Using diverging predictions from classical and quantum models to dissociate between categorization systems

IF 2.2 4区心理学 Q2 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS

Journal of Mathematical Psychology Pub Date : 2023-02-01 DOI:10.1016/j.jmp.2022.102738

Gunnar P. Epping, Jerome R. Busemeyer

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引用次数: 0

Abstract

Quantum probability theory has successfully provided accurate descriptions of behavior in the areas of judgment and decision making, and here we apply the same principles to two category learning tasks, one task using information-integration categories and the other using rule-based categories. Since information-integration categories lack verbalizable descriptions, unlike rule-based ones, we assert that an information-integration categorization decision results from an intuitive probabilistic reasoning system characterized by quantum probability theory, whereas a rule-based categorization decision results from a logical, rational probabilistic reasoning system characterized classical probability theory. In our experiment, participants learn to categorize simple, visual stimuli as members of either category S or category K during an acquisition phase, and then rate the likelihood on a scale of 0 to 5 that a stimulus belongs to one category and subsequently perform the same likelihood rating for the other category during a transfer phase. Following the principle of complementarity in quantum theory, we expect the category likelihood ratings to exhibit order effects in the information-integration task, but not in the rule-based task. In the information-integration task, we found definitive order effects in the likelihood ratings. But, in the rule-based task, we found that the order effects in the likelihood ratings are not significant.

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利用经典和量子模型的不同预测来分离分类系统

量子概率论已经成功地为判断和决策领域的行为提供了准确的描述，在这里，我们将相同的原理应用于两个类别学习任务，一个任务使用信息集成类别，另一个使用基于规则的类别。与基于规则的类别不同，信息集成类别缺乏可语言描述，因此我们认为信息集成类别决策来自以量子概率论为特征的直觉概率推理系统，而基于规则的类别决策来自以经典概率论为特征的逻辑、理性概率推理系统。在我们的实验中，参与者在获取阶段学习将简单的视觉刺激分类为S类或K类，然后在0到5的范围内评估刺激属于一个类别的可能性，随后在转移阶段对另一个类别进行相同的可能性评级。根据量子理论中的互补原理，我们期望类别似然评级在信息整合任务中表现出顺序效应，而在基于规则的任务中则不表现出顺序效应。在信息整合任务中，我们在可能性评级中发现了明确的顺序效应。但是，在基于规则的任务中，我们发现排序对可能性评级的影响并不显著。

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

Journal of Mathematical Psychology 医学-数学跨学科应用

CiteScore

3.70

自引率

11.10%

发文量

审稿时长

20.2 weeks

期刊介绍： The Journal of Mathematical Psychology includes articles, monographs and reviews, notes and commentaries, and book reviews in all areas of mathematical psychology. Empirical and theoretical contributions are equally welcome. Areas of special interest include, but are not limited to, fundamental measurement and psychological process models, such as those based upon neural network or information processing concepts. A partial listing of substantive areas covered include sensation and perception, psychophysics, learning and memory, problem solving, judgment and decision-making, and motivation. The Journal of Mathematical Psychology is affiliated with the Society for Mathematical Psychology. Research Areas include: • Models for sensation and perception, learning, memory and thinking • Fundamental measurement and scaling • Decision making • Neural modeling and networks • Psychophysics and signal detection • Neuropsychological theories • Psycholinguistics • Motivational dynamics • Animal behavior • Psychometric theory