A Flipped Systematic Debugging Approach to Enhance Elementary Students’ Program Debugging Performance and Optimize Cognitive Load

IF 4 2区教育学 Q1 EDUCATION & EDUCATIONAL RESEARCH

Journal of Educational Computing Research Pub Date : 2023-03-16 DOI:10.1177/07356331221133560

Xuemin Gao, K. Hew

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引用次数: 1

Abstract

Reintroducing computer science (CS) education in K–12 schools to promote computational thinking (CT) has attracted significant attention among scholars and educators. Among the several essential components included in CS and CT education, program debugging is an indispensable skill. However, debugging teaching has often been overlooked in K–12 contexts, and relevant empirical studies are lacking in the literature. Moreover, novices generally have poor performance in domain knowledge and strategic knowledge concerning debugging. They also consistently experience a high cognitive burden in debugging learning. To address these gaps, we developed a flipped systematic debugging approach combined with a systematic debugging process (SDP) and the modeling method. A quasi-experimental study was conducted to explore the effectiveness of this flipped systematic debugging approach, in which 83 fifth-grade students attended the flipped debugging training lessons with the SDP–modeling method, and 75 fifth-grade students attended the unassisted flipped debugging training lessons without the SDP–modeling method. The results indicated that flipped debugging training using the SDP–modeling method improved students’ debugging skills. The results from the questionnaire showed that the proposed teaching approach increased the students’ investment in germane cognitive load by promoting schema construction. It also helped reduce students’ intrinsic and extraneous cognitive load in learning.

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提高小学生程序调试性能及优化认知负荷的翻转系统调试方法

在K-12学校重新引入计算机科学(CS)教育以促进计算思维(CT)已经引起了学者和教育工作者的极大关注。在计算机科学和计算机科学教育的几个重要组成部分中，程序调试是一项不可或缺的技能。然而，在K-12背景下，调试教学往往被忽视，文献中缺乏相关的实证研究。此外，新手在领域知识和与调试相关的策略知识方面的表现普遍较差。他们在调试学习中也一直经历着很高的认知负担。为了解决这些差距，我们开发了一种与系统调试过程(SDP)和建模方法相结合的翻转系统调试方法。通过准实验研究探讨该翻转系统调试方法的有效性，83名五年级学生参加了采用sdp建模方法的翻转调试实训课程，75名五年级学生参加了不采用sdp建模方法的无辅助翻转调试实训课程。结果表明，采用sdp建模方法的翻转调试训练提高了学生的调试技能。问卷调查结果表明，所提出的教学方法通过促进图式构建，增加了学生对关联认知负荷的投入。它还有助于减少学生在学习中的内在和外在的认知负荷。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Educational Computing Research EDUCATION & EDUCATIONAL RESEARCH-

CiteScore

11.90

自引率

6.20%

发文量

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.