Abstract
Recently, convolutional neural network (CNN) has been widely investigated to decode human intentions using surface Electromyography (sEMG) signals. However, a pre-trained CNN model usually suffers from severe degradation when testing on a new individual, and this is mainly due to domain shift where characteristics of training and testing sEMG data differ substantially. To enhance inter-subject performances of CNN in the wrist kinematics estimation, we propose a novel regression scheme for supervised domain adaptation (SDA), based on which domain shift effects can be effectively reduced. Specifically, a two-stream CNN with shared weights is established to exploit source and target sEMG data simultaneously, such that domain-invariant features can be extracted. To tune CNN weights, both regression losses and a domain discrepancy loss are employed, where the former enable supervised learning and the latter minimizes distribution divergences between two domains. In this study, eight healthy subjects were recruited to perform wrist flexion-extension movements. Experiment results illustrated that the proposed regression SDA outperformed fine-tuning, a state-of-the-art transfer learning method, in both single-single and multiple-single scenarios of kinematics estimation. Unlike fine-tuning which suffers from catastrophic forgetting, regression SDA can maintain much better performances in original domains, which boosts the model reusability among multiple subjects.
Highlights
T HE surface electromyography reflects the electrical activity of muscle fibres during contraction, and it has been widely used for intelligent prostheses or exoskele-Manuscript received December 12, 2020; revised March 26, 2021; accepted May 27, 2021
Inspired by the recent success of DA in deep learning, we propose a novel regression scheme for supervised domain adaptation (SDA) to reduce domain shift effects on convolutional neural network (CNN)-based wrist kinematics estimation in the inter-subject circumstance
Since this study focused on the inter-subject transfer learning, the dataset of each subject was categorized as either the source or target domain for each TL process, which resulted in 56 processes in the single-single scenario
Summary
T HE surface electromyography (sEMG) reflects the electrical activity of muscle fibres during contraction, and it has been widely used for intelligent prostheses or exoskele-Manuscript received December 12, 2020; revised March 26, 2021; accepted May 27, 2021. To decode human intentions from sEMG more intuitively, artificial intelligence (AI) can be leveraged in either the classification-based hand gesture recognition [3], [4] or regression-based kinematic estimation [5], [6]. Different from the classification scheme which is only able to estimate discrete movements sequentially [7], regression approaches estimate continuous joint motions and can enable simultaneous and proportional control in multiple degrees of freedoms [8]
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