基于动作类电子游戏不同水平人群的脑电beta节律频数分析法

doi:10.3969/j.issn.0258-8021.2021.05.08

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摘要动作类电子游戏是现代生活中一种重要的娱乐方式。近年的研究发现,动作类电子游戏能对玩家的多种认知功能(如选择性注意)产生影响,而这些认知能力通常与脑电beta节律有关。但是,传统的脑电节律分析主要关注时程上的平均节律强度,难以相对连续地刻画不同游戏水平人群在游戏过程中注意相关的beta节律变化。基于机器学习算法提出一种新的脑电beta节律频数分析方法。被试包含232位英雄联盟正常男性玩家,游戏水平按照游戏排位由低到高分为水平1～5(各组被试数分别为27,74,77,34和20人)。被试先后在静息态和游戏状态下进行脑电数据采集。以每位被试游戏态beta节律与静息态beta节律的差值为特征,采用高斯核支持向量机对测试集中每位被试所有数据段进行预测分类(即高/低水平beta模式),然后计算每例被试中高水平beta模式的数据段占其所有数据段总数的比例。最后,采用单因素方差分析对各游戏水平被试的频数进行统计分析,并将其与游戏表现评分得分进行皮尔逊相关分析。结果表明,在游戏过程中,高水平beta3模式的频数在组间具有显著差异(P<0.05,F=17.40),且随着游戏水平的升高呈现显著的上升趋势。基于聚类法(P<0.05,F=6.57)与线性判别方法(P<0.05,F=14.84)的频数分析结果也显示高水平beta3模式频数的组间差异显著。进一步,发现该频数与游戏表现评分呈正相关(P<0.05,r=0.22)。研究提示,不同游戏水平对注意相关脑功能的影响可以通过高水平beta模式频数法进行刻画。对于理解游戏对大脑的可塑性影响,所提出的方法提供了新的角度且具有较好的应用前景。

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	刘晓波
	赵铃铃
	李毅
	宫殿坤
	尧德中
	董立

关键词 ：动作类电子游戏, 脑电, beta节律, 机器学习, 频数分析

Abstract：Action video games (AVGs) have become one of the most prominent entertainment in contemporary life. Recently, many studies have shown that the action video games have important impacts on player′s cognitive functions such as attention, which is related to EEG beta rhythm. However, traditional EEG rhythm analysis is based on the average of power strength across temporal segments, which may be difficult to continuously assess the potential effects of AVG levels on brain function. Therefore, based on machine learning, we proposed a new EEG rhythm ratio analysis method. This study included 232 healthy League of Legends male players, and the game levels were divided into level 1 to level 5 (from low to high, corresponding to 27, 74, 77, 34 and 20 subjects) according to the expertise ranking. The game state and resting state EEG for each subject were both recorded. The proposed rhythm ratio analysis contained following steps: 1) difference values of beta rhythm power between game state and resting state were calculated and used as features; 2) all features of data segments for each subject would be relabeled using the support vector machine with radial basis function kernel (high-level/low-level beta pattern), while the training datasets were level 1 and level 5 groups (others were test dataset), and the ratios of predicted high-level beta patterns were obtained for each subject; and 3) finally, the effect of game level on the ratio of high-level beta patterns was assessed using one-way ANOVA, and Pearson′s correlation between game performance score and the ratio of high-level beta patterns was investigated. The results of one-way ANOVA depicted that there were significant differences among the different game level groups (P<0.05, F=17.40), and the ratio of high-level beta patterns was increasing with the increase of game level. There were also significant differences among the different game level groups using ratio analysis based on clustering (P<0.05,F=6.57) and linear discriminant (P<0.05,F=14.84) methods. Furthermore, there was a significant correlation between the game performance score and the ratio of high-level beta patterns (P<0.05, r=0.22). It is implied that the potential effects of action video game on brain function, such as attention, could be assessed by the proposed method. The results may provide a new sight to improve our understanding about brain plasticity related to AVGs.

Key words： action video game electroencephalogram beta rhythm machine learning ratio analysis

收稿日期: 2020-06-20

PACS:

R318

基金资助:#国家自然科学基金(81701778,61933003);四川省科技计划项目(2018JZ0073)

通讯作者: *E-mail: Lidong@uestc.edu.cn

引用本文:

刘晓波, 赵铃铃, 李毅, 宫殿坤, 尧德中, 董立. 基于动作类电子游戏不同水平人群的脑电beta节律频数分析法[J]. 中国生物医学工程学报, 2021, 40(5): 574-581.
Liu Xiaobo, Zhao Lingling, Li Yi, Gong Diankun, Yao Dezhong, Dong Li. EEG Beta Rhythm Ratio Analysis for Action Video Game Players with Different Game Levels. Chinese Journal of Biomedical Engineering, 2021, 40(5): 574-581.

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http://cjbme.csbme.org/CN/10.3969/j.issn.0258-8021.2021.05.08 或 http://cjbme.csbme.org/CN/Y2021/V40/I5/574

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