Representational competence: towards a distributed and embodied cognition account

IF 4.7 2区教育学 Q1 EDUCATION & EDUCATIONAL RESEARCH

Studies in Science Education Pub Date : 2017-01-02 DOI:10.1080/03057267.2017.1248627

Prajakt Pande, S. Chandrasekharan

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引用次数: 58

Abstract

Abstract Multiple external representations (MERs) are central to the practice and learning of science, mathematics and engineering, as the phenomena and entities investigated and controlled in these domains are often not available for perception and action. MERs therefore play a twofold constitutive role in reasoning in these domains. Firstly, MERs stand in for the phenomena and entities that are imagined, and thus make possible scientific investigations. Secondly, related to the above, sensorimotor and imagination-based interactions with the MERs make possible focused cognitive operations involving these phenomena and entities, such as mental rotation and analogical transformations. These two constitutive roles suggest that acquiring expertise in science, mathematics and engineering requires developing the ability to transform and integrate the MERs in that field, in tandem with running operations in imagination on the phenomena and entities the MERs stand for. This core ability to integrate external and internal representations and operations on them – termed representational competence (RC) – is therefore critical to learning in science, mathematics and engineering. However, no general account of this core process is currently available. We argue that, given the above two constitutive roles played by MERs, a theoretical account of representational competence requires an explicit model of how the cognitive system interacts with external representations, and how imagination abilities develop through this process. At the applied level, this account is required to develop design guidelines for new media interventions for learning science and mathematics, particularly emerging ones that are based on embodied interactions. As a first step to developing such a theoretical account, we review the literature on learning with MERs, as well as acquiring RC, in chemistry, biology, physics, mathematics and engineering, from two perspectives. First, we focus on the important theoretical accounts and related empirical studies, and examine what is common about them. Second, we summarise the major trends in each discipline, and then bring together these trends. The results show that most models and empirical studies of RC are framed within the classical information processing approach, and do not take a constitutive view of external representations. To develop an account compatible with the constitutive view of external representations, we outline an interaction-based theoretical account of RC, extending recent advances in distributed and embodied cognition.

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代表能力：面向分布式和具体化的认知账户

摘要多重外部表征（MERs）是科学、数学和工程实践和学习的核心，因为在这些领域中研究和控制的现象和实体往往无法用于感知和行动。因此，MER在这些领域的推理中起着双重组成作用。首先，MER代表了想象中的现象和实体，从而使科学调查成为可能。其次，与上述相关，与MERs的基于感觉运动和想象的互动使涉及这些现象和实体的集中认知操作成为可能，如心理旋转和类比转换。这两个组成角色表明，获得科学、数学和工程方面的专业知识需要培养转换和整合该领域MER的能力，同时对MER所代表的现象和实体进行想象操作。因此，这种整合外部和内部表征及其操作的核心能力——称为表征能力（RC）——对科学、数学和工程学习至关重要。然而，目前还没有关于这一核心进程的一般说明。我们认为，考虑到MERs所扮演的上述两个组成角色，对表征能力的理论描述需要一个明确的模型，说明认知系统如何与外部表征相互作用，以及想象力如何在这个过程中发展。在应用层面，需要该账户为学习科学和数学的新媒体干预制定设计指南，特别是基于具体互动的新兴媒体干预。作为开发这样一个理论账户的第一步，我们从两个角度回顾了化学、生物学、物理、数学和工程领域关于MERs学习以及获得RC的文献。首先，我们关注重要的理论账户和相关的实证研究，并考察它们的共同点。其次，我们总结了每个学科的主要趋势，然后将这些趋势汇总在一起。结果表明，RC的大多数模型和实证研究都是在经典信息处理方法的框架内进行的，没有采取外部表征的本构观点。为了发展一种与外部表征的本构观点相兼容的解释，我们概述了RC的基于交互的理论解释，扩展了分布式和具体化认知的最新进展。

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

Studies in Science Education EDUCATION, SCIENTIFIC DISCIPLINES-

CiteScore

15.30

自引率

2.00%

发文量

审稿时长

>12 weeks

期刊介绍： The central aim of Studies in Science Education is to publish review articles of the highest quality which provide analytical syntheses of research into key topics and issues in science education. In addressing this aim, the Editor and Editorial Advisory Board, are guided by a commitment to: maintaining and developing the highest standards of scholarship associated with the journal; publishing articles from as wide a range of authors as possible, in relation both to professional background and country of origin; publishing articles which serve both to consolidate and reflect upon existing fields of study and to promote new areas for research activity. Studies in Science Education will be of interest to all those involved in science education including: science education researchers, doctoral and masters students; science teachers at elementary, high school and university levels; science education policy makers; science education curriculum developers and text book writers. Articles featured in Studies in Science Education have been made available either following invitation from the Editor or through potential contributors offering pieces. Given the substantial nature of the review articles, the Editor is willing to give informal feedback on the suitability of proposals though all contributions, whether invited or not, are subject to full peer review. A limited number of books of special interest and concern to those involved in science education are normally reviewed in each volume.