The Motion Reverse Correlation (MRC) Method: a Linear Systems Approach in the Motion Domain

Overview

Journal J Neurosci Methods

Specialty Neurology

Date 2003 Feb 28

PMID 12606064

Citations 16

Authors

Bart G Borghuis

Janos A Perge

Ildiko Vajda

Richard J A van Wezel

Wim A van de Grind

Martin J M Lankheet

Affiliations

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Abstract

We introduce the motion reverse correlation method (MRC), a novel stimulus paradigm based on a random sequence of motion impulses. The method is tailored to investigate the spatio-temporal dynamics of motion selectivity in cells responding to moving random dot patterns. Effectiveness of the MRC method is illustrated with results obtained from recordings in both anesthetized cats and an awake, fixating macaque monkey. Motion tuning functions are computed by reverse correlating the response of single cells with a rapid sequence of displacements of a random pixel array (RPA). Significant correlations between the cell's responses and various aspects of stimulus motion are obtained at high temporal resolution. These correlations provide a detailed description of the temporal dynamics of, for example, direction tuning and velocity tuning. In addition, with a spatial array of independently moving RPAs, the MRC method can be used to measure spatial as well as temporal receptive field properties. We demonstrate that MRC serves as a powerful and time-efficient tool for quantifying receptive field properties of motion selective cells that yields temporal information that cannot be derived from existing methods.

Citing Articles

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Intrinsic timescales of sensory integration for motion perception.

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Dynamic population codes of multiplexed stimulus features in primate area MT.

Goddard E, Solomon S, Carlson T J Neurophysiol. 2017; 118(1):203-218.

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Dynamics of contextual modulation of perceived shape in human vision.

Gheorghiu E, Kingdom F Sci Rep. 2017; 7:43274.

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