迈向复杂系统理解的学习进展

Susan A. Yoon, Sao-Ee Goh, Zhitong Yang
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引用次数: 11

摘要

最近关于学生对复杂系统了解程度的研究表明,他们在理解非线性、复杂因果关系和分散控制等特定系统概念方面通常存在挑战。然而,这项研究尚未采用一种系统的方法,以有序的方式学习复杂系统,以符合下一代科学标准的要求,即在发展连续体中指导教学和学习的学习途径。在本文中,我们提出学习进阶研究可以为识别复杂系统理解能力的学习途径提供一个概念框架。作为发展进程的第一步,我们通过使用项目反应理论模型分析学生的书面反应,从最简单到最难的顺序阐明了一系列复杂的系统思想。结果表明,最容易理解的想法是那些与系统内的水平或规模以及系统的相互联系性质有关的想法。最难掌握的概念是那些与系统的分散组织和影响的不可预测或不确定性有关的概念。我们讨论了本研究在开发课程内容方面的启示,这些课程内容可以指导8-12年级的科学教育的学习体验。
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Toward a Learning Progression of Complex Systems Understanding
Recent research on what students know about complex systems shows that they typically have challenges in understanding particular system ideas such as nonlinearity, complex causality, and decentralized control. Yet this research has yet to adopt a systematic approach to learning about complex systems in an ordered way in line with the Next Generation Science Standards’ call for learning pathways that guide teaching and learning along a developmental continuum. In this paper, we propose that learning progressions research can provide a conceptual framework for identifying a learning pathway to complex systems understanding competence. As a first step in developing a progression, we articulate a sequence of complex systems ideas, from the least to most difficult, by analyzing students’ written responses using an item response theory model. Results show that the easiest ideas to comprehend are those that relate to levels or scales within systems and the interconnected nature of systems. The most difficult ideas to grasp are those related to the decentralized organization of the system and the unpredictable or nondeterministic nature of effects. We discuss implications for this research in terms of developing curricular content that can guide learning experiences in grades 8–12 science education.
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