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ekunazanu | 7 months ago
No, cones do not produce a negative response. The graph shows the intensity of the primaries required to recreate the spectral colour at that wavelength. The negative implies that the primary was added to the spectral colour to match it with itself, instead of adding it with the other primaries.
https://en.wikipedia.org/wiki/CIE_1931_color_space#Color_mat...
nomel|7 months ago
Yes, they do, after the photoreceptors. Those CIE colorspace curves aren't biology, and shouldn't be interpreted as such.
LMS colorspace is the (currently understood) biological colorspace [1], and contains inhibitions, from the opponent process [2] found in the meatware [3]:
red-green: L - M
blue-yellow: S - (L + M)
This contains a nice introduction to biological colorspace [4].
[1] https://en.wikipedia.org/wiki/LMS_color_space
[2] https://en.wikipedia.org/wiki/Opponent_process
[3] https://en.wikipedia.org/wiki/Lateral_geniculate_nucleus#Col...
[4] https://color2.psych.upenn.edu/brainard/papers/Stockman_Brai...
ekunazanu|7 months ago
> This contains a nice introduction to biological colorspace
Looks like an interesting read, thanks for sharing!
rf15|7 months ago
not what was claimed at all...
ekunazanu|7 months ago
That's what I gathered from spectral response. Usually spectral response in this context refers to the responsivity of the cones. Even when accounting for 'brain subtracting green from red' (which I assume comes from the opponent process theory) the following graph has nothing to do with it. The captions too read 'Yes, this results in red having negative sensitivity @500 nm', implying the red (L) cones have a negative sensitivity to cyans — which, again, is not really the case.