工作记忆更新中的相互干扰:一个层次贝叶斯模型

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Yiyang Chen , Mario Peruggia , Trisha Van Zandt
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引用次数: 1

摘要

我们提出了一个工作记忆更新的层次贝叶斯模型。该模型同时考虑了记忆更新范式中的反应时间(RT)和回答的准确性,后者是测量工作记忆容量的常用范式。我们采用了Oberauer和Kliegl(2006)的相互干扰模型来解释反应。Oberauer和Kliegl(2006)使用基于工作记忆中存储的项目激活水平的玻尔兹曼方程框架来量化记忆更新后在最后回忆步骤中正确反应的概率。我们用马尔可夫链结构扩展原来的框架,使模型考虑了在记忆更新的中间步骤和记忆更新后的最后回忆步骤中所有可能的反应的概率,正确或错误。我们使用Wald扩散过程来表征RT,其中漂移率参数与工作记忆中项目的激活水平相关。该模型允许我们在一个联合的理论框架下研究记忆更新范式中选择和RTs的潜在机制。仿真研究表明了该模型的有效性,后验预测分布和样本外验证表明该模型能很好地解释经验工作记忆更新结果。我们将该模型应用于两个已发布的数据集。第一组数据来自Oberauer和Kliegl(2001),研究了工作记忆的年龄差异。我们的模型结果显示,与年轻人相比,老年人的相互干扰水平增加,记忆痕迹信息的使用减少,记忆项目的预激活可能减少。第二组数据来自De Simoni和von Bastian(2018),研究了工作记忆训练的迁移效应。我们的模型结果揭示了信息积累速度的潜在转移效应,即在一个工作记忆任务中进行训练可能会提高另一个工作记忆任务的信息处理速度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Mutual interference in working memory updating: A hierarchical Bayesian model

We propose a hierarchical Bayesian model for working memory updating. This model accounts for both the accuracy of the responses and the reaction times (RT) in the memory updating paradigm, which is a commonly used paradigm to measure working memory capacity. We adapt a mutual interference model from Oberauer and Kliegl (2006) to explain responses. Oberauer and Kliegl (2006) used a Boltzmann equation framework based on the activation levels of items stored in working memory to quantify the probability of correct response at the final recall step after memory updating. We expand the original framework with a Markov chain structure, so that the model accounts for the probabilities of all possible responses, correct or incorrect, at both the intermediate steps during memory updating and the final recall step after memory updating. We use a Wald diffusion process to characterize RT, where the drift rate parameters are associated with the activation levels of items in working memory. This model allows us to investigate the mechanisms underlying choices and RTs in the memory updating paradigm under a joint theoretical framework. A simulation study shows the effectiveness of this model, and posterior predictive distributions and out-of-sample validations show that this model gives a good account of empirical working memory updating findings. We apply the model to two published data sets. The first data set, from Oberauer and Kliegl (2001), examined age differences in working memory. Results from our model reveal an increased level of mutual interference, less use of memory trace information, and potentially less pre-activation of memorized items in older adults compared to younger adults. The second data set, from De Simoni and von Bastian (2018), investigated transfer effects of working memory training. Results from our model reveal a potential transfer effect in the speed of information accumulation, where training in one working memory task may improve the information processing speed in another.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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