An Accurate EEGNet-based Motor-Imagery Brain-Computer Interface for Low-Power Edge Computing

March 31, 2020 Β· Declared Dead Β· πŸ› IEEE International Symposium on Medical Measurements and Applications

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Authors Xiaying Wang, Michael Hersche, Batuhan TΓΆmekce, Burak Kaya, Michele Magno, Luca Benini arXiv ID 2004.00077 Category eess.SP: Signal Processing Cross-listed cs.HC, cs.LG Citations 91 Venue IEEE International Symposium on Medical Measurements and Applications Last Checked 4 months ago
Abstract
This paper presents an accurate and robust embedded motor-imagery brain-computer interface (MI-BCI). The proposed novel model, based on EEGNet, matches the requirements of memory footprint and computational resources of low-power microcontroller units (MCUs), such as the ARM Cortex-M family. Furthermore, the paper presents a set of methods, including temporal downsampling, channel selection, and narrowing of the classification window, to further scale down the model to relax memory requirements with negligible accuracy degradation. Experimental results on the Physionet EEG Motor Movement/Imagery Dataset show that standard EEGNet achieves 82.43%, 75.07%, and 65.07% classification accuracy on 2-, 3-, and 4-class MI tasks in global validation, outperforming the state-of-the-art (SoA) convolutional neural network (CNN) by 2.05%, 5.25%, and 5.48%. Our novel method further scales down the standard EEGNet at a negligible accuracy loss of 0.31% with 7.6x memory footprint reduction and a small accuracy loss of 2.51% with 15x reduction. The scaled models are deployed on a commercial Cortex-M4F MCU taking 101ms and consuming 4.28mJ per inference for operating the smallest model, and on a Cortex-M7 with 44ms and 18.1mJ per inference for the medium-sized model, enabling a fully autonomous, wearable, and accurate low-power BCI.
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