Exploration of the Dynamics of Neuro-Cognition During TRIZ

Volume 6: 33rd International Conference on Design Theory and Methodology (DTM) Pub Date : 2021-08-17 DOI:10.1115/detc2021-70412

J. Milovanovic, Mo Hu, Tripp Shealy, J. Gero

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引用次数: 1

Abstract

The Theory of Inventive Problem Solving (TRIZ) method and toolkit provides a well-structured approach to support engineering design with pre-defined steps: interpret and define the problem, search for standard engineering parameters, search for inventive principles to adapt, and generate final solutions. The research presented in this paper explores the neuro-cognitive differences of each of these steps. We measured the neuro-cognitive activation in the prefrontal cortex (PFC) of 30 engineering students. Neuro-cognitive activation was recorded while students completed an engineering design task. The results show a varying activation pattern. When interpreting and defining the problem, higher activation is found in the left PFC, generally associated with goal directed planning and making analytical. Neuro-cognitive activation shifts to the right PFC during the search process, a region usually involved in exploring the problem space. During solution generation more activation occurs in the medial PFC, a region generally related to making associations. The findings offer new insights and evidence explaining the dynamic neuro-cognitive activations when using TRIZ in engineering design.

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TRIZ过程中神经认知动力学的探索

创造性问题解决理论(TRIZ)方法和工具包提供了一个结构良好的方法，通过预先定义的步骤来支持工程设计:解释和定义问题，搜索标准工程参数，搜索适应的创造性原则，并生成最终解决方案。本文提出的研究探讨了这些步骤中每个步骤的神经认知差异。我们测量了30名工科学生前额叶皮层(PFC)的神经认知激活。当学生完成一项工程设计任务时，神经认知活动被记录下来。结果显示出不同的激活模式。在解释和定义问题时，左侧PFC的激活程度更高，通常与目标导向的计划和分析有关。在搜索过程中，神经认知活动转移到右侧PFC，这个区域通常与探索问题空间有关。在溶液生成过程中，更多的激活发生在内侧PFC，一个通常与形成联想有关的区域。这些发现为解释在工程设计中使用TRIZ时动态神经认知激活提供了新的见解和证据。

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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Volume 6: 33rd International Conference on Design Theory and Methodology (DTM)

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