Visible Spectrum: All Colors & Where Is Brown?

In summary, the visible spectrum of light should contain all the colors that we are able to see. However, there may be some wavelength of light that our human eyes do not really perceive because the chemistry in the eye is not able to react to those wavelengths. This means that we see only a portion of the EM spectrum, which could be a limitation on the colors that we can see.
  • #1
daveed
138
0
... is the visible spectrum of light supposed to contain all the colors that we are able to see?
if so, where is brown?
 
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  • #2
Brown is a mix of color.
 
  • #3
daveed said:
... is the visible spectrum of light supposed to contain all the colors that we are able to see?
if so, where is brown?
We humans can only see what we see. As far as we know our human eyes only detect wavelengths between 380 nm and 650 nm or something close to that. We perceive light as continuous bands, but it is quantum level based. There may be some wavelength of light that our human eyes do not really perceive because the chemistry in the eye is not able to react to those wavelengths. So, for all intents and purposes, we see all that is available in the visible range, but there is the chance that we are missing some.
 
  • #4
what_are_electrons said:
We humans can only see what we see. As far as we know our human eyes only detect wavelengths between 380 nm and 650 nm or something close to that. We perceive light as continuous bands, but it is quantum level based. There may be some wavelength of light that our human eyes do not really perceive because the chemistry in the eye is not able to react to those wavelengths. So, for all intents and purposes, we see all that is available in the visible range, but there is the chance that we are missing some.

the visible range is from 400nm to 750nm. And we are missing a lot. The range in wavelength of light is enourmous. The visible spectrum is soo small on the scale. We don't get to see microwaves, radio waves, x-rays, gamma rays. Imagine what the world would look like if we could getect all of these. :biggrin:
 
  • #5
Yea, the visible part of the spectrum has the least range out of all of them.
 
  • #6
The VISIBLE SPECTRUM is defined as the light to which our eyes are sensitive. So by definition we can see all of the VISIBLE SPECTRUM. The entire EM spectrum is huge, the Visible spectrum is a insignificantly small band.
 
  • #7
...What WOULD the world look like if we could see down to 200 nm and upto 900 nm? Or more!

Could some one ...photoshop an image of what it would roughly look like. I'm guessing no.
 
  • #8
Gara said:
...What WOULD the world look like if we could see down to 200 nm and upto 900 nm? Or more!

Could some one ...photoshop an image of what it would roughly look like. I'm guessing no.

Well what colours would you assign to the low and high wavelengths? You can't just create a totally new colour.
 
  • #9
Gara said:
...What WOULD the world look like if we could see down to 200 nm and upto 900 nm? Or more!

Could some one ...photoshop an image of what it would roughly look like. I'm guessing no.

Humans basically have three color receptors, each of which is based on a dye which absorbs different frequencies of light.

It would be possible to imagine a being with three receptors "tuned differently" to cover a wider bandwidth. The details of what would be seen would depend on the new tuning of the receptors. A reasonable mapping could be done from what such a being would see into human color-space, if one definied the specific behavior of the beings receptors (there are many possibilities).

If the hypothetical had more than three receptors, any analogy would fail. Their color space would have a different number of dimensions than ours.

The visual percepton of color in humans is usually portrayed by a "chromaticity diagram", such as that shown at
http://www.cs.rit.edu/~ncs/color/t_chroma.html

The main feature of the diagram is that any two colors on it add - if you select 2 points on the diagram, a color made by mixing them together lies on the line joining the two points.

The diagram supresses one dimension (intensity) from the full 3-d color space.

Note that the fully saturated colors (monochromatic light, like the colors in the rainbow) are on the outside of the diagram, while white light is on the inside, near the center.
 
  • #10
Humans' perception of colour relies upon the three types of cones (or is it rods?), which have peak sensitivity in blue, green, and red bands respectively. In principle, you could wire up the nerves at the end of the rods to devices which detected any selection of three regions of the EM that you choose - you would then perceive the field of view of those devices in terms of BGR. You can achieve similar effects by using photoshop, converting (say) X-ray region1 to 'red', UV region2 to 'green', and radio region3 to 'blue'; indeed, many of the astronomical images you see (from, say, the HST, Chandra, XMM-Newton, Spitzer, even radio telescopes) use this principle.

Different question: can your mind 'perceive' 'new colours' (other than combinations of BGR)? A: some lucky (or not) individuals actually posses this ability :surprise:

1) synesthesics, whose brain wiring is 'interesting'; they can feel colours, and see smells (for example)
2) some women (but no men): there are actually two types of red cones, each with slightly different wavelength sensitivity; the genes for cones are on the X chromosome, so a woman with one type of red cone gene on one X and the other on the other X can have retinas with each type sprinkled randomly (I've also read that there may be two green cones as well). A woman with this rich retina will 'see' colour more richly than a man (or woman without); unfortunately, she will have no way to convey to the unfortunate just what that richer sensation is actually like :eek:
 
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  • #11
I have often imagined that we could "see" RF frequencys, so every radio transmitter would be glowing a different color.
 
  • #12
ArmoSkater87 said:
Brown is a mix of color.

Brown is a mixture of Orange and Green.

Cones are for color (Red Cone, Green Cone, & Blue Cone) and Rods are for Black & White. There are more Rods than there are Cones for each color. That's why we see the stars at night in black and white. If we had enough cones, we could tell what color the stars are.
 
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  • #13
Snakes in the pit viper family have small holes in their heads that sense IR radiation and likely assemble the image to look much like images they can see with their eyes. Other animals have similar senses that allow them to "see" more of the EM spectrum than we do.
 
  • #14
daveed said:
... is the visible spectrum of light supposed to contain all the colors that we are able to see?
if so, where is brown?

A color in the spectrum is specified by the wavelength, and so this is a one-dimensional quantity.

The space of all possible colors would allow us to specify an intensity for each spectral color and so would be infinite dimensional.

The colors we see are determined by the three different receptor types in our eyes and so this is a 3 -dimensional space. This can be specified as RGB or as hue (i.e. the pure, spectral color), saturation and luminosity (bring up a color dialog box on your computer to see this). Brown is then a dark orange-red color.
 
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  • #15
Nenad said:
Imagine what the world would look like if we could getect all of these. :biggrin:
The stoners favorite kitchen appliance would be the microwave as opposed the fridge.
 
  • #16
I think if we saw IR as red, and UV as blue, we would start to confuse IR/UV stuff with red/blue stuff.

Whoa, nice lamb there mate, UV.

"No... it's blue."

If you edited your eyes somehow, (surgery, genes, whatever) up to 900 nm or above, could you see in the dark via thermal vision?

*grabs a patent and rings up the military*
 
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  • #17
Gara said:
If you edited your eyes somehow, (surgery, genes, whatever) up to 900 nm or above, could you see in the dark via thermal vision?

*grabs a patent and rings up the military*

Thermal imaging has been around for some time now. The police used to use it in helicopters to look into peoples houses. The supreme court ruled a few years ago that they need a warrant to image a private residence. Their reasoning was that behind closed doors a person has their right to privacy, and looking through their walls at them when they think they are unobservable is a violation of that privacy. Anything you do in front of an open window or door however is not protected by the right to privacy as people can naturally "see" what you are doing.
 
  • #18
If the big bad wolf could see radio waves it would explain why little red riding hood said 'what big eyes you have, grandma'. I vote for yellow plus violet = brown. I could only afford the 12 crayon box when I started school.
 

1. What is the visible spectrum?

The visible spectrum is the range of electromagnetic radiation that our eyes are able to detect. It includes all the colors of the rainbow, from red to violet.

2. How many colors are in the visible spectrum?

There are seven colors in the visible spectrum: red, orange, yellow, green, blue, indigo, and violet. However, there are many shades and variations within each of these colors.

3. What causes the colors in the visible spectrum?

The colors in the visible spectrum are caused by the different wavelengths of light. Each color corresponds to a specific wavelength, with red having the longest wavelength and violet having the shortest.

4. Where does brown fit into the visible spectrum?

Brown is not considered a color in the visible spectrum. It is a combination of different wavelengths of light, and is often seen as a mixture of red, orange, yellow, and/or green.

5. Can we see colors outside of the visible spectrum?

Yes, there are colors outside of the visible spectrum that we cannot see with our eyes. These include infrared and ultraviolet light, which have longer and shorter wavelengths than the colors in the visible spectrum.

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