Automated detection of learning stages and interaction difficulty from eye-tracking data within a mixed reality learning environmen

IF 3.5 Q3 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY Smart and Sustainable Built Environment Pub Date : 2023-01-09 DOI:10.1108/sasbe-07-2022-0129
O. Ogunseiju, Nihar J. Gonsalves, A. Akanmu, Yewande Abraham, C. Nnaji
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Abstract

PurposeConstruction companies are increasingly adopting sensing technologies like laser scanners, making it necessary to upskill the future workforce in this area. However, limited jobsite access hinders experiential learning of laser scanning, necessitating the need for an alternative learning environment. Previously, the authors explored mixed reality (MR) as an alternative learning environment for laser scanning, but to promote seamless learning, such learning environments must be proactive and intelligent. Toward this, the potentials of classification models for detecting user difficulties and learning stages in the MR environment were investigated in this study.Design/methodology/approachThe study adopted machine learning classifiers on eye-tracking data and think-aloud data for detecting learning stages and interaction difficulties during the usability study of laser scanning in the MR environment.FindingsThe classification models demonstrated high performance, with neural network classifier showing superior performance (accuracy of 99.9%) during the detection of learning stages and an ensemble showing the highest accuracy of 84.6% for detecting interaction difficulty during laser scanning.Research limitations/implicationsThe findings of this study revealed that eye movement data possess significant information about learning stages and interaction difficulties and provide evidence of the potentials of smart MR environments for improved learning experiences in construction education. The research implication further lies in the potential of an intelligent learning environment for providing personalized learning experiences that often culminate in improved learning outcomes. This study further highlights the potential of such an intelligent learning environment in promoting inclusive learning, whereby students with different cognitive capabilities can experience learning tailored to their specific needs irrespective of their individual differences.Originality/valueThe classification models will help detect learners requiring additional support to acquire the necessary technical skills for deploying laser scanners in the construction industry and inform the specific training needs of users to enhance seamless interaction with the learning environment.
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在混合现实学习环境中从眼动追踪数据中自动检测学习阶段和互动难度
目的建筑公司越来越多地采用激光扫描仪等传感技术,这使得有必要提高该领域未来的劳动力技能。然而,有限的现场访问阻碍了激光扫描的体验式学习,因此需要一个替代的学习环境。此前,作者探索了混合现实(MR)作为激光扫描的替代学习环境,但要促进无缝学习,这种学习环境必须是主动和智能的。为此,本研究调查了分类模型在MR环境中检测用户困难和学习阶段的潜力。设计/方法/方法该研究在MR环境中激光扫描的可用性研究中,对眼睛跟踪数据和大声思考数据采用了机器学习分类器,以检测学习阶段和交互困难。发现分类模型表现出了高性能,神经网络分类器在检测学习阶段时表现出优异的性能(99.9%的准确率),集成分类器在检测激光扫描过程中的交互困难时表现出84.6%的最高准确率。研究局限性/含义本研究结果表明,眼动数据具有关于学习阶段和互动困难的重要信息,并为智能MR环境在建筑教育中改善学习体验的潜力提供了证据。研究的意义进一步在于智能学习环境的潜力,它可以提供个性化的学习体验,最终改善学习效果。这项研究进一步强调了这种智能学习环境在促进包容性学习方面的潜力,通过这种环境,具有不同认知能力的学生可以体验到针对其特定需求的学习,而不考虑其个人差异。独创性/价值分类模型将有助于发现需要额外支持的学习者,以获得在建筑行业部署激光扫描仪所需的技术技能,并告知用户的具体培训需求,以增强与学习环境的无缝互动。
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来源期刊
Smart and Sustainable Built Environment
Smart and Sustainable Built Environment GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY-
CiteScore
9.20
自引率
8.30%
发文量
53
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