Characterization and classification of EEG signals evoked by different CAD models

IF 2.2 3区工程技术 Q3 ENGINEERING, MANUFACTURING Human Factors and Ergonomics in Manufacturing & Service Industries Pub Date : 2024-02-13 DOI:10.1002/hfm.21027

Hongwei Niu, Jia Hao, Zhiyuan Ming, Xiaonan Yang, Lu Wang

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Abstract

The past two decades have witnessed dramatic advancement in computer-aided design (CAD). However, development of human–computer interfaces (HCI) for CAD have not kept up with these advances. Windows, Icons, Menus, Pointer (WIMP) is still the mainly used interface for CAD applications which limits the naturalness and intuitiveness of the CAD modeling process. As a novel interface, Brain–computer interfaces (BCIs) have great potential in the application of CAD modeling. Utilizing BCIs, the user can create CAD models just by thinking about it in principle, because BCIs provide an end-to-end interaction channel between users and CAD models. However, current related studies are mainly limited to the existing BCIs paradigms, while ignoring the relationship between electroencephalogram (EEG) signals and CAD models, which largely increases the cognitive load on the users. In this study, we aimed to explore the potential of using BCI to create CAD models directly independent of the classical BCIs paradigms. For this purpose, EEG signals evoked by six basic CAD models (i.e., point, square, trapezoid, line, triangle, and circle) were collected from 28 participants. After preprocessing and sub-trial principal components analysis (st-PCA) of recorded data, the peak, mean and time-frequency energy features were extracted from EEG signals. By applying the one-way repeated measures analysis of variance, we demonstrated that there were significant differences among these EEG features evoked by different CAD models. These features from EEG electrode channels ranked by mutual information were then used to train a discriminant classifier of genetic algorithm-based support vector machine. The empirical result showed that this classifier can discriminate the CAD models with an average accuracy of about 72%, which turns out that EEG based model generation is feasible, and provides the technical and theoretical basis for building a novel BCI for CAD modeling.

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不同 CAD 模型诱发的脑电信号的特征和分类

过去二十年，计算机辅助设计（CAD）取得了突飞猛进的发展。然而，计算机辅助设计（CAD）人机交互界面（HCI）的发展并没有跟上这些进步。Windows、图标、菜单、指针（WIMP）仍然是 CAD 应用程序的主要界面，这限制了 CAD 建模过程的自然性和直观性。作为一种新型界面，脑机接口（BCI）在 CAD 建模应用中具有巨大潜力。利用 BCI，用户原则上只需思考即可创建 CAD 模型，因为 BCI 为用户和 CAD 模型之间提供了端到端的交互通道。然而，目前的相关研究主要局限于现有的 BCIs 范例，而忽略了脑电图（EEG）信号与 CAD 模型之间的关系，这在很大程度上增加了用户的认知负荷。在本研究中，我们旨在探索利用 BCI 直接创建 CAD 模型的潜力，而不依赖于经典的 BCI 范例。为此，我们收集了 28 名参与者由六个基本 CAD 模型（即点、正方形、梯形、线、三角形和圆）诱发的脑电信号。在对记录数据进行预处理和子试验主成分分析（st-PCA）后，从脑电信号中提取了峰值、平均值和时频能量特征。通过应用单向重复测量方差分析，我们证明了不同 CAD 模型诱发的这些脑电图特征之间存在显著差异。然后，利用这些按互信息排序的脑电图电极通道特征来训练基于遗传算法的支持向量机判别分类器。实证结果表明，该分类器可以对 CAD 模型进行判别，平均准确率约为 72%，这证明基于脑电图的模型生成是可行的，并为构建用于 CAD 建模的新型 BCI 提供了技术和理论基础。

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来源期刊

Human Factors and Ergonomics in Manufacturing & Service Industries 管理科学-工程：制造

CiteScore

5.20

自引率

8.30%

发文量

审稿时长

6.0 months

期刊介绍： The purpose of Human Factors and Ergonomics in Manufacturing & Service Industries is to facilitate discovery, integration, and application of scientific knowledge about human aspects of manufacturing, and to provide a forum for worldwide dissemination of such knowledge for its application and benefit to manufacturing industries. The journal covers a broad spectrum of ergonomics and human factors issues with a focus on the design, operation and management of contemporary manufacturing systems, both in the shop floor and office environments, in the quest for manufacturing agility, i.e. enhancement and integration of human skills with hardware performance for improved market competitiveness, management of change, product and process quality, and human-system reliability. The inter- and cross-disciplinary nature of the journal allows for a wide scope of issues relevant to manufacturing system design and engineering, human resource management, social, organizational, safety, and health issues. Examples of specific subject areas of interest include: implementation of advanced manufacturing technology, human aspects of computer-aided design and engineering, work design, compensation and appraisal, selection training and education, labor-management relations, agile manufacturing and virtual companies, human factors in total quality management, prevention of work-related musculoskeletal disorders, ergonomics of workplace, equipment and tool design, ergonomics programs, guides and standards for industry, automation safety and robot systems, human skills development and knowledge enhancing technologies, reliability, and safety and worker health issues.