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Improving AR-SSVEP Recognition Accuracy Under High Ambient Brightness Through Iterative Learning

Rui Zhang, Lijun Cao, Zongxin Xu, Yangsong Zhang, Lipeng Zhang, Yuxia Hu, Mingming Chen, Dezhong Yao

2023IEEE Transactions on Neural Systems and Rehabilitation Engineering25 citationsDOIOpen Access PDF

Abstract

Augmented reality-based brain-computer interface (AR-BCI) system is one of the important ways to promote BCI technology outside of the laboratory due to its portability and mobility, but its performance in real-world scenarios has not been fully studied. In the current study, we first investigated the effect of ambient brightness on AR-BCI performance. 5 different light intensities were set as experimental conditions to simulate typical brightness in real scenes, while the same steady-state visual evoked potentials (SSVEP) stimulus was displayed in the AR glass. The data analysis results showed that SSVEP can be evoked under all 5 light intensities, but the response intensity became weaker when the brightness increased. The recognition accuracies of AR-SSVEP were negatively correlated to light intensity, the highest accuracies were 89.35% with FBCCA and 83.33% with CCA under 0 lux light intensity, while they decreased to 62.53% and 49.24% under 1200 lux. To solve the accuracy loss problem in high ambient brightness, we further designed a SSVEP recognition algorithm with iterative learning capability, named ensemble online adaptive CCA (eOACCA). The main strategy is to provide initial filters for high-intensity data by iteratively learning low-light-intensity AR-SSVEP data. The experimental results showed that the eOACCA algorithm had significant advantages under higher light intensities ( 600 lux). Compared with FBCCA, the accuracy of eOACCA under 1200 lux was increased by 13.91%. In conclusion, the current study contributed to the in-depth understanding of the performance variations of AR-BCI under different lighting conditions, and was helpful in promoting the AR-BCI application in complex lighting environments.

Topics & Concepts

Brain–computer interfaceBrightnessComputer scienceLight intensitySoftware portabilityArtificial intelligenceVisual evoked potentialsIntensity (physics)Pattern recognition (psychology)Computer visionElectroencephalographyOpticsPhysicsPsychiatryPsychologyProgramming languageNeuroscienceBiologyEEG and Brain-Computer InterfacesAdvanced Memory and Neural ComputingNeuroscience and Neural Engineering
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