EDAPT: Towards Calibration-Free BCIs with Continual Online Adaptation

TL;DR

EDAPT is a novel framework that enables calibration-free brain-computer interfaces by continually adapting models online, improving accuracy without user-specific calibration, and demonstrating efficiency and scalability across multiple datasets.

Contribution

EDAPT introduces a task- and model-agnostic continual adaptation framework that eliminates calibration in BCIs through online personalized model updates.

Findings

EDAPT consistently improves accuracy over static methods across nine datasets.

Combining population pretraining with online finetuning enhances performance.

Model updates are efficient, completing within 200 milliseconds on standard hardware.

Abstract

Brain-computer interfaces (BCIs) suffer from accuracy degradation as neural signals drift over time and vary across users, requiring frequent recalibration that limits practical deployment. We introduce EDAPT, a task- and model-agnostic framework that eliminates calibration through continual model adaptation. EDAPT first trains a baseline decoder using data from multiple users, then continually personalizes this model via supervised finetuning as the neural patterns evolve during use. We tested EDAPT across nine datasets covering three BCI tasks, and found that it consistently improved accuracy over conventional, static methods. These improvements primarily stem from combining population-level pretraining and online continual finetuning, with unsupervised domain adaptation providing further gains on some datasets. EDAPT runs efficiently, updating models within 200 milliseconds on consumer-grade hardware. Finally, decoding accuracy scales with total data budget rather than its allocation between subjects and trials. EDAPT provides a practical pathway toward calibration-free BCIs, reducing a major barrier to BCI deployment.