Abstract
Multiplexed deep neural networks (DNN) have engendered high-performance predictive models gaining popularity for decoding brain waves, extensively collected in the form of electroencephalogram (EEG) signals. In this paper, to the best of our knowledge, we introduce a first-ever DNN-based generalized approach to estimate reaction time (RT) using the periodogram representation of single-trial EEG in a visual stimulus-response experiment with 48 participants. We have designed a Fully Connected Neural Network (FCNN) and a Convolutional Neural Network (CNN) to predict and classify RTs for each trial. Though deep neural networks are widely known for classification applications, cascading FCNN/CNN with the Random Forest model, we designed a robust regression-based estimator to predict RT. With the FCNN model, the accuracies obtained for binary and 3-class classification were 93% and 76%, respectively, which further improved with the use of CNN (94% and 78%, respectively). The regression-based approach predicted RTs with correlation coefficients (CC) of 0.78 and 0.80 for FCNN and CNN, respectively. Investigating further, we found that the left central as well as parietal and occipital lobes were crucial for predicting RT, with significant activities in the theta and alpha frequency bands.
Highlights
Thanks to advancements in sensor and hardware capabilities, and signal processing techniques, we have better tools to understand the brain
Moving average operations on individual reaction time (RT) show an upward trend for most participants (75%), intimating a decrease in response speed over time
Apart from that, the overall variation of RTs can be observed by sorting the RTs of a subject from low to high
Summary
Thanks to advancements in sensor and hardware capabilities, and signal processing techniques, we have better tools to understand the brain. This paper focuses on analyzing human response towards visual stimulus and provides methods of estimating RT from information embedded in electroencephalogram (EEG) signals [2]. EEG frequency and reaction time-based sequential analysis was performed in one of the prior studies to establish a relationship between speed of response and background frequency [16]. Another study demonstrated an experiment to monitor EEG signal and reaction time during a normoxic saturation dive. Visual evoked responses (VERs), electroencephalograms (EEGs), and simple reaction time (RT) were measured for all. One of the studies tried to apply a method for temporally extracting stimulus and response-locked components of brain activity from human scalp electroencephalography (EEG) during an auditory simple reaction time task [18].
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