Thanks! Too human centric for my taste, but pretty good!
If you have time, could you try explaining it as if we were talking to an alien, but only through a one-dimensional signal (like ones and zeroes only = cannot explain direction)?
To answer you actual question since my other response completely missed your point, I don’t know if it’s actually possible to properly describe light and color as a one dimensional signal.
I think we need at least two dimensions to describe it properly. Frequency and amplitude. Amplitude is needed to describe how intense/bright the light is and frequency describes what color the light is. Technically there is also polarization which could be thought of as another necessary dimension.
We could likely simplify it just down to the frequency and consider amplitude and polarization to be constants.
But since color is a really a property of the specific kind eye we talk about, and not universal truth, we get kind of stuck on how we could explain it to aliens which possibly have very different eyes or don’t even have eyes at all.
We have to accept that colour is a pretty subjective thing and not a universal truth.
The idea of frequency (vibration) itself though is very likely a universal concept that would be well understood by any human like intelligence in the universe. So we have something to work with.
We can maybe explain how OUR eyes work pretty well just by using frequency alone (just one dimension).
To explain this to an alien with no eyes, the best analogy would be one based on a sense they might have, such as hearing. We could describe the different colors as different pitches of a sound. Just as our ears perceive a low-frequency sound as a low pitch (like a bass drum) and a high-frequency sound as a high pitch (like a piccolo), the different frequencies of light waves correspond to different colors.
Red light has the lowest frequency of the three. Its frequency is approximately in the range of 400 to 484 THz. This corresponds to a wavelength range of about 620 to 750 nanometers (nm).
Green light falls in the middle of the visible spectrum, between red and blue. Its frequency is approximately in the range of 530 to 600 THz. This corresponds to a wavelength range of about 500 to 565 nm.
Blue light has a higher frequency and shorter wavelength than both red and green. Its frequency is approximately in the range of 620 to 670 THz. This corresponds to a wavelength range of about 450 to 485 nm.
We could put this in a neat one dimensional table:
400 - 484 THz,
530 - 600 THz,
620 - 670 THz,
We could of course encode this data into binary (ones and zeros).
What it really all comes down to is that the universe is full of things vibrating (slight over simplification, photons oscillate not vibrate) at different frequencies and amplitudes. We have organs that turn vibrating air molecules into sound and we have organs that turn vibrating photons into vision.
Living things often develop organs that let them turn these abstract vibrations into useful inputs that their brains can do stuff with. Things like color and sound are really more a property of biology than physics/math. So explaining them in terms of pure physics/math is pretty challenging.
Hope that was a kind of interesting answer at least.
Note: Im tired and misread your question as something like “how can non-human creatures/aliens tell the difference between colours?”. I wrote too much now to delete this haha.
That gets super weird because a “color” is a pretty subjective concept. It’s really just photons (light) vibrating at certain frequencies. We developed special organs for detecting certain frequencies (eyes) when we were still fish-like things living underwater. Because of that we can mostly see colors that propagate through water fairly well. There are whole classes of color we know exist but can’t see (ultraviolet and infrared).
It gets even weirder because some HUMANS seem to not even see colors the way western people do. The Himba language has a single word, “buru,” that covers what Western cultures consider both green and blue. This makes it more difficult for them to quickly differentiate between a blue square and a group of green squares in a visual test. The Himba language has many words for different shades of green that Western languages do not, which allows them to easily distinguish between subtle variations of green that are very difficult for English speakers to see. So colors are also a cultural/linguistics thing that extends beyond pure science.
To start breaking away from human centric stuff and get into aliens, we should look at other animals which evolved eyes separately from humans. Eyes actually evolved several times in completely separate animal lineages (convergent evolution). But the cool thing is that some animals who also have eyes, see colors in fundamentally different ways because they have different cones and brains.
The eyes of mantis shrimp and birds for example evolved completely separately from the eyes of humans and for different reasons. We don’t share a common ancestor which has eyes.
Birds and some insects are often tetrachromats, possessing four types of cones. They can see colors in the ultraviolet spectrum, which is invisible to humans. This allows them to see patterns on flowers and other organisms that are used for navigation or to attract mates.
Mantis shrimp have the most complex color vision known, with up to 12 types of photoreceptors. Scientists are still trying to understand exactly how their brain processes this information.
Many animals have light-sensitive organs that are not even considered eyes. This is known as extraocular photoreception, and it serves a variety of purposes beyond image formation.
Octopuses and Cuttlefish have an ability to change the color and texture of their skin for camouflage. It turns out that their skin contains the same light-sensitive proteins (opsins) found in their eyes. This “dermal light sense” allows their skin to respond directly to light, helping them to match their surroundings without the need for input from their brain.
Flatworms have eyes that are sensitive to light and dark, but they also have other light-sensitive cells scattered across their bodies. These cells help them to sense light well enough to get around but not much more.
So light doesn’t even neasesarily need to be a “visual” thing at all. It really just comes down to having some sensory organ that can detect photons.
Carl Sagan, and E. E. Salpeter, proposed a hypothetical ecosystem of creatures living in Jupiter’s atmosphere. I think this could be a jumping off point for thinking about real “alien” eyes. Especially because Jupiter could not be more different than earth.
Their paper didn’t specify the details of the creatures’ eyes, but it did suggest a possible visual system. Given the low light levels in the atmosphere, they would likely be highly sensitive to visible light, which is primarily sunlight reflecting off the clouds.
Sagan and Salpeter imagined three types of lifeforms:
Sinkers: These are microscopic organisms, like bacteria or plankton, that live on organic molecules and drift down into the deeper, hotter layers of the atmosphere. They likely would not have complex eyes, but instead, would have simple photoreceptors to detect light for photosynthesis.
Floaters: These are gigantic, balloon-like creatures that could be miles wide. They would maintain buoyancy by heating the gases inside their bodies and would graze on the smaller sinkers. Their eyes would probably be large and highly sensitive to capture as much light as possible in the perpetually cloudy environment.
Hunters: These are agile, jet-propelled predators that would feed on the massive floaters. Their eyes would need to be exceptionally well-developed for navigating the turbulent atmosphere and for tracking their enormous prey from a distance.
It is highly unlikely that these hypothetical creatures would see the same colors as humans. Their vision would be fundamentally different, tailored to the unique lighting conditions and atmospheric composition of Jupiter.
Since Jupiter is much farther from the sun, the intensity of sunlight is significantly lower than on Earth. FWIW though, Jupiter does produce a bit of it’s light. The planet’s thick atmosphere, which contains large amounts of methane and ammonia, absorbs red and orange light, and scatters blue and green light. This gives Jupiter its characteristic red and orange color bands, but the light that would be available for vision would be predominantly in the blue, green, and ultraviolet ranges.
Instead of seeing a broad spectrum of colors like humans, these creatures might have a specialized form of color vision focused on the parts of the spectrum that penetrate the atmosphere best. This calls back to the idea that human eyes evolved underwater and that’s why we can mostly see the frequencies that propagate well through water. They might be very good at differentiating subtle shades of blue and green, and even be able to see into the ultraviolet spectrum, which is abundant in Jupiter’s upper atmosphere due to the sun’s radiation.
Sagan also mused on the possibility of using radio waves for communication among these creatures. This would be a more effective form of long-distance communication than vision in an environment with limited light and atmospheric turbulence.
So to wrap this up and get to the point of your original question, aliens could possiblity see colors like we do but would very likely not. It’s even possible they would detect light with an organ more like “ears” than eyes. Where instead of “seeing” sound, they “hear” it like flatworm or octopus “feels” it.
Thanks! Too human centric for my taste, but pretty good!
If you have time, could you try explaining it as if we were talking to an alien, but only through a one-dimensional signal (like ones and zeroes only = cannot explain direction)?
To answer you actual question since my other response completely missed your point, I don’t know if it’s actually possible to properly describe light and color as a one dimensional signal.
I think we need at least two dimensions to describe it properly. Frequency and amplitude. Amplitude is needed to describe how intense/bright the light is and frequency describes what color the light is. Technically there is also polarization which could be thought of as another necessary dimension.
We could likely simplify it just down to the frequency and consider amplitude and polarization to be constants.
But since color is a really a property of the specific kind eye we talk about, and not universal truth, we get kind of stuck on how we could explain it to aliens which possibly have very different eyes or don’t even have eyes at all.
We have to accept that colour is a pretty subjective thing and not a universal truth.
The idea of frequency (vibration) itself though is very likely a universal concept that would be well understood by any human like intelligence in the universe. So we have something to work with.
We can maybe explain how OUR eyes work pretty well just by using frequency alone (just one dimension).
To explain this to an alien with no eyes, the best analogy would be one based on a sense they might have, such as hearing. We could describe the different colors as different pitches of a sound. Just as our ears perceive a low-frequency sound as a low pitch (like a bass drum) and a high-frequency sound as a high pitch (like a piccolo), the different frequencies of light waves correspond to different colors.
Red light has the lowest frequency of the three. Its frequency is approximately in the range of 400 to 484 THz. This corresponds to a wavelength range of about 620 to 750 nanometers (nm).
Green light falls in the middle of the visible spectrum, between red and blue. Its frequency is approximately in the range of 530 to 600 THz. This corresponds to a wavelength range of about 500 to 565 nm.
Blue light has a higher frequency and shorter wavelength than both red and green. Its frequency is approximately in the range of 620 to 670 THz. This corresponds to a wavelength range of about 450 to 485 nm.
We could put this in a neat one dimensional table:
We could of course encode this data into binary (ones and zeros).
What it really all comes down to is that the universe is full of things vibrating (slight over simplification, photons oscillate not vibrate) at different frequencies and amplitudes. We have organs that turn vibrating air molecules into sound and we have organs that turn vibrating photons into vision.
Living things often develop organs that let them turn these abstract vibrations into useful inputs that their brains can do stuff with. Things like color and sound are really more a property of biology than physics/math. So explaining them in terms of pure physics/math is pretty challenging.
Hope that was a kind of interesting answer at least.
Note: Im tired and misread your question as something like “how can non-human creatures/aliens tell the difference between colours?”. I wrote too much now to delete this haha.
That gets super weird because a “color” is a pretty subjective concept. It’s really just photons (light) vibrating at certain frequencies. We developed special organs for detecting certain frequencies (eyes) when we were still fish-like things living underwater. Because of that we can mostly see colors that propagate through water fairly well. There are whole classes of color we know exist but can’t see (ultraviolet and infrared).
It gets even weirder because some HUMANS seem to not even see colors the way western people do. The Himba language has a single word, “buru,” that covers what Western cultures consider both green and blue. This makes it more difficult for them to quickly differentiate between a blue square and a group of green squares in a visual test. The Himba language has many words for different shades of green that Western languages do not, which allows them to easily distinguish between subtle variations of green that are very difficult for English speakers to see. So colors are also a cultural/linguistics thing that extends beyond pure science.
To start breaking away from human centric stuff and get into aliens, we should look at other animals which evolved eyes separately from humans. Eyes actually evolved several times in completely separate animal lineages (convergent evolution). But the cool thing is that some animals who also have eyes, see colors in fundamentally different ways because they have different cones and brains.
The eyes of mantis shrimp and birds for example evolved completely separately from the eyes of humans and for different reasons. We don’t share a common ancestor which has eyes.
Birds and some insects are often tetrachromats, possessing four types of cones. They can see colors in the ultraviolet spectrum, which is invisible to humans. This allows them to see patterns on flowers and other organisms that are used for navigation or to attract mates.
Mantis shrimp have the most complex color vision known, with up to 12 types of photoreceptors. Scientists are still trying to understand exactly how their brain processes this information.
Many animals have light-sensitive organs that are not even considered eyes. This is known as extraocular photoreception, and it serves a variety of purposes beyond image formation.
Octopuses and Cuttlefish have an ability to change the color and texture of their skin for camouflage. It turns out that their skin contains the same light-sensitive proteins (opsins) found in their eyes. This “dermal light sense” allows their skin to respond directly to light, helping them to match their surroundings without the need for input from their brain.
Flatworms have eyes that are sensitive to light and dark, but they also have other light-sensitive cells scattered across their bodies. These cells help them to sense light well enough to get around but not much more.
So light doesn’t even neasesarily need to be a “visual” thing at all. It really just comes down to having some sensory organ that can detect photons.
Carl Sagan, and E. E. Salpeter, proposed a hypothetical ecosystem of creatures living in Jupiter’s atmosphere. I think this could be a jumping off point for thinking about real “alien” eyes. Especially because Jupiter could not be more different than earth.
Their paper didn’t specify the details of the creatures’ eyes, but it did suggest a possible visual system. Given the low light levels in the atmosphere, they would likely be highly sensitive to visible light, which is primarily sunlight reflecting off the clouds.
Sagan and Salpeter imagined three types of lifeforms:
Sinkers: These are microscopic organisms, like bacteria or plankton, that live on organic molecules and drift down into the deeper, hotter layers of the atmosphere. They likely would not have complex eyes, but instead, would have simple photoreceptors to detect light for photosynthesis.
Floaters: These are gigantic, balloon-like creatures that could be miles wide. They would maintain buoyancy by heating the gases inside their bodies and would graze on the smaller sinkers. Their eyes would probably be large and highly sensitive to capture as much light as possible in the perpetually cloudy environment.
Hunters: These are agile, jet-propelled predators that would feed on the massive floaters. Their eyes would need to be exceptionally well-developed for navigating the turbulent atmosphere and for tracking their enormous prey from a distance.
It is highly unlikely that these hypothetical creatures would see the same colors as humans. Their vision would be fundamentally different, tailored to the unique lighting conditions and atmospheric composition of Jupiter.
Since Jupiter is much farther from the sun, the intensity of sunlight is significantly lower than on Earth. FWIW though, Jupiter does produce a bit of it’s light. The planet’s thick atmosphere, which contains large amounts of methane and ammonia, absorbs red and orange light, and scatters blue and green light. This gives Jupiter its characteristic red and orange color bands, but the light that would be available for vision would be predominantly in the blue, green, and ultraviolet ranges.
Instead of seeing a broad spectrum of colors like humans, these creatures might have a specialized form of color vision focused on the parts of the spectrum that penetrate the atmosphere best. This calls back to the idea that human eyes evolved underwater and that’s why we can mostly see the frequencies that propagate well through water. They might be very good at differentiating subtle shades of blue and green, and even be able to see into the ultraviolet spectrum, which is abundant in Jupiter’s upper atmosphere due to the sun’s radiation.
Sagan also mused on the possibility of using radio waves for communication among these creatures. This would be a more effective form of long-distance communication than vision in an environment with limited light and atmospheric turbulence.
So to wrap this up and get to the point of your original question, aliens could possiblity see colors like we do but would very likely not. It’s even possible they would detect light with an organ more like “ears” than eyes. Where instead of “seeing” sound, they “hear” it like flatworm or octopus “feels” it.