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https://gnanaganga.inflibnet.ac.in:8443/jspui/handle/123456789/16599
Title: | Enhancing Deep Learning for Autism Spectrum Disorder Detection with Dual-Encoder Gan-Based Augmentation of Electroencephalogram Data [Mejora Del Aprendizaje Profundo Para La Detección De Trastornos Del Espectro Autista Con Aumento De Datos De Electroencefalograma Basado En Gan De Codificador Dual] |
Authors: | Lalli, K Senbagavalli, M |
Keywords: | Autism Spectrum Disorder Class Imbalance Data Augmentation Differential Entropy Dual-Encoder Eeg Rest-Hgcn Wasserstein Gan |
Issue Date: | 2024 |
Publisher: | Salud, Ciencia y Tecnologia - Serie de Conferencias Editorial Salud, Ciencia y Tecnologia |
Citation: | Vol. 3 |
Abstract: | Autism Spectrum Disorder (ASD) is a general neurodevelopmental condition that requires early and accurate diagnosis. Electroencephalography (EEG) signals are reliable biomarkers for ASD detection and diagnosis. A recent Deep Learning (DL) model called Resting-state EEG-based Hybrid Graph Convolutional Network (Rest-HGCN) has been developed for this purpose. However, a challenge in ASD diagnosis is the limited availability of EEG data, leading to imbalanced classes and ineffective model training. To address this issue, a new approach is proposed in this paper, which involves a generative model for EEG data augmentation. A novel Dual Encoder-Balanced Conditional Wasserstein Generative Adversarial Network (DEBCWGAN) is designed to produce fine synthetic minority-class EEG examples and augment the original training dataset. This model integrates the Variational Auto-Encoder (VAE) and balanced conditional Wasserstein GAN. Initially, EEG signals for ASD in the training dataset are pre-processed as Differential Entropy (DE) features and split into different segments. Each feature segment is processed in the temporal and the spatial domain depending on the electrode place. Then, twin encoders are trained to capture both spatial and temporal information from these features, concatenate them as Latent Variables (LVs), and provide them to the decoder to produce synthetic EEG examples. Additionally, gradient penalty and L2 regularization are used to speed up convergence and prevent overfitting effectively. Further, the augmented dataset is used to train the Rest-HGCN for ASD detection, enhancing its robustness and generalizability. Finally, test outcomes demonstrate that the DEBWGAN-GP-Rest-HGCN on the EEG Dataset for ASD and ABC-CT dataset achieves 91,6 % and 88,1 % accuracy, respectively compared to the Rest-HGCN, AlexNet, K-Nearest Neighbor (KNN) and Support Vector Machine (SVM). © 2024; Los autores. |
URI: | https://doi.org/10.56294/sctconf2024958 https://gnanaganga.inflibnet.ac.in:8443/jspui/handle/123456789/16599 |
ISSN: | 2953-4860 |
Appears in Collections: | Journal Articles |
Files in This Item:
File | Size | Format | |
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SCTConf_2024_958.pdf | 1.39 MB | Adobe PDF | View/Open |
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