Abstract
In anomalous trichromacy, the color signals available from comparing the activities of the two classes of cone sensitive in the medium and long wavelength parts of the spectrum are much reduced from those available in normal trichromacy, and color discrimination thresholds along the red-green axis are correspondingly elevated. Yet there is evidence that suprathreshold color perception is relatively preserved; this has led to the suggestion that anomalous trichromats post-receptorally amplify their impoverished red-green signals. To test this idea, we measured chromatic discrimination from white and from saturated red and green pedestals. If there is no post-receptoral compensation, the anomalous trichromat’s loss of chromatic contrast will apply equally to the pedestal and to the test color. Coupled with a compressively nonlinear neural representation of saturation, this means that a given pedestal contrast will cause a smaller than normal modulation of discrimination sensitivity. We examined cases where chromatic pedestals impair the color discrimination of normal trichromatic observers. As predicted, anomalous observers experienced less impairment than normal trichromats, though they remained less sensitive than normal trichromats. Although the effectiveness of chromatic pedestals in impairing color discrimination was less for anomalous than for normal trichromats, the chromatic pedestals were more effective for anomalous observers than would be expected if the anomalous post-receptoral visual system were the same as in normal trichromacy; the hypothesis of zero compensation can be rejected. This might suggest that the effective contrast of the pedestal is post-receptorally amplified. But on closer analysis, the results do not support candidate simple models involving post-receptoral compensation either.
Highlights
In normal trichromatic color vision there are three types of cone photoreceptors, distinct in their sensitivities to short (S), medium (M), and long (L) wavelengths of light
The simplest possible scenario that we consider for the relation between normal and anomalous trichromats is that the post-receptoral organization of the visual system of anomalous observers is completely normal, without any neural compensation to remedy the deficit associated with the pigment swap
A pedestal with high chromatic contrast that saturates a color contrast encoding neuron in the normal trichromat may fail to saturate it in the anomalous observer
Summary
In normal trichromatic color vision there are three types of cone photoreceptors, distinct in their sensitivities to short (S), medium (M), and long (L) wavelengths of light. The two cone types that are sensitive to medium and long wavelengths of light are more similar in their spectral sensitivities than are the normal M and L cones. In protanomaly, M’ cones, with a spectral sensitivity close to that of the normal M cones, replace the L cones. For both protanomals and deuteranomals, the greater spectral overlap between the sensitivities of the two cone types sensitive at medium and long wavelengths effectively reduces chromatic contrast in the corresponding region of the visible spectrum. Color discrimination is impaired (e.g. Pokorny et al, 1979; Rodriguez-Carmona and Barbur, 2012)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
