# What do the colors in false color images represent?

Every kid who first looks into a telescope is shocked to see that everything's black and white. The pretty colors, like those in this picture of the Sleeping Beauty Galaxy (M64), are missing:

The person running the telescope will explain to them that the color they see in pictures like those isn't real. They're called "false color images", and the colors usually represent light outside the visual portion of the electromagnetic spectrum.

Often you see images where a red color is used for infrared light and purple for ultraviolet. Is this also correct for false color astronomy images? What colors are used for other parts of the spectrum? Is there a standard, or does it vary by the telescope the image was taken from or some other factor?

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dear lord that galaxy is beautiful – Carson Myers Jun 13 '11 at 7:36

Part of why you don't see colors in astronomical objects through a telescope is that your eye isn't sensitive to colors when what you are looking at is faint. Your eyes have two types of photoreceptors: rods and cones. Cones detect color, but rods are more sensitive. So, when seeing something faint, you mostly use your rods, and you don't get much color. Try looking at a color photograph in a dimly lit room.

As Geoff Gaherty points out, if the objects were much brighter, you would indeed see them in color.

However, they still wouldn't necessarily be the same colors you see in the images, because most images are indeed false color. What the false color means really depends on the data in question. What wavelengths an image represents depends on what filter was being used (if any) when the image was taken, and the sensitivity of the detector (eg CCD) being used. So, different images of the same object may look very different. For example, compare this image of the Lagoon Nebula (M8) to this one.

Few astronomers use filter sets designed to match the human eye. It is more common for filter sets to be selected based on scientific considerations. General purpose sets of filters in common use do not match the human eye: compare the transmission curves for the Johnson-Cousins UBVRI filters and the SDSS filters the the sensativity of human cone cells. So, a set of images of an object from a given astronomical telescope may have images at several wavelengths, but these will probably not be exactly those that correspond to red, green, and blue to the human eye. Still, the easiest way for humans to visualise this data is to map these images to the red, green, and blue channels in an image, basically pretending that they are.

In addition to simply mapping images through different filters to the RGB channels of an image, more complex approaches are sometimes used. See, for example, this paper (2004PASP..116..133L).

So, ultimately, what the colors you see in a false color image actually mean depends both of what data happened to be used to be make the image and the method of doing the mapping preferred by whoever constructed the image.

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Since this is not a full answer here goes my comment We use or better say map different parts of electromagnetic spectra to RGB. This is true for Infrared, SubMM, MM, etc. We usually use colour distinction based on the amount of interstellar extinction. We put say 3 micron as blue, 4 micron say green and 8 micron say red. This way we reveal some of the deeply embedded objects - young stars for example. – Tigran Khanzadyan Jun 13 '11 at 11:20
To go along with both Eric's and Tigran's explanations, this image shows the color mappings of the famous image of the Eagle Nebula. Notice that the colors used (blue, green, and red) don't exactly match the colors they represent. A true color image, on the other hand, is very different (mostly red due to H-alpha). Still, your eye isn't sensitive enough to perceive this color. – voithos Jun 13 '11 at 19:39

Answering that the colours are false is wrong. False colours are used only in a small minority of astronomical photographs. In most cases, the colours are 100% real. They certainly haven't been added by computers, as some people claim. The first colour photographs of astronomical objects came out in the late 1950s, and showed brilliant reds and blues. This was decades before computers began to be used in astrophotography.

The correct answer is that the colours are real, but the human eye lacks the capability of seeing any colours at such low levels of light intensity. The colours are there, but everything is interpreted as shades of grey green by the human eye.

I can count only three times in 54 years of observing when I have seen colours in deep sky objects, and all were with very large apertures: 18-inch (Eta Carinae Nebula), 22-inch (Dumbbell Nebula), and 74-inch (Cat's Eye Nebula).

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I don't think "false colors" implies that the colors were "added by computer", only that they do not represent the exact same colors the eye would see, which is correct. I do not know how well color photographic film really matches the human eye, but I do expect that it is much closer than, say, Johnson BVR. However, I suspect that such film is uncommon in images in contemporary publications, which are probably mostly Johnson B/V/R, SDSS g/r/i, or some set of HST filters (F430W + F555W + F814W?). For emission line objects, sometimes the difference can be dramatic. – EHN Jun 13 '11 at 4:29

For solar physics, the false colors were used to quickly identify the filter that was used, and possibly even the instrument itself.

So, for instance, SOHO/EIT, there are three filters, each one typically shown with a color that are ordered by spectrum (eg, the 'green' false color image has a spectral sensitivity between the 'yellow' and 'blue' images. 'yellow' is between 'orange' and 'green')

STEREO/SECCHI/EUVI used the same colors for the corresponding spectral lines that their filters were sensitive to, so when you'd see a 'blue' picture of the sun, you knew it was near 171 Angstrom, 'green' was near 195 Angstrom, etc.

And then came SDO/AIA, which was done by the team who brought you TRACE, so they carried over the colorings from their previous instrument, which never generated full disk images (unless as a mosaic). So now, the 171 images are yellow, not blue. The Blue images are actually 335, which would be closer to the red/orange 304 images, which themselves have enough disagreement on color tables that even the SDO mission website uses a table closer to the EIT/EUVI tables than the AIA PI teams' table. (so, in a way, the color table also reflects what the scientist is more interested in ... Flaring regions, or the everyday stuff.)

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Astronomers sometimes show objects, such as the Moon and Mercury in their true colors, but, since the color variations are subtle, they enhance the saturation of the colors to show differences more clearly.

Earth scientists often use a special false color palette for observations; the filters are infrared, red, and green (they don't use blue because blue scattered most by the atmosphere). But infrared is converted to green in the picture because infrared is strongly reflected by plants. Then red is left as red, and green converted to blue to make 'natural' looking pictures.

Astronomers must use false colors when visualizing objects in band passes completely invisible to the eye, such as infrared and ultraviolet. They almost always use the convention that the longest wavelength or lowest energy is rendered red, the middle band is rendered green, and the shortest wavelength or highest energy is rendered blue. This can be a significant aid to scientists in interpretation, as well as just to the general public.

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The images that are currently taken with the High End, (read: \$), Astro-cameras, indeed produce complete full color images. A perfect example is http://www.kevindixon.westhost.com/Deep_Sky_CCD-Siciliano.htm. This is one of many by this particular Astrophotographer. None of the color is false at all. Astrophysicists will use spectral analysis to assign colors to specific elements, thereby creating a "False Color" image. This gives them the ability to 'view' the makeup of an object that they desire to study in detail as to the distribution of the elemental makeup of a specific object of interest. You will find at the above link, all the details regarding the image. How long it took, the camera used, and even the Amateur Astronomer's Telescope that it was taken through.

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