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Self‐Explanations: How Students Study and Use Examples in Learning to Solve Problems
Cognitive Science 13 (2):145-182 (1989)
Abstract
The present paper analyzes the self‐generated explanations (from talk‐aloud protocols) that “Good” and “Poor” students produce while studying worked‐out examples of mechanics problems, and their subsequent reliance on examples during problem solving. We find that “Good” students learn with understanding: They generate many explanations which refine and expand the conditions for the action parts of the example solutions, and relate these actions to principles in the text. These self‐explanations are guided by accurate monitoring of their own understanding and misunderstanding. Such learning results in example‐independent knowledge and in a better understanding of the principles presented in the text. “Poor” students do not generate sufficient self‐explanations, monitor their learning inaccurately, and subsequently rely heavily on examples. We then discuss the role of self‐explanations in facilitating problem solving, as well as the adequacy of current AI models of explanation‐based learning to account for these psychological findings.My notes
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Citations of this work
Evaluating XAI: A comparison of rule-based and example-based explanations.Jasper van der Waa, Elisabeth Nieuwburg, Anita Cremers & Mark Neerincx - 2021 - Artificial Intelligence 291 (C):103404.
The Role of Explanation in Discovery and Generalization: Evidence From Category Learning.Joseph J. Williams & Tania Lombrozo - 2010 - Cognitive Science 34 (5):776-806.
From implicit skills to explicit knowledge: a bottom‐up model of skill learning.Edward Merrillb & Todd Petersonb - 2001 - Cognitive Science 25 (2):203-244.
Active‐Constructive‐Interactive: A Conceptual Framework for Differentiating Learning Activities.Michelene T. H. Chi - 2009 - Topics in Cognitive Science 1 (1):73-105.
Rule acquisition events in the discovery of problem‐solving strategies.Kurt VanLehn - 1991 - Cognitive Science 15 (1):1-47.
References found in this work
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Why a Diagram is (Sometimes) Worth Ten Thousand Words.Jill H. Larkin & Herbert A. Simon - 1987 - Cognitive Science 11 (1):65-100.
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Skill acquisition: Compilation of weak-method problem situations.John R. Anderson - 1987 - Psychological Review 94 (2):192-210.
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