Analysis and test of laws for backward (metacontrast) masking

Gregory Francis; Mark Rothmayer; Frouke Hermens

doi:10.1163/1568568041865962

Analysis and test of laws for backward (metacontrast) masking

Gregory Francis, Mark Rothmayer, Frouke Hermens

Psychology

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

11 Citations (Scopus)

Abstract

In backward visual masking, it is common to find that the mask has its biggest effect when it follows the target by several tens of milliseconds. Research in the 1960s and 1970s suggested that masking effects were best characterized by the stimulus onset asynchrony (SOA) between the target and mask. In particular, one claim has been that the SOA for which masking is optimal remains fixed, even as target and mask durations varied. Experimental evidence supported this claim, and it was accepted as an SOA law. However, recent modeling (Francis, 1997) and experimental studies (Macknik and Livingstone, 1998) argued for new ISI (interstimulus interval) and STA (stimulus termination asynchrony) laws, respectively. This paper reports a mathematical analysis and experimental tests of the laws. The mathematical analysis demonstrates unsuspected relationships between the laws. The experiments test the predictions of the SOA, ISI, and STA laws. The data favor the ISI law over the SOA and the STA laws.

Original language	English
Pages (from-to)	163-186
Number of pages	24
Journal	Spatial Vision
Volume	17
Issue number	3
DOIs	https://doi.org/10.1163/1568568041865962
Publication status	Published - 2004

Keywords

cortical dynamics
neural dynamics
visual masking
perception
adaptation
visibility
models
motion

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10.1163/1568568041865962

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title = "Analysis and test of laws for backward (metacontrast) masking",

abstract = "In backward visual masking, it is common to find that the mask has its biggest effect when it follows the target by several tens of milliseconds. Research in the 1960s and 1970s suggested that masking effects were best characterized by the stimulus onset asynchrony (SOA) between the target and mask. In particular, one claim has been that the SOA for which masking is optimal remains fixed, even as target and mask durations varied. Experimental evidence supported this claim, and it was accepted as an SOA law. However, recent modeling (Francis, 1997) and experimental studies (Macknik and Livingstone, 1998) argued for new ISI (interstimulus interval) and STA (stimulus termination asynchrony) laws, respectively. This paper reports a mathematical analysis and experimental tests of the laws. The mathematical analysis demonstrates unsuspected relationships between the laws. The experiments test the predictions of the SOA, ISI, and STA laws. The data favor the ISI law over the SOA and the STA laws. ",

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year = "2004",

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T1 - Analysis and test of laws for backward (metacontrast) masking

AU - Francis, Gregory

AU - Rothmayer, Mark

AU - Hermens, Frouke

PY - 2004

Y1 - 2004

N2 - In backward visual masking, it is common to find that the mask has its biggest effect when it follows the target by several tens of milliseconds. Research in the 1960s and 1970s suggested that masking effects were best characterized by the stimulus onset asynchrony (SOA) between the target and mask. In particular, one claim has been that the SOA for which masking is optimal remains fixed, even as target and mask durations varied. Experimental evidence supported this claim, and it was accepted as an SOA law. However, recent modeling (Francis, 1997) and experimental studies (Macknik and Livingstone, 1998) argued for new ISI (interstimulus interval) and STA (stimulus termination asynchrony) laws, respectively. This paper reports a mathematical analysis and experimental tests of the laws. The mathematical analysis demonstrates unsuspected relationships between the laws. The experiments test the predictions of the SOA, ISI, and STA laws. The data favor the ISI law over the SOA and the STA laws.

AB - In backward visual masking, it is common to find that the mask has its biggest effect when it follows the target by several tens of milliseconds. Research in the 1960s and 1970s suggested that masking effects were best characterized by the stimulus onset asynchrony (SOA) between the target and mask. In particular, one claim has been that the SOA for which masking is optimal remains fixed, even as target and mask durations varied. Experimental evidence supported this claim, and it was accepted as an SOA law. However, recent modeling (Francis, 1997) and experimental studies (Macknik and Livingstone, 1998) argued for new ISI (interstimulus interval) and STA (stimulus termination asynchrony) laws, respectively. This paper reports a mathematical analysis and experimental tests of the laws. The mathematical analysis demonstrates unsuspected relationships between the laws. The experiments test the predictions of the SOA, ISI, and STA laws. The data favor the ISI law over the SOA and the STA laws.

KW - cortical dynamics

KW - neural dynamics

KW - visual masking

KW - perception

KW - adaptation

KW - visibility

KW - models

KW - motion

U2 - 10.1163/1568568041865962

DO - 10.1163/1568568041865962

M3 - Article

SN - 0169-1015

VL - 17

SP - 163

EP - 186

JO - Spatial Vision

JF - Spatial Vision

IS - 3

ER -

Analysis and test of laws for backward (metacontrast) masking

Abstract

Keywords

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