Inferred representations behave like oscillators in dynamic Bayesian models of beat perception

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Jonathan Cannon , Thomas Kaplan
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引用次数: 0

Abstract

The human’s capacity to perceptually entrain to an auditory rhythm has been repeatedly modeled as a dynamical system consisting of one or more forced oscillators. However, a more recent perspective, closely related to the popular theory of Predictive Processing, treats auditory entrainment as an inference process in which the observer infers the phase, tempo, and/or metrical structure of an auditory stimulus based on event timing. Here, we propose a close relationship between these two perspectives. We show for the first time that a system performing variational Bayesian inference about the circular phase underlying a rhythmic stimulus takes the form of a forced, damped oscillator with a specific nonlinear phase response function corresponding to the internal metrical model of the underlying rhythm. This algorithm can be extended to simultaneous inference on both phase and tempo using one of two possible approximations that closely align with the two most prominent models of auditory entrainment: one yields a single oscillator with an adapting period, and the other yields a networked bank of oscillators. We conclude that an inference perspective on rhythm perception can offer similar descriptive power and flexibility to a dynamical systems perspective while also plugging into the fertile unifying framework of Bayesian Predictive Processing.

节拍感知动态贝叶斯模型中的推断表征表现得像振荡器
人类感知听觉节奏的能力被反复模拟为一个由一个或多个强制振荡器组成的动态系统。然而,与预测处理(Predictive Processing)这一流行理论密切相关的一种最新观点,则将听觉随动视为一种推理过程,在这一过程中,观察者根据事件发生的时间推断出听觉刺激的相位、节奏和/或韵律结构。在此,我们提出了这两种观点之间的密切关系。我们首次证明,对节奏刺激的圆周相位进行变异贝叶斯推理的系统,其形式是一个受迫阻尼振荡器,其特定的非线性相位响应函数与基本节奏的内部韵律模型相对应。这种算法可以扩展到同时推断相位和节奏,使用两种可能的近似方法之一,这两种近似方法与最著名的两种听觉诱导模型密切相关:一种方法产生一个具有适应周期的单振荡器,另一种方法产生一个网络化的振荡器组。我们的结论是,节奏感知的推理视角可以提供与动力系统视角类似的描述能力和灵活性,同时还能与贝叶斯预测处理的肥沃统一框架相结合。
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
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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