探索增强型卷积神经网络与 MOOC 中潜在的 STEM 知识概念所推荐的注意机制之间的协同作用

IF 3.8 1区 心理学 Q1 EDUCATION & EDUCATIONAL RESEARCH
Xia Xiaona , Qi Wanxue
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引用次数: 0

摘要

STEM的多课程关联对学习者的学习背景提出了重要挑战。一旦学习者对知识关联理解不够,或者没有落实知识推进的拓扑顺序,就容易在学习过程中产生倦怠情绪,形成严重的负面情绪,不利于学习效果的提高,甚至过早辍学。这显然是一个心理教学问题,也就是我们的研究目标。本研究聚焦MOOCs中的STEM学习行为,探索深度学习路径。我们设计了一种处理上下文特征和内容特征的新方法,用于知识概念推荐。多个实体、特征和课程可以构建和优化知识概念关系。然后,利用注意力机制实现知识概念在不同实体间的传播。大量实验证明,这种方法可以准确捕捉知识概念的潜在兴趣,实现有效的深度学习路由,并探索和引导积极的学习状态,减少或避免辍学或低通过率等负面心理结果。整个研究旨在提高学习效果,改善学习动机,优化学习行为,为 STEM 教育提供更有效的建议,这对高等教育中的跨学科学习非常重要。整个研究可为追踪学习者可能出现的心理变化、改善学习行为趋势、提高 STEM 学习过程中的学习质量、全面改善和优化学习状态、构建积极学习兴趣的有效决策提供关键支持。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Explorar la sinergia entre las redes neuronales de convolución mejoradas y los mecanismos de atención recomendados por posibles conceptos de conocimiento STEM en MOOCs

The multi course association of STEM poses an important challenge to the learning background of learners. Once learners do not have sufficient understanding of knowledge association or do not implement the topological order of knowledge advancement, they are prone to burnout in the learning process, forming serious negative emotions, which is not conducive to learning effectiveness, and even premature dropout. This is clearly a psychological teaching problem, that is our research objectives. This study focuses on the STEM learning behaviors in MOOCs, and explores the deep learning routing. We design one novel method to process the context features and content features for knowledge concept recommendation. Multiple entities, features, and courses enable the construction and optimization of knowledge concept relationships. Then, an attention mechanism is used to achieve the knowledge concept propagation between different entities. The extensive experiments have proved this method might accurately capture potential interests of knowledge concepts, achieve the effective deep learning routing, and explore and guide the positive learning state, reduce or avoid the negative psychological outcomes, such as dropout or low pass rate. The entire study aims to enhance learning outcomes, improve learning motivation, optimize learning behaviors, and provide more effective suggestions for STEM education, that is very important for the interdisciplinary learning in higher education. The whole research might provide key support for tracking possible psychological changes in learners, improving learning behavior trends, and enhance learning quality during STEM learning, fully improve and optimize the learning state, construct effective decisions for positive learning interests.

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来源期刊
CiteScore
6.60
自引率
5.60%
发文量
18
审稿时长
35 days
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