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Main Authors: Gowda, Harshavardhana T., McNaughton, Zachary D., Miller, Lee M.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.02591
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author Gowda, Harshavardhana T.
McNaughton, Zachary D.
Miller, Lee M.
author_facet Gowda, Harshavardhana T.
McNaughton, Zachary D.
Miller, Lee M.
contents Objective. In this article, we present data and methods for decoding speech articulations using surface electromyogram (EMG) signals. EMG-based speech neuroprostheses offer a promising approach for restoring audible speech in individuals who have lost the ability to speak intelligibly due to laryngectomy, neuromuscular diseases, stroke, or trauma-induced damage (e.g., from radiotherapy) to the speech articulators. Approach. To achieve this, we collect EMG signals from the face, jaw, and neck as subjects articulate speech, and we perform EMG-to-speech translation. Main results. Our findings reveal that the manifold of symmetric positive definite (SPD) matrices serves as a natural embedding space for EMG signals. Specifically, we provide an algebraic interpretation of the manifold-valued EMG data using linear transformations, and we analyze and quantify distribution shifts in EMG signals across individuals. Significance. Overall, our approach demonstrates significant potential for developing neural networks that are both data- and parameter-efficient, an important consideration for EMG-based systems, which face challenges in large-scale data collection and operate under limited computational resources on embedded devices.
format Preprint
id arxiv_https___arxiv_org_abs_2411_02591
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Geometry of orofacial neuromuscular signals: speech articulation decoding using surface electromyography
Gowda, Harshavardhana T.
McNaughton, Zachary D.
Miller, Lee M.
Computation and Language
Objective. In this article, we present data and methods for decoding speech articulations using surface electromyogram (EMG) signals. EMG-based speech neuroprostheses offer a promising approach for restoring audible speech in individuals who have lost the ability to speak intelligibly due to laryngectomy, neuromuscular diseases, stroke, or trauma-induced damage (e.g., from radiotherapy) to the speech articulators. Approach. To achieve this, we collect EMG signals from the face, jaw, and neck as subjects articulate speech, and we perform EMG-to-speech translation. Main results. Our findings reveal that the manifold of symmetric positive definite (SPD) matrices serves as a natural embedding space for EMG signals. Specifically, we provide an algebraic interpretation of the manifold-valued EMG data using linear transformations, and we analyze and quantify distribution shifts in EMG signals across individuals. Significance. Overall, our approach demonstrates significant potential for developing neural networks that are both data- and parameter-efficient, an important consideration for EMG-based systems, which face challenges in large-scale data collection and operate under limited computational resources on embedded devices.
title Geometry of orofacial neuromuscular signals: speech articulation decoding using surface electromyography
topic Computation and Language
url https://arxiv.org/abs/2411.02591