Congrats, Hagen (or Luke) – your OP has made it to Cecil’s column! See: Is colorblindness an evolutionary advantage? - The Straight Dope
Moving to “Comments on Cecil’s Columns.”
So this is the comment thread now? A nitpick:
Cecil says: “Even today most primates are dichromats. Only a few species including humans are trichromats, with three types of cone, a trait we’re thought to have re-evolved when our ancestors took to foraging in daylight and better color vision improved their ability to find fruit.” (Bolding mine)
Googling around, I figure slightly less than 100 primate species have full color vision (19 apes + ~78 OW monkeys + 1 NW monkey; and minus the few species of OW monkeys who are nocturnal and see in B&W which I don’t have a count for). And that is not including the many polymorphic NW monkey females. “A few” indeed.
Also, not necessarily ignored by Cecil but not mentioned in the research he quoted: something like colorblindness can stay in the gene pool because it is not being actively selected against. So its existence does not imply that it is advantageous, just not a sufficient disadvantage. So a colorblind monkey may not be able to find ripe fruit and be at a disadvantage. Or he can just make another monkey bring him fruit. We accomplish the same thing with the grocery store, and if a pedestrian is faced with a car barreling towards him, a trichromat is unlikely to be any more likely to survive than a dichromat.
Almost all amphibians, reptile, and birds have trichromatic or quad-chromatic vision.
Mammals developed during the Jurassic, Triassic and Cretaceous periods when dinosaurs ruled the earth. Mammals evolved during that period as small nocturnal creatures in order to find ecological niches that were not dominated by dinosaurs. At night long wave light vision (such as red color vision) isn’t very useful, and in evolution, if you don’t use a trait, you lose it. Thus, mammals lost their red color vision and became dichromatic.
It is thought that somewhere after South America and Africa split, an African species of monkey became trichromatic by duplicating the green color vision receptor onto their sex chromosome. This proved such an advantage for monkeys that this species and its offspring were able to completely replace all other African monkeys. Thus, all Old World Monkeys are trichromatic while almost all male New World Monkeys are dichromatic (it seems that many female species of New World Monkeys might be trichromatic). Apes, which evolved from Old World Monkeys are trichromatic.
That third receptor is most sensitive to yellow light, but it can be used to tell the difference between red and green and thus we have trichromatic color vision. However, due to it’s sensitivity we can’t see a lot of infrared colors that many other creatures have no problems with. Some animals have another receptor for ultraviolet light.
In humans, 8% of the male population are colored blind (not a good idea putting a gene for color vision on the sex chromosome), but the population of color blind monkeys and apes is much lower which seems to show that the lack of trichromatic color vision is a big disadvantage in the wild.
Just an anecdote: my grandfather says he was chosen as an aerial spotter for being colorblind during WWII, and claims he was able to ID a few camoflaged installations that others missed.
Also, my father’s green African parrot once escaped, and my gramps was the one who spotted it in a tree.
Damn those little guys are badass! If they ever get zapped by nuclear waste and grow to be more than 12 inches long*, the human race is pretty well screwed.
*Yes, I know all about the cube-square law and so forth and that the world doesn’t really work that way.
It’s good to remind people that evolution is not necessarily about “progress”. But considering the dope is supposed to be about fighting ignorance, I think a lot of people are now going to spread the “fact” that colourblindness is advantageous when really it’s fairly wild speculation.
For starters, while a situation where “colourblinds” best “norms” (for the sake of brevity) is interesting, it wouldn’t be hard to set up an experiment where norms beat colourblinds, so it’s hardly conclusive.
Then the observations about colour vision in nature, if anything refute the hypothesis, IMO.
Most of the animals tested for colour vision, outside of mammals, are at least trichromats; if such vision were a disadvantage it’s had millions of years and millions of niches to get selected out.
And if we’re going to consider mammals more “advanced”, then where would we fit primates and their “re-evolving” a third colour receptor?
Finally the implication that we might lose trichromacy because we don’t need to select ripe fruit is dubious. Sure, we don’t need to pick fruit but what we do need to do is to interact with a largely manmade world. Colour is such a useful way of showing information that much technology makes use of our full gamut of vision, and colourblinds are generally at a disadvantage wherever they are not specifically considered.
(My own view is that it’s pointless extrapolating natural selection in humans; in a century or two GE and cybernetic implants may become commonplace. But that would open a big debate in itself).
My grandfather volunteered for the RAF in WW1 (better than being an infantry subaltern in the trenches), went through flying training, and ended up being selected as an observer rather than a pilot because he was red-green colourblind. This was in 1918, so the idea of being able to see through camouflage was an early one.
This fairly accurately describes me.
Yep
Most of the time it isn’t an issue. However, once in Jr High science class we were doing an experiment to tell what a substance was by burning it and looking at the color, then reading a chart to ID it. Well, my lab partner and I were both colorblind, though his was worse. I did okay on most, he couldn’t see most of them. But there was one that I burned and it didn’t have a color at all, almost didn’t seem to be burning to me. We both looked at each other, shrugged, and tried to ask the table next to us. Um, yeah.
In college I had an experiment looking at a spectrum and to me, what everyone else was calling yellow looked a bit green.
Usually it doesn’t mean anything, but every once in a while I’ll call something black an others will say it is green.
Looking at the images on the wiki page
The flag image, all flags look distinct, with the blue in the top flag just a big lighter than the blue in the III flag.
The protanopia image, I see the 37, though the edges aren’t distinct.
The deuteranopia image I can’t see the number. Even knowing it is 49, if I study hard knowing the number is 49, I can sorta see where there might be faint hints of those numbers, but it really looks like an undistinguished field that I’m projecting onto.
For the tritanopia image, the 56 is visible but faint. More of a suggestion than a distinct number.
The ishihara chart has a number that looks somewhat like it might be 81.The upright of the 4 is fairly distinct, but the inner elbow is missing.
I think, as far as camoflage goes, I agree there are probably two factors. First, the variance in color perceptions means two shades that are supposed to look different look the same, so the image isn’t broken up like for normal vision. And second, colorblind people are conditioned to look for other factors to tell things apart, so edges and motion stand out more. Things like that.
For those of you who are colorblind, (or perhaps only the anomalous trichromats), how do the colors on TV look? Correct? Stupid? Is it different for CRTs versus LCD or plasma? If you’ve seen the Quattron, with four colors of phosphors, is it better, worse, or no difference?
I’m not colorblind, but those flag images always look liked poor representations of the types. Ishihara is good stuff. Irishman have you ever been diagnosed?
Colors on TV always look correct for colorblind people because that’s the only percept that they know.
I wish there was info on how the Quattron worked. It would make answering that question easier.
Not necessarily. TVs use three colors to represent what in reality is a continuum. If the balance is set for normal-sighted people, and colorblind people react to those colors differently, the colors could seem off.
(It’s possible the original colors were chosen way back when to look right for colorblind people as well.)
I’ve never noticed a problem with TV or movie colors. Or internet colors that nobody else complains about. Other than a few limited specific real life situations when specific shades become important, I really don’t notice.
We did the standard charts in Jr High. I don’t recall specifics, just being aware at that time that I could read some of the numbers.
The colors on the TV look just as “correct” as the colors in the real world do to this anomalous trichromat.
As it happens, we recently acquired a Quattron at my house. Yes, it does look better. Do keep in mind, though, the “fourth pixel” color is a yellow, which my eyes respond to the same as a normal trichromat would.
What I find most remarkable about the big TV we now have is not so much the color (although that is totally spectacular) but that I can actually see a difference between high definition and standard broadcasts (often I can’t) and that the 3D system it has actually works with my eyesight - frequently 3D systems do work with me at all. My vision has some issues beyond just slightly off color reception, you see, but really, I’m straying off topic here.
Cecil says:
I was trying to find the source for this research.
The closest I can is Vernon and Straker 1943, which is quoted in this paper:
(2nd page of PDF, shown as page 98)
The data and associated narrative seems to state exactly the opposite as Cecil, that colorblindness is least common in areas of the country where there had been greatest migration.
(Vernon, P. E. and Straker, A. 1943. Distribution of Colour-Blind Men in Great Britain. Nature. 152, 690 - it’s available to download but for a price)