A Multi-Area Stochastic Model for a Covert Visual Search Task

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2015 Aug 20

PMID 26287613

Citations 4

Authors

Michael A Schwemmer

Samuel F Feng

Philip J Holmes

Jacqueline Gottlieb

Jonathan D Cohen

Affiliations

Soon will be listed here.

Abstract

Decisions typically comprise several elements. For example, attention must be directed towards specific objects, their identities recognized, and a choice made among alternatives. Pairs of competing accumulators and drift-diffusion processes provide good models of evidence integration in two-alternative perceptual choices, but more complex tasks requiring the coordination of attention and decision making involve multistage processing and multiple brain areas. Here we consider a task in which a target is located among distractors and its identity reported by lever release. The data comprise reaction times, accuracies, and single unit recordings from two monkeys' lateral interparietal area (LIP) neurons. LIP firing rates distinguish between targets and distractors, exhibit stimulus set size effects, and show response-hemifield congruence effects. These data motivate our model, which uses coupled sets of leaky competing accumulators to represent processes hypothesized to occur in feature-selective areas and limb motor and pre-motor areas, together with the visual selection process occurring in LIP. Model simulations capture the electrophysiological and behavioral data, and fitted parameters suggest that different connection weights between LIP and the other cortical areas may account for the observed behavioral differences between the animals.

Citing Articles

Salience by competitive and recurrent interactions: Bridging neural spiking and computation in visual attention.

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Selective Influence and Sequential Operations: A Research Strategy for Visual Search.

Lowe K, Reppert T, Schall J Vis cogn. 2020; 27(5-8):387-415.

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Will big data yield new mathematics? An evolving synergy with neuroscience.

Feng S, Holmes P IMA J Appl Math. 2016; 81(3):432-456.

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