STEM集成设计

Q1 Social Sciences

Journal of Pre-College Engineering Education Research Pub Date : 2013-04-18 DOI:10.7771/2157-9288.1078

L. Berland

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引用次数: 68

摘要

我们越来越多地看到在高中课堂上强调STEM的整合，这样学生将学习和应用相关的数学和科学内容，同时培养工程思维习惯。然而，科学教育和工程教育的研究表明，真正整合STEM的目标充满了挑战。因此，本文报告了nsf资助的一个项目的努力，该项目将在科学课堂上学到的经验教训(其中科学学习目标在工程挑战中被语境化)转化为工程课堂上学到的经验教训(其中工程实践是一个额外的、重要的学习目标)。特别是，本文确定了促进学生在从事工程实践时应用数学和科学概念的设计原则。我们解释每个原则背后的意图和学习理论。此外，我们通过举例说明其在我们为期一年的工程课程中的应用来实现每个目标。我们越来越多地看到在高中课堂上强调STEM的整合，这样学生将学习和应用相关的数学和科学内容，同时培养工程思维习惯。然而，科学教育和工程教育的研究表明，真正整合STEM的目标充满了挑战。因此，本文报告了nsf资助的一个项目的努力，该项目将在科学课堂上学到的经验教训(其中科学学习目标在工程挑战中被语境化)转化为工程课堂上学到的经验教训(其中工程实践是一个额外的、重要的学习目标)。特别是，本文确定了促进学生在从事工程实践时应用数学和科学概念的设计原则。我们解释每个原则背后的意图和学习理论。此外，我们通过举例说明其在我们为期一年的工程课程中的应用来实现每个目标。

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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Designing for STEM Integration

Abstract We are increasingly seeing an emphasis on STEM integration in high school classrooms such that students will learn and apply relevant math and science content while simultaneously developing engineering habits of mind. However, research in both science education and engineering education suggests that this goal of truly integrating STEM is rife with challenges. As such, this paper reports upon the efforts of an NSF-funded project to translate the lessons learned in science classrooms—in which the science learning goals are contextualized within engineering challenges—to engineering classrooms—in which the engineering practices are an additional, and important, learning goal. In particular, this paper identifies design principles for facilitating student application of math and science concepts while they engage in the practices of engineering. We explain the intent and learning theories behind each principle. In addition, we reify each goal by illustrating its application in our yearlong engineering course. Abstract We are increasingly seeing an emphasis on STEM integration in high school classrooms such that students will learn and apply relevant math and science content while simultaneously developing engineering habits of mind. However, research in both science education and engineering education suggests that this goal of truly integrating STEM is rife with challenges. As such, this paper reports upon the efforts of an NSF-funded project to translate the lessons learned in science classrooms—in which the science learning goals are contextualized within engineering challenges—to engineering classrooms—in which the engineering practices are an additional, and important, learning goal. In particular, this paper identifies design principles for facilitating student application of math and science concepts while they engage in the practices of engineering. We explain the intent and learning theories behind each principle. In addition, we reify each goal by illustrating its application in our yearlong engineering course.

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来源期刊

Journal of Pre-College Engineering Education Research Social Sciences-Education

CiteScore

3.90

自引率

0.00%

发文量

审稿时长

32 weeks

期刊介绍： The Journal of Pre-College Engineering Education Research (J-PEER) is issued electronically twice a year and serves as a forum and community space for the publication of research and evaluation reports on areas of pre-college STEM education, particularly in engineering. J-PEER targets scholars and practitioners in the new and expanding field of pre-college engineering education. This journal invites authors to submit their original and unpublished work in the form of (1) research papers or (2) shorter practitioner reports in numerous areas of STEM education, with a special emphasis on cross-disciplinary approaches incorporating engineering. J-PEER publishes a wide range of topics, including but not limited to: research articles on elementary and secondary students’ learning; curricular and extracurricular approaches to teaching engineering in elementary and secondary school; professional development of teachers and other school professionals; comparative approaches to curriculum and professional development in engineering education; parents’ attitudes toward engineering; and the learning of engineering in informal settings.