Using the Past to Estimate Sensory Uncertainty

Overview

Journal Elife

Specialty Biology

Date 2020 Dec 15

PMID 33319749

Citations 9

Authors

Ulrik Beierholm

Tim Rohe

Ambra Ferrari

Oliver Stegle

Uta Noppeney

Affiliations

Soon will be listed here.

Abstract

To form a more reliable percept of the environment, the brain needs to estimate its own sensory uncertainty. Current theories of perceptual inference assume that the brain computes sensory uncertainty instantaneously and independently for each stimulus. We evaluated this assumption in four psychophysical experiments, in which human observers localized auditory signals that were presented synchronously with spatially disparate visual signals. Critically, the visual noise changed dynamically over time continuously or with intermittent jumps. Our results show that observers integrate audiovisual inputs weighted by sensory uncertainty estimates that combine information from past and current signals consistent with an optimal Bayesian learner that can be approximated by exponential discounting. Our results challenge leading models of perceptual inference where sensory uncertainty estimates depend only on the current stimulus. They demonstrate that the brain capitalizes on the temporal dynamics of the external world and estimates sensory uncertainty by combining past experiences with new incoming sensory signals.

Citing Articles

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Cumulative multisensory discrepancies shape the ventriloquism aftereffect but not the ventriloquism bias.

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