Here, we examine the hypothesis that colour constancy mechanisms per se are optimised for natural environments, and in particular, for natural illuminations. Colour constancy – the phenomenon by which object colours are perceived as constant despite changes in the illumination spectrum – is thought to involve mechanisms at the higher cortical level, in addition to retinal and thalamic components –. Although the ecological theory of perception would also suggest that higher cortical mechanisms are sculpted by natural scene statistics through evolutionary pressure, there is less direct evidence for such optimisation, particularly for mechanisms underlying colour perception. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.Ĭompeting interests: The authors have declared that no competing interests exist.Įvidence suggests that the human visual system is optimised for the environment in which it evolved, particularly at retinal and thalamic levels where spatial and spectral sensitivities have been shown to be tuned to natural scene statistics –. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.įunding: This project was part of a larger project funded by the Engineering and Physical Sciences Research Council (EPSRC), grant number: EP/H022236/1. Received: AugAccepted: JanuPublished: February 19, 2014Ĭopyright: © 2014 Pearce et al. PLoS ONE 9(2):Įditor: Daniel Osorio, University of Sussex, United Kingdom We conclude that high-level mechanisms of colour constancy are biased for the blue daylight illuminations and variegated backgrounds to which the human visual system has typically been exposed.Ĭitation: Pearce B, Crichton S, Mackiewicz M, Finlayson GD, Hurlbert A (2014) Chromatic Illumination Discrimination Ability Reveals that Human Colour Constancy Is Optimised for Blue Daylight Illuminations. These results are not explained by statistical properties of the scene signal changes at the retinal level. Illumination discrimination is also enhanced, and therefore colour constancy diminished, for uniform backgrounds, irrespective of the object type. We find that discrimination of illumination changes is poorer along the daylight locus than the atypical locus, and is poorest particularly for bluer illumination changes, demonstrating conversely that surface colour constancy is best for blue daylight illuminations. We use real scenes consisting of solid familiar or unfamiliar objects against uniform or variegated backgrounds and compare discrimination performance for typical illuminations from the daylight chromaticity locus (approximately blue-yellow) and atypical spectra from an orthogonal locus (approximately red-green, at correlated colour temperature 6700 K), all produced in real time by a 10-channel LED illuminator. Here we demonstrate a new method for investigating colour constancy using illumination matching in real scenes which, unlike previous methods using surface matching and simulated scenes, allows testing of multiple, real illuminations. Although colour constancy has evolved under a constrained subset of illuminations, it is unknown whether its underlying mechanisms, thought to involve multiple components from retina to cortex, are optimised for particular environmental variations. The phenomenon of colour constancy in human visual perception keeps surface colours constant, despite changes in their reflected light due to changing illumination.
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