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元记忆的贝叶斯推理模型。

A Bayesian inference model for metamemory.

机构信息

Collaborative Innovation Center of Assessment Toward Basic Education Quality, Beijing Normal University.

Institute of Developmental Psychology, Beijing Normal University.

出版信息

Psychol Rev. 2021 Oct;128(5):824-855. doi: 10.1037/rev0000270. Epub 2021 May 27.

DOI:10.1037/rev0000270
PMID:34043396
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9006386/
Abstract

The dual-basis theory of metamemory suggests that people evaluate their memory performance based on both processing experience during the memory process and their prior beliefs about overall memory ability. However, few studies have proposed a formal computational model to quantitatively characterize how processing experience and prior beliefs are integrated during metamemory monitoring. Here, we introduce a Bayesian inference model for metamemory (BIM) which provides a theoretical and computational framework for the metamemory monitoring process. BIM assumes that when people evaluate their memory performance, they integrate processing experience and prior beliefs via Bayesian inference. We show that BIM can be fitted to recall or recognition tasks with confidence ratings on either a continuous or discrete scale. Results from data simulation indicate that BIM can successfully recover a majority of generative parameter values, and demonstrate a systematic relationship between parameters in BIM and previous computational models of metacognition such as the stochastic detection and retrieval model (SDRM) and the meta-d' model. We also show examples of fitting BIM to empirical data sets from several experiments, which suggest that the predictions of BIM are consistent with previous studies on metamemory. In addition, when compared with SDRM, BIM could more parsimoniously account for the data of judgments of learning (JOLs) and memory performance from recall tasks. Finally, we discuss an extension of BIM which accounts for belief updating, and conclude with a discussion of how BIM may benefit metamemory research. (PsycInfo Database Record (c) 2021 APA, all rights reserved).

摘要

双重基础的记忆监控理论认为,人们会根据记忆过程中的加工体验以及他们对整体记忆能力的先前信念来评估自己的记忆表现。然而,很少有研究提出正式的计算模型来定量刻画在元记忆监控过程中如何整合加工体验和先前信念。在这里,我们引入了一种用于元记忆的贝叶斯推断模型(BIM),为元记忆监控过程提供了理论和计算框架。BIM 假设,当人们评估自己的记忆表现时,他们会通过贝叶斯推断来整合加工体验和先前信念。我们表明,BIM 可以拟合回忆或识别任务,并对连续或离散尺度的信心评分进行拟合。数据模拟的结果表明,BIM 可以成功地恢复大多数生成参数值,并展示了 BIM 中的参数与先前元认知计算模型(如随机检测和检索模型(SDRM)和元 d'模型)之间的系统关系。我们还展示了将 BIM 拟合到来自几个实验的几个经验数据集的示例,这表明 BIM 的预测与先前关于元记忆的研究一致。此外,与 SDRM 相比,BIM 可以更简洁地解释来自回忆任务的学习判断(JOL)和记忆表现的数据。最后,我们讨论了 BIM 的扩展,该扩展考虑了信念更新,并讨论了 BIM 如何有益于元记忆研究。(PsycInfo 数据库记录(c)2021 APA,保留所有权利)。

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