Nurul N. Jamal, Dayang N. A. Jawawi, Rohayanti Hassan, Radziah Mohamad, Shahliza A. Halim, Nor A. Saadon, Mohd A. Isa, Haza N. A. Hamed
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There is a lack of research that designed CT learning through ER specifically based on student's preferences. Besides, it resulted in a challenge to determine the suitability of CT and ER for different kind of preferences. Therefore, this study aimed to develop an adaptive learning (AL) framework for students to deliver learning of CT through ER. The framework consists of three submodels: domain model, student model, and adaptation model. One case study is defined, which is learning the introductory level of CT through ER (CTER). At the end of the study, it can be observed that the AL framework produced positive results in performance and perception for various student categories. It was noted that students utilizing the AL framework had superior understanding of CTER. 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引用次数: 0
摘要
计算思维(CT)已在全球教育系统中得到推广,是科技公民的一项基本技能。为帮助引入、改进和提供计算思维,人们规划并制定了各种策略。其中一项策略就是为 CT 学习创建和开发辅助工具。本文选择教育机器人(ER)作为支持 CT 学习的重点工具。每种 CT 和 ER 都有大量的研究领域。有各种报告指出,将 CT 学科与教育机器人技术相结合,对学生的学习很有帮助。然而,并非所有学生的学习和思维方式都是相似的。他们的个性特征存在差异。目前还缺乏专门根据学生的喜好设计通过 ER 学习 CT 的研究。此外,如何确定 CT 和 ER 是否适合不同类型的偏好也是一项挑战。因此,本研究旨在为学生开发一个自适应学习(AL)框架,通过ER提供CT学习。该框架由三个子模型组成:领域模型、学生模型和适应模型。本研究定义了一个案例研究,即通过 ER 学习 CT 入门级课程(CTER)。研究结果表明,AL 框架为各类学生的学习成绩和感知能力带来了积极的影响。我们注意到,使用 AL 框架的学生对 CTER 有更好的理解。无论是单独还是合作学习,所有应用或未应用 AL 框架学习 CTER 入门的学生都取得了积极的学习成果。
Adaptive learning framework for learning computational thinking using educational robotics
Computational thinking (CT) has been promoted worldwide by educational systems and is an essential skill for technological citizens. Various strategies have been planned and developed to help in introducing, improving, and delivering CT. One of the strategies is by creating and developing the supporting tools for CT learning. In this article, educational robotics (ER) is chosen as the focus tool to support CT learning. Each CT and ER has a massive field of study. There are various available reports determining the suitability of CT subject integrated with ER for students' learning. However, all students do not develop similar style of learning and thinking. There is difference in their personal traits. There is a lack of research that designed CT learning through ER specifically based on student's preferences. Besides, it resulted in a challenge to determine the suitability of CT and ER for different kind of preferences. Therefore, this study aimed to develop an adaptive learning (AL) framework for students to deliver learning of CT through ER. The framework consists of three submodels: domain model, student model, and adaptation model. One case study is defined, which is learning the introductory level of CT through ER (CTER). At the end of the study, it can be observed that the AL framework produced positive results in performance and perception for various student categories. It was noted that students utilizing the AL framework had superior understanding of CTER. Individually or collaboratively, all students who applied or did not apply the AL framework in studying the CTER introduction had positive learning outcomes.
期刊介绍:
Computer Applications in Engineering Education provides a forum for publishing peer-reviewed timely information on the innovative uses of computers, Internet, and software tools in engineering education. Besides new courses and software tools, the CAE journal covers areas that support the integration of technology-based modules in the engineering curriculum and promotes discussion of the assessment and dissemination issues associated with these new implementation methods.