Limb Position Effect in Myoelectric Control: Strategies for Optimisation and Standardisation
Listed in
This article is not in any list yet, why not save it to one of your lists.Abstract
Objective
Myoelectric control uses electromyography (EMG) signals for muscle-machine interfacing with applications in prostheses, augmented/virtual reality, and consumer electronics. However, factors such as changes in the limb’s position during activities of daily living reduce the controller’s reliability. Therefore, there is a need to develop techniques that reduce this limb position effect to increase the widespread adoption of these technologies.
Approach
We developed an open-source device to standardise myoelectric control experiments. The device has sixteen locations for automatically positioning the participant’s arms to perform hand gestures or grasp objects, with lights and sensors for guidance and timekeeping. We used this device to collect data from eighteen healthy participants in a five-session study under three modalities: performing five hand gestures with a static or dynamic limb and moving three objects. We recorded forearm electromyography and kinematics of the upper limb and trained a linear discriminant analysis model to assess the classifier’s accuracy across different modalities and arm positions.
Main results
The classifier’s accuracy with a static limb was decreased when tested on untrained positions, confirming the limb position effect. More training positions improved accuracy, with four optimally balancing the training burden and classifier accuracy. Classifiers trained with data from dynamic movements outperformed when tested on dynamic data. Furthermore, adding kinematic data to the classifier increased accuracy yet significantly reduced learning rates. However, training with a dynamic limb improved this learning rate.
Significance
The limb position effect can be countered by training with multiple positions and including kinematic data. Classifiers with EMG and kinematic data should be trained using a dynamic limb to achieve high accuracy with reasonable amounts of training data. Our open-source, automated device will help standardise datasets between laboratories, aiding the further development of robust and widespread myoelectric control.
