John T. Krall scite author profile

Transient muscle movements influence the temporal structure of myoelectric signal patterns, often leading to unstable prediction behavior from movement-pattern classification methods. We show that temporal convolutional network sequential models leverage the myoelectric signal's history to discover contextual temporal features that aid in correctly predicting movement intentions, especially during interclass transitions. We demonstrate myoelectric classification using temporal convolutional networks to effect 3 simultaneous hand and wrist degrees-of-freedom in an experiment involving nine humansubjects. Temporal convolutional networks yield significant (p < 0.001) performance improvements over other state-of-the-art methods in terms of both classification accuracy and stability.

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Unilateral Ophthalmoplegia With Paresis of Voluntary Upward Associated Ocular Movement

Krall¹

1907

The Journal of Nervous and Mental Disease

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John T. Krall

Stable Responsive EMG Sequence Prediction and Adaptive Reinforcement With Temporal Convolutional Networks

Stable Electromyographic Sequence Prediction During Movement Transitions using Temporal Convolutional Networks

Unilateral Ophthalmoplegia With Paresis of Voluntary Upward Associated Ocular Movement

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