Abstract
A brain-computer interface (BCI) provides a direct communication channel between a brain and an external device. Steady-state visual evoked potential based BCI (SSVEP-BCI) has received increasing attention due to its high information transfer rate, which is accomplished by individual calibration for frequency recognition. Task-related component analysis (TRCA) is a recent and state-of-the-art method for individually calibrated SSVEP-BCIs. However, in TRCA, the spatial filter learned from each stimulus may be redundant and temporal information is not fully utilized. To address this issue, this paper proposes a novel method, i.e., task-discriminant component analysis (TDCA), to further improve the performance of individually calibrated SSVEP-BCI. The performance of TDCA was evaluated by two publicly available benchmark datasets, and the results demonstrated that TDCA outperformed ensemble TRCA and other competing methods by a significant margin. An offline and online experiment testing 12 subjects further validated the effectiveness of TDCA. The present study provides a new perspective for designing decoding methods in individually calibrated SSVEP-BCI and presents insight for its implementation in high-speed brain speller applications.
Highlights
A brain-computer interface (BCI) enables people to interface and interact with the outside world by leveraging brain signals related to sensation, perception or high-level cognitive activities [1]
The result showed that task-discriminant component analysis (TDCA) outperformed ensemble task-related component analysis (TRCA) at all data lengths
Paired t-test revealed that the difference for accuracy between TRCA and TDCA was statistically significant (p < .05) for all data lengths, and for data lengths greater than 0.1 s on the information transfer rate (ITR)
Summary
A brain-computer interface (BCI) enables people to interface and interact with the outside world by leveraging brain signals related to sensation, perception or high-level cognitive activities [1]. Steady-state visual evoked potential based BCI (SSVEP-BCI) [2] has enjoyed wide-spread adoption due to its advantages in high information transfer rate (ITR), low cost, and ease of use. The merit of high ITR is attributable to the high signal-to-noise ratio (SNR) profile of SSVEP, which is a frequency-tagged occipital brain signal that can be evoked by flickers, moving gratings, and reversible checkerboards. The relatively high performance of SSVEP-BCI helps with the development of practical applications related to dialing [3] and spelling [2], as well as other end-user applications, e.g., wheelchair control [4], and smart home applications[5]
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