TY - JOUR VL - 122 A1 - Abdullah A1 - Faye, I. A1 - Islam, M.R. JF - Engineering Applications of Artificial Intelligence UR - https://www.scopus.com/inward/record.uri?eid=2-s2.0-85150309438&doi=10.1016%2fj.engappai.2023.106122&partnerID=40&md5=5d7e377b1451a131fed6d56eabf4b2ea Y1 - 2023/// TI - A comparative study on end-to-end deep learning methods for Electroencephalogram channel selection ID - scholars18530 KW - Backpropagation; Brain computer interface; Convolutional neural networks; Learning systems; Long short-term memory; Network architecture KW - Brainâ??computer interface; Channel selection; Comparatives studies; Convolutional neural network; Deep learning; Electroencephalogram channel selection; End to end; Goal models; Learning methods; Wrapper methods KW - Electroencephalography N2 - The electroencephalogram (EEG) channel selection approach with deep neural networks enables us to fit the channel selection to the goal model without dealing with the high processing expenses associated with wrapper methods for an efficient, integrated brainâ??computer interface (BCIs) study. An end-to-end deep learning-based methodology is proposed in this work to choose the proper channels for BCI paradigms. The EEG channel selection and network parameters are optimized using a concrete selector layer. The Gumbel-softmax approach is used in this layer to include the discrete parameters involved in the selection process into continuous relaxations, allowing for end-to-end backpropagation learning of the parameters. This study suggests a regularization method to reduce this tendency, as the selection layer is frequently shown to include the same channel twice in a particular selection. We performed six models using the suggested framework, and our proposed study, MSFBCNN+LSTM, extracts significant and robust properties compared to other models. For verification, high gamma dataset is used for each model to investigate and observe good accuracy. Overall, the MSFBCNN+LSTM architecture has the maximum classification mean accuracy of 90.59 in the specified tasks. This paper suggests that using integrated architectures of deep learning model learns the best features and contributes to BCI's performance. © 2023 Elsevier Ltd N1 - cited By 0 AV - none ER -