Litcius/Paper detail

Learning Space-Time-Frequency Representation with Two-Stream Attention Based 3D Network for Motor Imagery Classification

Zhiyang Li, Jing Wang, Ziyu Jia, Youfang Lin

202019 citationsDOI

Abstract

Motor imagery (MI), as one of the important applications of brain-computer interface (BCI), has lately received great attention. However, current MI researches have not provided satisfactory representations of electroencephalogram (EEG), taking account of the space-time-frequency features for MI classification. Moreover, those models also lack the exploration of attentive spatial, temporal, and spectral dynamics. In this study, we propose TA3D (Two-stream Attention based 3D network), a novel model for MI classification. It mainly consists of two streams: the space-time stream and the space-frequency stream, representing and learning discriminative features in the space-time-frequency dimension. Specifically, each stream contains three key parts: 1) 3D representations of EEG signals depict the spatial information over temporal/spectral distributions; 2) Attention mechanisms adaptively explore attentive dynamics of EEG signals and focus on the most valuable information in separate dimensions; 3) 3D convolutions learn spatial representation, temporal dependence, and spectral dependence. The outputs of the two streams are concatenated for space-time-frequency feature fusion. Extensive experiments implemented on two BCI datasets demonstrate that our model outperforms state-of-the-art MI classification methods.

Topics & Concepts

Computer scienceDiscriminative modelMotor imageryBrain–computer interfaceRepresentation (politics)Artificial intelligencePattern recognition (psychology)ElectroencephalographyFeature vectorFocus (optics)Dimension (graph theory)Time–frequency analysisFeature (linguistics)Feature extractionSpeech recognitionComputer visionMathematicsPsychiatryPoliticsPhilosophyLinguisticsOpticsPure mathematicsPolitical sciencePsychologyLawFilter (signal processing)PhysicsEEG and Brain-Computer InterfacesNeural dynamics and brain functionFunctional Brain Connectivity Studies