创建一个动态专家-使用主成分分析和机器学习模型的大脑活动识别

IF 2.1 3区心理学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Cognitive Systems Research Pub Date : 2025-01-01 DOI:10.1016/j.cogsys.2024.101314

Ismail M. Gadzhiev , Alexander S. Makarov , Vadim L. Ushakov , Vyacheslav A. Orlov , Georgy A. Ivanitsky , Sergei A. Dolenko

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引用次数: 0

摘要

本研究探讨了利用功能磁共振成像数据开发一个能够识别认知状态和转换的动态专家的可行性。研究人员收集了31名参与者在fMRI扫描期间执行空间和语言任务的数据，并使用九步算法对其进行预处理，以去除伪影和去噪。研究了三种类型的分类问题，使用机器学习方法和降维技术对活动状态进行分类。为每个分类问题确定了性能最好的模型，从而深入了解了它们的适用性。值得注意的是，静息状态与活动状态的二元分类方法相对简单，质量较好。一个关键的发现强调了在预测时刻之前考虑信号的时间历史对提高模型性能的重要性。

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Creating A dynamic cognovisor – Brain activity recognition using principal Component analysis and Machine learning models

This study explores the feasibility of developing a dynamic cognovisor capable of recognizing cognitive states and transitions using fMRI data. Data were collected from 31 participants performing spatial and verbal tasks during fMRI scanning and were preprocessed using a nine-step algorithm for artifact removal and denoising. Three types of classification problems were examined, with machine learning methods and dimensionality reduction techniques applied to classify activity states. The best-performing models were identified for each classification problem, providing insights into their applicability. Notably, binary classification of resting versus active states achieved good quality with relatively simple methods. A key finding underscores the importance of accounting for temporal history of the signal prior to the prediction moment to improve model performance.

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来源期刊

Cognitive Systems Research 工程技术-计算机：人工智能

CiteScore

9.40

自引率

5.10%

发文量

审稿时长

>12 weeks

期刊介绍： Cognitive Systems Research is dedicated to the study of human-level cognition. As such, it welcomes papers which advance the understanding, design and applications of cognitive and intelligent systems, both natural and artificial. The journal brings together a broad community studying cognition in its many facets in vivo and in silico, across the developmental spectrum, focusing on individual capacities or on entire architectures. It aims to foster debate and integrate ideas, concepts, constructs, theories, models and techniques from across different disciplines and different perspectives on human-level cognition. The scope of interest includes the study of cognitive capacities and architectures - both brain-inspired and non-brain-inspired - and the application of cognitive systems to real-world problems as far as it offers insights relevant for the understanding of cognition. Cognitive Systems Research therefore welcomes mature and cutting-edge research approaching cognition from a systems-oriented perspective, both theoretical and empirically-informed, in the form of original manuscripts, short communications, opinion articles, systematic reviews, and topical survey articles from the fields of Cognitive Science (including Philosophy of Cognitive Science), Artificial Intelligence/Computer Science, Cognitive Robotics, Developmental Science, Psychology, and Neuroscience and Neuromorphic Engineering. Empirical studies will be considered if they are supplemented by theoretical analyses and contributions to theory development and/or computational modelling studies.