Abstract
Objective. Support vector machines (SVM) have developed into a gold standard for accurate classification in brain–computer interfaces (BCI). The choice of the most appropriate classifier for a particular application depends on several characteristics in addition to decoding accuracy. Here we investigate the implementation of hidden Markov models (HMM) for online BCIs and discuss strategies to improve their performance. Approach. We compare the SVM, serving as a reference, and HMMs for classifying discrete finger movements obtained from electrocorticograms of four subjects performing a finger tapping experiment. The classifier decisions are based on a subset of low-frequency time domain and high gamma oscillation features. Main results. We show that decoding optimization between the two approaches is due to the way features are extracted and selected and less dependent on the classifier. An additional gain in HMM performance of up to 6% was obtained by introducing model constraints. Comparable accuracies of up to 90% were achieved with both SVM and HMM with the high gamma cortical response providing the most important decoding information for both techniques. Significance. We discuss technical HMM characteristics and adaptations in the context of the presented data as well as for general BCI applications. Our findings suggest that HMMs and their characteristics are promising for efficient online BCIs.
Highlights
Brain-Computer-Interface (BCI) oriented research has a principle goal of aiding disabled people suffering from severe motor impairments (Hoffmann et al, 2007; Palaniappan et al, 2009)
Our findings suggest that Hidden Markov Models (HMM) and their characteristics are promising for efficient online brain-computer interfaces
While the results suggest that high feature quality is the main factor for high performances in this ECoG data set, two key points have to be emphasized for the application of HMMs with respect to the present finger classification problem
Summary
Brain-Computer-Interface (BCI) oriented research has a principle goal of aiding disabled people suffering from severe motor impairments (Hoffmann et al, 2007; Palaniappan et al, 2009). The majority of research on BCI has been based on EEG data and restricted to simple experimental tasks using a small set of commands. In these studies (Cincotti, et al, 2003; Lee & Choi, 2003; Obermaier et al.,1999) information was extracted from a limited number of EEG channels over scalp sites of the right and left hemisphere. The signal quality of ECoG recorded brain activity outperforms the EEG-data with respect to higher amplitudes and higher signal-to-noise ratio (SNR), higher spatial resolution, and broader bandwidth (0–500Hz) (Crone et al 1998; Schalk 2010). ECoG-signals have the potential for improving earlier results of feature extraction and signal classification (Schalk, 2010)
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