Reconstruction of Surface EMG Signal using IMU data for Upper Limb Actions
This work addresses muscle intent detection for applications like prosthetics and rehabilitation biofeedback, but it is incremental as it builds on existing methods for signal reconstruction.
The paper tackled the problem of synthesizing surface electromyography (sEMG) signals from IMU data for upper limb actions using a deep learning model, achieving high temporal fidelity in predicting muscle activation timing and shape, though peak amplitudes were often underestimated.
Surface Electromyography (sEMG) provides vital insights into muscle function, but it can be noisy and challenging to acquire. Inertial Measurement Units (IMUs) provide a robust and wearable alternative to motion capture systems. This paper investigates the synthesis of normalized sEMG signals from 6-axis IMU data using a deep learning approach. We collected simultaneous sEMG and IMU data sampled at 1~KHz for various arm movements. A Sliding-Window-Wave-Net model, based on dilated causal convolutions, was trained to map the IMU data to the sEMG signal. The results show that the model successfully predicts the timing and general shape of muscle activations. Although peak amplitudes were often underestimated, the high temporal fidelity demonstrates the feasibility of using this method for muscle intent detection in applications such as prosthetics and rehabilitation biofeedback.