元认知规划支架在计算思维培养中的应用

IF 4 2区 教育学 Q1 EDUCATION & EDUCATIONAL RESEARCH
Ying Zhou, C. Chai, Xiuting Li, Chao Ma, Baoping Li, Ding Yu, Jyh‐Chong Liang
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引用次数: 1

摘要

计算思维是一种帮助人们“像计算机科学家一样思考”来解决实际问题的思维方式。然而,通过编程练习计算思维依赖于问题解决者的元认知。本研究通过两项定量研究考察了学生在程序设计中的元认知计划和问题解决表现。首先,我们分析了21名大一新生的元认知规划和通过编程解决问题的表现,发现与“问题描述”和“节目理解”相关的元认知规划表现与解决问题的表现显著相关。其次,在第一次研究的基础上设计了半支架和全支架。另外89名新生被随机分成三组,分别用无支架、半支架和全支架三种方式编写编程计划。ANCOVA结果显示,无支架组的问题解决能力明显弱于其他两组,而半支架组与全支架组的问题解决能力无显著差异。研究表明,半支架与完全支架在解决问题方面的效果相似。本研究建议教师应着重利用半脚手架来支持学生的“问题描述”和“程序理解”。这种支架式技术在编程中通过解决问题来训练学生的计算思维是充分而有效的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Application of Metacognitive Planning Scaffolding for the Cultivation of Computational Thinking
Computational thinking is a way of thinking that helps people “think like a computer scientist” to solve practical problems. However, practicing computational thinking through programming is dependent on the problem solvers’ metacognition. This study investigated students’ metacognitive planning and problem-solving performance in programming through two quantitative studies. First, we analyzed the performance of metacognitive planning and of problem solving through the programming of 21 freshmen, and found that the metacognitive planning performance related to “problem description” and “program comprehension” was significantly correlated with problem-solving performance. Second, semi-scaffolding and full-scaffolding were designed based on the first study. Another 89 freshmen were randomly divided into three groups and were asked to write their programming plan with no-scaffolding, semi-scaffolding, or with full-scaffolding. ANCOVA revealed that the problem-solving performance of the no-scaffolding group was significantly weaker than that of the other two groups, but there was no significant difference between the semi-scaffolding and the full-scaffolding groups. The study indicated that semi-scaffolding had a similar effect to full-scaffolding on problem-solving performance. The study suggests that teachers should emphasize supporting students’ “problem description” and “program comprehension” using semi-scaffolding. This scaffolding technique is sufficient and efficient for training students’ computational thinking through problem solving in programming.
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来源期刊
Journal of Educational Computing Research
Journal of Educational Computing Research EDUCATION & EDUCATIONAL RESEARCH-
CiteScore
11.90
自引率
6.20%
发文量
69
期刊介绍: The goal of this Journal is to provide an international scholarly publication forum for peer-reviewed interdisciplinary research into the applications, effects, and implications of computer-based education. The Journal features articles useful for practitioners and theorists alike. The terms "education" and "computing" are viewed broadly. “Education” refers to the use of computer-based technologies at all levels of the formal education system, business and industry, home-schooling, lifelong learning, and unintentional learning environments. “Computing” refers to all forms of computer applications and innovations - both hardware and software. For example, this could range from mobile and ubiquitous computing to immersive 3D simulations and games to computing-enhanced virtual learning environments.
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