Temporal Out-of-Distribution Detection for Asynchronous Motor Imagery Brain-Computer Interfaces

TL;DR

This paper introduces a hierarchical, two-stage EEG detection framework for asynchronous motor-imagery brain-computer interfaces, improving out-of-distribution detection and control accuracy in continuous EEG streams.

Contribution

It proposes a novel TempDens method combining multiple scores for better OOD rejection and reframes online motor-imagery control as a hierarchical decision process.

Findings

Outperforms conventional OOD detection baselines in experiments.

Effectively supports task-state detection and OOD MI recognition.

Reframes BCI control as a hierarchical decision problem.

Abstract

Real online brain--computer interfaces operate on continuous electroencephalography (EEG) streams, where users are usually at rest and enter motor-imagery task states only intermittently. EEG windows may also arise from OOD MI activity outside the predefined control set. Conventional closed-set motor-imagery classifiers tend to assign such inputs to ID classes, which can cause erroneous control. To address this issue, this paper proposes a two-stage EEG detection framework for asynchronous motor-imagery brain--computer interfaces. A sliding-window mechanism continuously monitors EEG signals. The first stage uses an EEGNet-based rest/task gate to determine whether the current window should enter the control-decision process. The second stage performs ID MI classification and out-of-distribution detection only for task-state samples. To improve OOD rejection, we further propose TempDens, which combines classification-output energy, deep-feature density, and temporal-consistency scores to characterize distributional deviation from output, feature, and temporal-dynamic perspectives. Experimental results show that the proposed method effectively supports task-state detection and OOD MI recognition in continuous EEG streams, outperforming multiple conventional OOD baselines. This study reframes online motor-imagery control as a hierarchical decision problem involving continuous monitoring, state discrimination, ID classification, and OOD rejection.