Enabling identification of component processes in perceptual learning with nonparametric hierarchical Bayesian modeling.

IF 2 4区 心理学 Q2 OPHTHALMOLOGY
Yukai Zhao, Jiajuan Liu, Barbara Anne Dosher, Zhong-Lin Lu
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引用次数: 0

Abstract

Perceptual learning is a multifaceted process, encompassing general learning, between-session forgetting or consolidation, and within-session fast relearning and deterioration. The learning curve constructed from threshold estimates in blocks or sessions, based on tens or hundreds of trials, may obscure component processes; high temporal resolution is necessary. We developed two nonparametric inference procedures: a Bayesian inference procedure (BIP) to estimate the posterior distribution of contrast threshold in each learning block for each learner independently and a hierarchical Bayesian model (HBM) that computes the joint posterior distribution of contrast threshold across all learning blocks at the population, subject, and test levels via the covariance of contrast thresholds across blocks. We applied the procedures to the data from two studies that investigated the interaction between feedback and training accuracy in Gabor orientation identification over 1920 trials across six sessions and estimated learning curve with block sizes L = 10, 20, 40, 80, 160, and 320 trials. The HBM generated significantly better fits to the data, smaller standard deviations, and more precise estimates, compared to the BIP across all block sizes. In addition, the HBM generated unbiased estimates, whereas the BIP only generated unbiased estimates with large block sizes but exhibited increased bias with small block sizes. With L = 10, 20, and 40, we were able to consistently identify general learning, between-session forgetting, and rapid relearning and adaptation within sessions. The nonparametric HBM provides a general framework for fine-grained assessment of the learning curve and enables identification of component processes in perceptual learning.

利用非参数分层贝叶斯建模识别知觉学习的组成过程。
知觉学习是一个多方面的过程,包括一般学习、会话间遗忘或巩固以及会话内快速再学习和退化。基于数十次或数百次试验的区块或片段阈值估计值构建的学习曲线可能会掩盖其组成部分过程;因此需要较高的时间分辨率。我们开发了两种非参数推断程序:一种是贝叶斯推断程序(BIP),用于独立估计每个学习者在每个学习区块中对比度阈值的后验分布;另一种是分层贝叶斯模型(HBM),通过各区块对比度阈值的协方差,在群体、受试者和测试水平上计算所有学习区块中对比度阈值的联合后验分布。我们将该程序应用于两项研究的数据中,这两项研究调查了 Gabor 方向识别中反馈与训练准确性之间的交互作用,共进行了 6 次 1920 次试验,并估算了学习曲线,块大小 L = 10、20、40、80、160 和 320 次试验。与所有块大小的 BIP 相比,HBM 生成的数据拟合度更高,标准偏差更小,估计值更精确。此外,HBM 得出的估计值没有偏差,而 BIP 只在大的区块大小下得出无偏差的估计值,但在小的区块大小下表现出更大的偏差。在 L = 10、20 和 40 的情况下,我们能够持续识别一般学习、会话间遗忘以及会话内的快速再学习和适应。非参数 HBM 为学习曲线的精细评估提供了一个通用框架,并能识别知觉学习的组成过程。
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来源期刊
Journal of Vision
Journal of Vision 医学-眼科学
CiteScore
2.90
自引率
5.60%
发文量
218
审稿时长
3-6 weeks
期刊介绍: Exploring all aspects of biological visual function, including spatial vision, perception, low vision, color vision and more, spanning the fields of neuroscience, psychology and psychophysics.
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