TinyMyo: a Tiny Foundation Model for Flexible EMG Signal Processing at the Edge

TL;DR

TinyMyo is a compact, self-supervised Transformer-based foundation model for EMG signal processing that generalizes well across tasks and can be deployed on ultra-low power edge devices, enabling scalable human-machine interfaces.

Contribution

This work introduces TinyMyo, the first ultra-low power EMG foundation model capable of multi-task learning and deployment on microcontrollers, advancing edge biosignal processing.

Findings

Achieves state-of-the-art performance on multiple EMG datasets.

Supports multiple downstream tasks with minimal task-specific adaptation.

Successfully deployed on a microcontroller with low inference time and energy consumption.

Abstract

Objective: Surface electromyography (EMG) is a non-invasive sensing modality widely used in biomechanics, rehabilitation, prosthetic control, and human-machine interfaces. Despite decades of use, achieving robust generalization across subjects, recording systems, and acquisition protocols remains challenging. While foundation models (FMs) are gaining traction for EMG, existing approaches remain limited to single downstream tasks and lack deployability on embedded platforms. This work addresses these limitations. Methods: We present TinyMyo, a lightweight FM based on a Transformer encoder architecture. The model is pre-trained in a self-supervised manner using masked reconstruction on publicly available datasets. With only 3.6M parameters, TinyMyo is designed to support multiple downstream tasks through minimal task-specific head adaptations. Results: We demonstrate generalization across hand gesture classification, hand kinematic regression, speech production and speech recognition, with performance comparable to or surpassing the state of the art (SoA), and model size below 5M parameters. We achieve SoA results compared to previous FM-based works on the NinaPro DB5 (89.4%), UCI-EMG (97.56%), and EPN-612 (96.74%) datasets. We demonstrate the first-time deployment of an EMG FM on an ultra-low power microcontroller (GAP9), with an inference time of 0.785 s, energy of 44.91 mJ and power envelope of 57.18 mW. Conclusion: TinyMyo demonstrates that compact, self-supervised EMG FM can guarantee strong generalization across multiple downstream tasks while remaining compatible with low-power edge devices. Significance: TinyMyo is the first EMG FM for ultra-low power edge devices, enabling scalable and energy-efficient sensing for motor intent decoding, neuromuscular assessment, and biosignal driven human-machine interaction.