Bloch's law and the dynamics of feature fusion

Frank Scharnowski; Frouke Hermens; Michael H Herzog

doi:10.1016/j.visres.2007.05.004

Bloch's law and the dynamics of feature fusion

Frank Scharnowski, Frouke Hermens, Michael H Herzog

Psychology

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

30 Citations (Scopus)

Abstract

How the visual brain integrates temporally dispersed information is an open question. Often, it is assumed that the visual system simply sums light over a certain period of time (e.g. Bloch’s law). However, in feature fusion, information presented later dominates, suggesting complex temporal dynamics that cannot be described by simple energy summation. For example, if two verniers are presented in rapid succession at the same location, they are not perceived individually but they fuse to one single vernier. The perceived offset of the fused vernier is a combination of the offsets of the two presented verniers, with the later one dominating. Here, we show that indeed, Bloch’s law does not hold across verniers in a sequence. However, changes in the luminance of a single vernier can be compensated for by changes in its duration in accordance with Bloch’s law. We present a simple model to demonstrate that these findings can be explained by decaying neural activation.

Original language	English
Pages (from-to)	2444-2452
Number of pages	9
Journal	Vision Research
Volume	47
Issue number	18
DOIs	https://doi.org/10.1016/j.visres.2007.05.004
Publication status	Published - Aug 2007

Keywords

feature integration
temporal dynamics
Bloch's law
temporal resolution

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10.1016/j.visres.2007.05.004

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title = "Bloch's law and the dynamics of feature fusion",

abstract = "How the visual brain integrates temporally dispersed information is an open question. Often, it is assumed that the visual system simply sums light over a certain period of time (e.g. Bloch{\textquoteright}s law). However, in feature fusion, information presented later dominates, suggesting complex temporal dynamics that cannot be described by simple energy summation. For example, if two verniers are presented in rapid succession at the same location, they are not perceived individually but they fuse to one single vernier. The perceived offset of the fused vernier is a combination of the offsets of the two presented verniers, with the later one dominating. Here, we show that indeed, Bloch{\textquoteright}s law does not hold across verniers in a sequence. However, changes in the luminance of a single vernier can be compensated for by changes in its duration in accordance with Bloch{\textquoteright}s law. We present a simple model to demonstrate that these findings can be explained by decaying neural activation.",

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AU - Scharnowski, Frank

AU - Hermens, Frouke

AU - Herzog, Michael H

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AB - How the visual brain integrates temporally dispersed information is an open question. Often, it is assumed that the visual system simply sums light over a certain period of time (e.g. Bloch’s law). However, in feature fusion, information presented later dominates, suggesting complex temporal dynamics that cannot be described by simple energy summation. For example, if two verniers are presented in rapid succession at the same location, they are not perceived individually but they fuse to one single vernier. The perceived offset of the fused vernier is a combination of the offsets of the two presented verniers, with the later one dominating. Here, we show that indeed, Bloch’s law does not hold across verniers in a sequence. However, changes in the luminance of a single vernier can be compensated for by changes in its duration in accordance with Bloch’s law. We present a simple model to demonstrate that these findings can be explained by decaying neural activation.

KW - feature integration

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KW - temporal resolution

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Bloch's law and the dynamics of feature fusion

Abstract

Keywords

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