CHAPTER 6 | LIGHT AND TELESCOPES 109
Adaptive Optics
Not too many years ago, astron-
omers thought it was pointless to
build more large telescopes on
Earth’s surface because of seeing
distortion caused by the atmo-
sphere. In the 1990s, computers
became fast enough to allow
astronomers to correct for some
of that distortion, and that has
made the new generation of giant
telescopes possible.
Adaptive optics uses high-
speed computers to monitor the distortion produced by turbulence
in Earth’s atmosphere and then correct the telescope image to
sharpen a fuzzy blob into a crisp picture. Th e resolution of the
image is still limited by diff raction in the telescope, but removing
much of the seeing distortion produces a dramatic improvement in
the detail visible (■ Figure 6-14). Don’t confuse adaptive optics
with the slower-speed active optics that controls the overall shape
of a telescope mirror.
To monitor the distortion in an image, adaptive optics sys-
tems must look at a fairly bright star in the fi eld of view, and there
isn’t always such a star properly located near a target object such
as a faint galaxy. In that case, astronomers can point a laser at a
spot in the sky very close to their target object, and where the laser
excites gas in Earth’s upper atmosphere, it produces a glowingModern computers have revolutionized telescope design and
operation. Nearly all large telescopes are operated by astronomers
and technicians working at computers in a control room, and
some telescopes can be operated by astronomers thousands of
miles from the observatory. Some telescopes are fully automated
and observe without direct human supervision. Th is has made
possible huge surveys of the sky in which millions of objects are
observed. Th e Sloan Digital Sky Survey, for example, mapped the
sky, measuring the position and brightness of 100 million stars
and galaxies at a number of wavelengths. Th e Two-Micron All
Sky Survey (2MASS) has mapped the entire sky at three wave-
lengths in the infrared. Other surveys are being made at other
wavelengths. Astronomers will study those data banks for decades
to come.
If built, the European Extremely
Large telescope (E-ELT) will have
a 42-m diameter mirror composed
of 906 segments. Note the car
at lower left for scale.Thirty Meter TelescopeGiant Magellan TelescopeThe 42-m mirror will
contain 906 segments.Note the human figure for
scale in this computer
graphic visualization.■ Figure 6-13
The proposed Giant Magellan Telescope
will have the resolving power of a tele-
scope 24.5 meters in diameter when it
is fi nished in about 2016. The Thirty
Meter Telescope (TMT) is planned to
occupy a specially designed dome. Like
nearly all of the newest large tele-
scopes, the European Extremely Large
Telescope will be on an alt-azimuth
mounting. (GMT: ESO; TMT: TMT: Thirty-
Meter Telescope; E-ELT: ESO)Adaptive OpticsOffOn■ Figure 6-14
In these images of the center of our gal-
axy, the adaptive optics system was turned
off for the left image and on for the right
image. Not only are the images of stars
sharper, but because the light is focused into
smaller images, fainter stars are visible. The
laser beam shown leaving one of the Keck
Telescopes produces an artifi cial star in the
fi eld of view, and the adaptive optics sys-
tem uses the laser-produced point of light to
reduce seeing distortion in the entire image.
(left, CFHT; right, Paul Hirst)