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> Hubble Space Telescope
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The Hubble Space
Telescope (HST), named after Edwin Hubble, was launched in 1989. However,
a flaw in its primary mirror did not allow it to perform up to
expectations until a team of astronauts fixed it during a space walk in
December of 1993.
Since then, the HST has returned dazzling pictures which have provided
scientists with a new view of the cosmos in many different areas of
astronomy, such as star formation, black holes, and the history of the
universe.
Purpose
The HST was one of the most expensive satellites to put in
orbit. Its primary mirror is only 2.4 meters (7.87 ft) wide, but it is
still able to capture images with higher resolution than any other ground
telescope until recent years*. The reason for this is Earth's atmosphere.
While it shields us from harmful radiation and allows us to live, it is
also turbulent and heavily distorts any image that is taken through it.
Therefore, with a telescope circling Earth high above the distortion
effects, HST could take sharper pictures than the twin 10 m (33 ft)
telescopes atop Hawaii's Mauna Kea.
*The military declassification of the process of adaptive optics - with
which most of the larger telescopes, such as the Keck atop Mauna Kea, have
been fitted - allow much clearer images with higher resolution to be
taken. The basic process is that a computer uses a "guide star" to monitor
the turbulence in the atmosphere. Then, it controls sometimes hundreds of
little motors to slightly alter the shape of the telescope's mirror to
compensate for the atmospheric turbulence. [Top]
Images
Many pictures that the HST takes are of the spectra - all
of the light spread out into a rainbow - of objects. An astrophysicist
proverb states that if a picture is worth a thousand words, then a spectra
is worth a thousand pictures. For example, if you take a picture of a
star,
 then
you see a point of light. But, if you take a spectra of a star, then you
can see the different types of chemicals it is made of, how far away it
is, and other information. Most of the 140,000+ pictures that the HST has
taken that have been released to the public though, are in visible light.
A famous image from HST is called the Hubble Deep Field North (left), and
it was taken in 1995. It took Hubble two weeks to generate the picture,
but it shows thousands of galaxies, some over ten billion years old.
Pictures like this are helping astronomers to map the visible universe.
Another famous image from
HST is from the Eagle Nebula (M16). It shows three pillars of gas, each
about 1 light-year wide, with the largest begin 10 light-years long. It
shows young protostars that are just beginning to break free of their
birth nebula.
There are two web sites that are dedicated to hosting pictures taken by
the HST. One is the Hubble Heritage Gallery, which releases one image a
month to the public. I have that duplicated with my own twist in the
Advanced version of this page. The other site is the Hubble Space
Telescope Public Pictures, which has almost if not all of the pictures
from HST that have been released to the public. Both sites have full
descriptions of every image they have, as well as the images in varying
sizes and resolutions. [Top]
Image Processing
Of the images the HST does take, none are in color. To
produce the images that you are used to seeing, several pictures are
actually taken. These pictures are taken in different filters, so that
only light of certain wavelengths can reach the detector. This way,
scientists can study an object in just infrared, or just optical light.
In the example to the right, three filters are used to gather red, optical
green, and blue light. The images are recorded onto the detector as photon
hits; the brighter the image, the more photons are detected. Thus the
resulting image is also black and white.
The next step to producing the full-color images such as those in the
Hubble Heritage galleries is to clean the raw pictures by removing false
photon hits and any biases of the different pixels of the detector.
Finally, three (usually) images that were taken with different filters are
combined in an image processing program, such as Adobe Photoshop. In this,
the different filters can be assigned different colors, not necessarily in
the same order as they appear in the EM spectrum and not necessarily the
original color that it would appear with the human eye.
In the example above, the red light is coded blue, the optical green is
red, and the blue is green. Then, delicate image manipulations are
performed in order to achieve a visually pleasing image. [Top]
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