Asymmetric Perceptual Confounds Between Canonical Lightings and Materials

Overview

Journal J Vis

Specialty Ophthalmology

Date 2018 Oct 23

PMID 30347097

Citations 4

Authors

Fan Zhang

Huib de Ridder

Sylvia C Pont

Affiliations

Soon will be listed here.

Abstract

To better understand the interactions between material perception and light perception, we further developed our material probe MatMix 1.0 into MixIM 1.0, which allows optical mixing of canonical lighting modes. We selected three canonical lighting modes (ambient, focus, and brilliance) and created scenes to represent the three illuminations. Together with four canonical material modes (matte, velvety, specular, glittery), this resulted in 12 basis images (the "bird set"). These images were optically mixed in our probing method. Three experiments were conducted with different groups of observers. In Experiment 1, observers were instructed to manipulate MixIM 1.0 and match optically mixed lighting modes while discounting the materials. In Experiment 2, observers were shown a pair of stimuli and instructed to simultaneously judge whether the materials and lightings were the same or different in a four-category discrimination task. In Experiment 3, observers performed both the matching and discrimination tasks in which only the ambient and focus light were implemented. Overall, the matching and discrimination results were comparable as (a) robust asymmetric perceptual confounds were found and confirmed in both types of tasks, (b) performances were consistent and all above chance levels, and (c) observers had higher sensitivities to our canonical materials than to our canonical lightings. The latter result may be explained in terms of a generic insensitivity for naturally occurring variations in light conditions. Our findings suggest that midlevel image features are more robust across different materials than across different lightings and, thus, more diagnostic for materials than for lightings, causing the asymmetric perceptual confounds.

Citing Articles

Color and gloss constancy under diverse lighting environments.

Morimoto T, Akbarinia A, Storrs K, Cheeseman J, Smithson H, Gegenfurtner K J Vis. 2023; 23(7):8.

PMID: 37432844 PMC: 10351023. DOI: 10.1167/jov.23.7.8.

Evaluation of Material Appearance Under Different Spotlight Distributions Compared to Natural Illumination.

Yamazoe T, Funaki T, Kiyasu Y, Mizokami Y J Imaging. 2021; 5(2).

PMID: 34460479 PMC: 8320908. DOI: 10.3390/jimaging5020031.

Perceived roughness of glossy objects: The influence of Fresnel effects and correlated image statistics.

Faul F J Vis. 2021; 21(8):1.

PMID: 34338739 PMC: 8340650. DOI: 10.1167/jov.21.8.1.

Effects of light map orientation and shape on the visual perception of canonical materials.

Zhang F, de Ridder H, Barla P, Pont S J Vis. 2020; 20(4):13.

PMID: 32324842 PMC: 7405718. DOI: 10.1167/jov.20.4.13.

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