Magnitude of Perceived Change in Natural Images May Be Linearly Proportional to Differences in Neuronal Firing Rates

David J. Tolhurst; Michelle P. S. To; Mazviita Chirimuuta; Tom Troscianko; Pei-Ying Chua; P. George Lovell

doi:10.1163/187847510X532676

Magnitude of Perceived Change in Natural Images May Be Linearly Proportional to Differences in Neuronal Firing Rates

David J. Tolhurst, Michelle P. S. To, Mazviita Chirimuuta, Tom Troscianko, Pei-Ying Chua, P. George Lovell

School of Psychology and Neuroscience

Research output: Contribution to journal › Article › peer-review

Abstract

We are studying how people perceive naturalistic suprathreshold changes in the colour, size, shape or location of items in images of natural scenes, using magnitude estimation ratings to characterise the sizes of the perceived changes in coloured photographs. We have implemented a computational model that tries to explain observers' ratings of these naturalistic differences between image pairs. We model the action-potential firing rates of millions of neurons, having linear and non-linear summation behaviour closely modelled on real VI neurons. The numerical parameters of the model's sigmoidal transducer function are set by optimising the same model to experiments on contrast discrimination (contrast 'dippers') on monochrome photographs of natural scenes. The model, optimised on a stimulus-intensity domain in an experiment reminiscent of the Weber-Fechner relation, then produces tolerable predictions of the ratings for most kinds of naturalistic image change. Importantly, rating rises roughly linearly with the model's numerical output, which represents differences in neuronal firing rate in response to the two images under comparison; this implies that rating is proportional to the neuronal response. (C) Koninklijke Brill NV, Leiden, 2010

Original language	English
Pages (from-to)	349-372
Number of pages	24
Journal	Seeing and Perceiving
Volume	23
Issue number	4
DOIs	https://doi.org/10.1163/187847510X532676
Publication status	Published - 2010

Keywords

Natural images
ratings
VI model
transducer function
RETINAL GANGLION-CELLS
CAT STRIATE CORTEX
SUPRATHRESHOLD CONTRAST PERCEPTION
PRIMARY VISUAL-CORTEX
STIMULUS CONTRAST
CORTICAL-NEURONS
RED-GREEN
DISCRIMINATION
MONKEY
MODEL

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title = "Magnitude of Perceived Change in Natural Images May Be Linearly Proportional to Differences in Neuronal Firing Rates",

abstract = "We are studying how people perceive naturalistic suprathreshold changes in the colour, size, shape or location of items in images of natural scenes, using magnitude estimation ratings to characterise the sizes of the perceived changes in coloured photographs. We have implemented a computational model that tries to explain observers' ratings of these naturalistic differences between image pairs. We model the action-potential firing rates of millions of neurons, having linear and non-linear summation behaviour closely modelled on real VI neurons. The numerical parameters of the model's sigmoidal transducer function are set by optimising the same model to experiments on contrast discrimination (contrast 'dippers') on monochrome photographs of natural scenes. The model, optimised on a stimulus-intensity domain in an experiment reminiscent of the Weber-Fechner relation, then produces tolerable predictions of the ratings for most kinds of naturalistic image change. Importantly, rating rises roughly linearly with the model's numerical output, which represents differences in neuronal firing rate in response to the two images under comparison; this implies that rating is proportional to the neuronal response. (C) Koninklijke Brill NV, Leiden, 2010",

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author = "Tolhurst, {David J.} and To, {Michelle P. S.} and Mazviita Chirimuuta and Tom Troscianko and Pei-Ying Chua and Lovell, {P. George}",

year = "2010",

doi = "10.1163/187847510X532676",

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AU - Tolhurst, David J.

AU - To, Michelle P. S.

AU - Chirimuuta, Mazviita

AU - Troscianko, Tom

AU - Chua, Pei-Ying

AU - Lovell, P. George

PY - 2010

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N2 - We are studying how people perceive naturalistic suprathreshold changes in the colour, size, shape or location of items in images of natural scenes, using magnitude estimation ratings to characterise the sizes of the perceived changes in coloured photographs. We have implemented a computational model that tries to explain observers' ratings of these naturalistic differences between image pairs. We model the action-potential firing rates of millions of neurons, having linear and non-linear summation behaviour closely modelled on real VI neurons. The numerical parameters of the model's sigmoidal transducer function are set by optimising the same model to experiments on contrast discrimination (contrast 'dippers') on monochrome photographs of natural scenes. The model, optimised on a stimulus-intensity domain in an experiment reminiscent of the Weber-Fechner relation, then produces tolerable predictions of the ratings for most kinds of naturalistic image change. Importantly, rating rises roughly linearly with the model's numerical output, which represents differences in neuronal firing rate in response to the two images under comparison; this implies that rating is proportional to the neuronal response. (C) Koninklijke Brill NV, Leiden, 2010

AB - We are studying how people perceive naturalistic suprathreshold changes in the colour, size, shape or location of items in images of natural scenes, using magnitude estimation ratings to characterise the sizes of the perceived changes in coloured photographs. We have implemented a computational model that tries to explain observers' ratings of these naturalistic differences between image pairs. We model the action-potential firing rates of millions of neurons, having linear and non-linear summation behaviour closely modelled on real VI neurons. The numerical parameters of the model's sigmoidal transducer function are set by optimising the same model to experiments on contrast discrimination (contrast 'dippers') on monochrome photographs of natural scenes. The model, optimised on a stimulus-intensity domain in an experiment reminiscent of the Weber-Fechner relation, then produces tolerable predictions of the ratings for most kinds of naturalistic image change. Importantly, rating rises roughly linearly with the model's numerical output, which represents differences in neuronal firing rate in response to the two images under comparison; this implies that rating is proportional to the neuronal response. (C) Koninklijke Brill NV, Leiden, 2010

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KW - ratings

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KW - transducer function

KW - RETINAL GANGLION-CELLS

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KW - SUPRATHRESHOLD CONTRAST PERCEPTION

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KW - STIMULUS CONTRAST

KW - CORTICAL-NEURONS

KW - RED-GREEN

KW - DISCRIMINATION

KW - MONKEY

KW - MODEL

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JO - Seeing and Perceiving

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IS - 4

ER -

Magnitude of Perceived Change in Natural Images May Be Linearly Proportional to Differences in Neuronal Firing Rates

Abstract

Keywords

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