EEG-based image classification using an efficient geometric deep network based on functional connectivity

Q1 Engineering
H. Hasan, Mais A. Al-Sharqi
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引用次数: 0

Abstract

To ensure that the FC-GDN is properly calibrated for the EEG-ImageNet dataset, we subject it to extensive training and gather all of the relevant weights for its parameters. Making use of the FC-GDN pseudo-code. The dataset is split into a "train" and "test" section in Kfold cross-validation. Ten-fold recommends using ten folds, with one fold being selected as the test split at each iteration. This divides the dataset into 90% training data and 10% test data. In order to train all 10 folds without overfitting, it is necessary to apply this procedure repeatedly throughout the whole dataset. Each training fold is arrived at after several iterations. After training all ten folds, results are analyzed. For each iteration, the FC-GDN weights are optimized by the SGD and ADAM optimizers. The ideal network design parameters are based on the convergence of the trains and the precision of the tests. This study offers a novel geometric deep learning-based network architecture for classifying visual stimulation categories using electroencephalogram (EEG) data from human participants while they watched various sorts of images. The primary goals of this study are to (1) eliminate feature extraction from GDL-based approaches and (2) extract brain states via functional connectivity. Tests with the EEG-ImageNet database validate the suggested method's efficacy. FC-GDN is more efficient than other cutting-edge approaches for boosting classification accuracy, requiring fewer iterations. In computational neuroscience, neural decoding addresses the problem of mind-reading. Because of its simplicity of use and temporal precision, Electroencephalographys (EEG) are commonly employed to monitor brain activity. Deep neural networks provide a variety of ways to detecting brain activity. Using a Function Connectivity (FC) - Geometric Deep Network (GDN) and EEG channel functional connectivity, this work directly recovers hidden states from high-resolution temporal data. The time samples taken from each channel are utilized to represent graph signals on a topological connection network based on EEG channel functional connectivity. A novel graph neural network architecture evaluates users' visual perception state utilizing extracted EEG patterns associated to various picture categories using graphically rendered EEG recordings as training data. The efficient graph representation of EEG signals serves as the foundation for this design. Proposal for an FC-GDN EEG-ImageNet test. Each category has a maximum of 50 samples. Nine separate EEG recorders were used to obtain these images. The FC-GDN approach yields 99.4% accuracy, which is 0.1% higher than the most sophisticated method presently available
基于函数连通性的高效几何深度网络在脑电图像分类中的应用
为了确保为EEG ImageNet数据集正确校准FC-GDN,我们对其进行了广泛的训练,并收集了其参数的所有相关权重。使用FC-GDN伪代码。在Kfold交叉验证中,数据集被划分为“训练”和“测试”部分。十倍建议使用十倍,每次迭代时选择一倍作为测试拆分。这将数据集划分为90%的训练数据和10%的测试数据。为了在不过度拟合的情况下训练所有10个折叠,有必要在整个数据集中重复应用此过程。每个训练折叠都是经过几次迭代后得出的。在训练完全部十个折叠后,对结果进行分析。对于每次迭代,FC-GDN权重由SGD和ADAM优化器进行优化。理想的网络设计参数是基于列车的收敛性和测试的精度。这项研究提供了一种新的基于几何深度学习的网络架构,用于使用人类参与者在观看各种图像时的脑电图(EEG)数据对视觉刺激类别进行分类。本研究的主要目标是(1)消除基于GDL的方法中的特征提取,以及(2)通过功能连接提取大脑状态。EEG ImageNet数据库的测试验证了所提出方法的有效性。FC-GDN在提高分类精度方面比其他尖端方法更有效,需要更少的迭代。在计算神经科学中,神经解码解决了读心术的问题。由于其使用简单且时间精确,脑电图(EEG)通常用于监测大脑活动。深度神经网络提供了多种检测大脑活动的方法。利用函数连通性(FC)-几何深度网络(GDN)和脑电通道函数连通性,该工作直接从高分辨率时间数据中恢复隐藏状态。从每个通道获取的时间样本用于表示基于EEG通道功能连通性的拓扑连接网络上的图形信号。一种新颖的图神经网络架构利用提取的与各种图片类别相关联的EEG模式来评估用户的视觉感知状态,其中使用图形渲染的EEG记录作为训练数据。EEG信号的高效图形表示是该设计的基础。FC-GDN EEG ImageNet测试提案。每个类别最多有50个样本。九个独立的脑电图记录器被用来获得这些图像。FC-GDN方法的准确率为99.4%,比目前最复杂的方法高出0.1%
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来源期刊
CiteScore
1.90
自引率
0.00%
发文量
140
审稿时长
7 weeks
期刊介绍: *Industrial Engineering: 1 . Ergonomics 2 . Manufacturing 3 . TQM/quality engineering, reliability/maintenance engineering 4 . Production Planning 5 . Facility location, layout, design, materials handling 6 . Education, case studies 7 . Inventory, logistics, transportation, supply chain management 8 . Management 9 . Project/operations management, scheduling 10 . Information systems for production and management 11 . Innovation, knowledge management, organizational learning *Mechanical Engineering: 1 . Energy 2 . Machine Design 3 . Engineering Materials 4 . Manufacturing 5 . Mechatronics & Robotics 6 . Transportation 7 . Fluid Mechanics 8 . Optical Engineering 9 . Nanotechnology 10 . Maintenance & Safety *Computer Science: 1 . Computational Intelligence 2 . Computer Graphics 3 . Data Mining 4 . Human-Centered Computing 5 . Internet and Web Computing 6 . Mobile and Cloud computing 7 . Software Engineering 8 . Online Social Networks *Electrical and electronics engineering 1 . Sensor, automation and instrumentation technology 2 . Telecommunications 3 . Power systems 4 . Electronics 5 . Nanotechnology *Architecture: 1 . Advanced digital applications in architecture practice and computation within Generative processes of design 2 . Computer science, biology and ecology connected with structural engineering 3 . Technology and sustainability in architecture *Bioengineering: 1 . Medical Sciences 2 . Biological and Biomedical Sciences 3 . Agriculture and Life Sciences 4 . Biology and neuroscience 5 . Biological Sciences (Botany, Forestry, Cell Biology, Marine Biology, Zoology) [...]
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