Abstract
AbstractIn recent years, colour vision abilities have been rather generously awarded to vari-ous invertebrates and even bacteria. This uncertainty of when to diagnose colour vi-sion stems in part from confusing what colour vision can do with what it is. What col-our vision can do is discriminate wavelength independent of intensity. However, if we take this as a definition of what colour vision is, then we might indeed be obliged to conclude that some plants and bacteria have colour vision. Moreover, there is a simi-lar confusion of what are necessary and what are sufficient mechanisms and behav-ioural abilities for colour vision. To humans, seeing in colour means seeing an image in which objects/lights have chromatic attributes - in contrast to the sensation that we have when viewing monochrome movies, or our experience in dim light when only rod vision is possible. The necessary basic equipment for this is to have at least two types of photoreceptors that differ in spectral sensitivity, and at least one type of spectrally opponent cell to compare the signals from the photoreceptors. Clearly, however, a necessary additional prerequisite for colour vision is to have vision, which entails the identification of shapes, sizes and locations of objects in the world. Thus if an animal has colour vision, it should see an image in which distinct objects/lights have colour attributes. This distinguishes colour vision from what has historically been called wavelength-specific behaviour: a type of behaviour triggered by fixed configurations of spectral receptor signals; however, we discuss difficulties in diagnosing wavelength specific behaviour as an indicator of the absence of colour vision.
Highlights
NATURE PRECEDINGS|07 April 2008 tween wavelength-discrimination and colour vision in humans
We have re-evaluated the current definition of colour vision for animals, attempting to assemble criteria that are neither too generous, nor too stringent
While wavelength dependent behaviours might require some of the basic mechanistic components of colour vision, they do not require vision, i.e. seeing images
Summary
Colour vision abilities have been rather generously awarded to various invertebrates and even bacteria. There is no doubt that colour vision entails the ability to discriminate the wavelength of light (rather than just its intensity). Patients with cerebral achromatopsia (an acquired loss of colour vision due to damage in certain areas of visual association cortex, without damage to early retino-cortical processing) report complete loss of phenomenal colour experience Such patients can detect borders between fields of illumination adjusted for intensity in such a way that wavelength differences provide the only cue for distinguishing the fields (Heywood et al 1991; Kentridge et al 2004). Some scholars have essentially viewed colour vision as the ability to detect the invariant physical surface properties of light-reflecting objects in the world (Byrne and Hilbert 2003), in which case colour constancy will be an integral and defining feature of colour vision (Land 1986; Thompson 1995; Werner 2006). Some degree of colour constancy is a by-product of basic receptor properties, it is not an essential prerequisite of colour vision, since colour vision continues to function even in the face of failures of colour constancy
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