Mathematical Description and Mechanistic Reasoning: A Pathway toward STEM Integration.

Q1 Social Sciences

Journal of Pre-College Engineering Education Research Pub Date : 2017-07-02 DOI:10.7771/2157-9288.1124

P. Weinberg

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引用次数: 10

Abstract

Because reasoning about mechanism is critical to disciplined inquiry in science, technology, engineering, and mathematics (STEM) domains, this study focuses on ways to support the development of this form of reasoning. This study attends to how mechanistic reasoning is constituted through mathematical description. This study draws upon Smith’s (2007) characterization of mathematical description of scientific phenomena as ‘‘bootstrapping,’’ where negotiating the relationship between target phenomena and represented relations is fundamental to learning. In addition, the development of mathematical representation presents a viable pathway towards STEM integration. In this study, participants responded to an assessment of mechanistic reasoning while cognitive interviews were conducted to characterize their reasoning about mechanism and mathematical description of the systems of levers represented in the items. Participant item responses were modeled using item response theory and participant talk and gesture were coded according to developed analytic frameworks. Participants were elementary, middle, and high school students as well as college undergraduates, and adults without college education. The results suggest a relationship between participants’ tendencies to describe these systems mathematically and their mechanistic reasoning ability. Moreover, there are specific elements of mechanistic reasoning that are more highly associated with mathematical description. In addition, there is a relationship between a participant’s propensity to both mathematically describe and mechanistically trace mechanical systems.

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数学描述与机械推理:迈向STEM整合之路。

由于关于机制的推理对于科学、技术、工程和数学(STEM)领域的纪律探究至关重要，因此本研究侧重于支持这种推理形式发展的方法。本研究关注如何透过数学描述建构机械推理。本研究借鉴了Smith(2007)将科学现象的数学描述描述为“自举”的特征，即目标现象和表征关系之间的关系是学习的基础。此外，数学表示的发展为STEM整合提供了一条可行的途径。在这项研究中，参与者对机械推理的评估做出了回应，同时进行了认知访谈，以表征他们对项目中所代表的杠杆系统的机制和数学描述的推理。采用项目反应理论对参与者的项目反应进行建模，并根据已开发的分析框架对参与者的谈话和手势进行编码。参与者包括小学、初中、高中学生、大学本科生和没有受过大学教育的成年人。研究结果表明，参与者用数学方法描述这些系统的倾向与他们的机械推理能力之间存在关系。此外，机械推理的一些特定元素与数学描述的关系更为密切。此外，参与者在数学上描述和机械上追踪机械系统的倾向之间存在关系。

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 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.