarthric patients

Comput Methods Programs Biomed. 2022 Mar:215:106602. doi: 10.1016/j.cmpb.2021.106602. Epub 2021 Dec 26.

Authors

Wei-Zhong Zheng¹, Ji-Yan Han¹, Chen-Kai Lee¹, Yu-Yi Lin¹, Shu-Han Chang², Ying-Hui Lai³

Affiliations

¹ Department of Biomedical Engineering, National Yang Ming Chiao Tung University, Taipei, Taiwan.
² Monte Vista Christian School, CA, USA.
³ Department of Biomedical Engineering, National Yang Ming Chiao Tung University, Taipei, Taiwan; Medical Device Innovation & Translation Center, National Yang Ming Chiao Tung University, Taipei, Taiwan. Electronic address: yh.lai@nycu.edu.tw.

PMID: 35021138
DOI: 10.1016/j.cmpb.2021.106602

Abstract

Background and objective: Most dysarthric patients encounter communication problems due to unintelligible speech. Currently, there are many voice-driven systems aimed at improving their speech intelligibility; however, the intelligibility performance of these systems are affected by challenging application conditions (e.g., time variance of patient's speech and background noise). To alleviate these problems, we proposed a dysarthria voice conversion (DVC) system for dysarthric patients and investigated the benefits under challenging application conditions.

Method: A deep learning-based voice conversion system with phonetic posteriorgram (PPG) features, called the DVC-PPG system, was proposed in this study. An objective-evaluation metric of Google automatic speech recognition (Google ASR) system and a listening test were used to demonstrate the speech intelligibility benefits of DVC-PPG under quiet and noisy test conditions; besides, the well-known voice conversion system using mel-spectrogram, DVC-Mels, was used for comparison to verify the benefits of the proposed DVC-PPG system.

Results: The objective-evaluation metric of Google ASR showed the average accuracy of two subjects in the duplicate and outside test conditions while the DVC-PPG system provided higher speech recognitions rate (83.2% and 67.5%) than dysarthric speech (36.5% and 26.9%) and DVC-Mels (52.9% and 33.8%) under quiet conditions. However, the DVC-PPG system provided more stable performance than the DVC-Mels under noisy test conditions. In addition, the results of the listening test showed that the speech-intelligibility performance of DVC-PPG was better than those obtained via the dysarthria speech and DVC-Mels under the duplicate and outside conditions, respectively.

Conclusions: The objective-evaluation metric and listening test results showed that the recognition rate of the proposed DVC-PPG system was significantly higher than those obtained via the original dysarthric speech and DVC-Mels system. Therefore, it can be inferred from our study that the DVC-PPG system can improve the ability of dysarthric patients to communicate with people under challenging application conditions.

Keywords: Deep learning; Dysarthric patient; Phonetic posteriorgram; Voice conversion.

MeSH terms

Dysarthria
Humans
Phonetics
Speech Intelligibility*
Speech Production Measurement
Voice*