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Stochastic sampling provides a unifying account of visual working memory limits

Sebastian Schneegans, Robert Taylor, Paul M. Bays

2020Proceedings of the National Academy of Sciences94 citationsDOIOpen Access PDF

Abstract

Research into human working memory limits has been shaped by the competition between different formal models, with a central point of contention being whether internal representations are continuous or discrete. Here we describe a sampling approach derived from principles of neural coding as a framework to understand working memory limits. Reconceptualizing existing models in these terms reveals strong commonalities between seemingly opposing accounts, but also allows us to identify specific points of difference. We show that the discrete versus continuous nature of sampling is not critical to model fits, but that, instead, random variability in sample counts is the key to reproducing human performance in both single- and whole-report tasks. A probabilistic limit on the number of items successfully retrieved is an emergent property of stochastic sampling, requiring no explicit mechanism to enforce it. These findings resolve discrepancies between previous accounts and establish a unified computational framework for working memory that is compatible with neural principles.

Topics & Concepts

Computer scienceProbabilistic logicLimit (mathematics)Working memorySampling (signal processing)Coding (social sciences)Point processTheoretical computer scienceProperty (philosophy)Artificial intelligenceMathematicsPsychologyStatisticsCognitionNeuroscienceMathematical analysisFilter (signal processing)Computer visionEpistemologyPhilosophyNeural and Behavioral Psychology StudiesNeural dynamics and brain functionVisual perception and processing mechanisms
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