Abstract
In recent years, several assistive devices have been proposed to reconstruct arm and hand movements from electromyographic (EMG) activity. Although simple to implement and potentially useful to augment many functions, such myoelectric devices still need improvement before they become practical. Here we considered the problem of reconstruction of handwriting from multichannel EMG activity. Previously, linear regression methods (e.g., the Wiener filter) have been utilized for this purpose with some success. To improve reconstruction accuracy, we implemented the Kalman filter, which allows to fuse two information sources: the physical characteristics of handwriting and the activity of the leading hand muscles, registered by the EMG. Applying the Kalman filter, we were able to convert eight channels of EMG activity recorded from the forearm and the hand muscles into smooth reconstructions of handwritten traces. The filter operates in a causal manner and acts as a true predictor utilizing the EMGs from the past only, which makes the approach suitable for real-time operations. Our algorithm is appropriate for clinical neuroprosthetic applications and computer peripherals. Moreover, it is applicable to a broader class of tasks where predictive myoelectric control is needed.
Highlights
Handwriting is a unique development of human culture
In this paper we investigated the relationship between handwriting and neuromuscular activity measured by electromyography
We built and optimized the Kalman filter in order to reconstruct the pen coordinates based on the dynamical characteristics of handwriting and the corresponding EMG measurements
Summary
Handwriting is a unique development of human culture. From the physiological point of view, handwriting is a complex interplay between the nervous system and the numerous muscles of the upper extremity. Despite several attempts to study this intricate activity theoretically (Plamondon and Maarse, 1989; McKeague, 2005) and experimentally (Linderman et al, 2009; Huang et al, 2010; Li et al, 2013), it is still not well understood and can not be reliably replicated in prostheses. The relationship between the muscle force and the pen trajectory is complicated by the motor redundancy phenomenon (Bernstein, 1967; Guigon et al, 2006). One and the same movement can be accomplished via basically infinite number of muscle activation patterns.
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