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Telescope - Research telescopes | | Telescope - Research telescopes: Encyclopedia II - Telescope - Research telescopes | | Most large research telescopes can operate as either a Cassegrain telescope (longer focal length, and a narrower field with higher magnification) or a Newtonian telescope (brighter field). They have a pierced primary mirror, a Newtonian focus, and a spider to mount a variety of replaceable secondary mirrors.
A new era of telescope making was inaugurated by the Multiple Mirror Telescope (MMT), with a mirror composed of six segments synthesizing a mirror of 4.5 meters diameter. This has now been replaced by a single 6.5m mirror. Its example was followed by ...
See also:Telescope, Telescope - History, Telescope - Types, Telescope - Telescope mountings, Telescope - Research telescopes, Telescope - Imperfect images, Telescope - The five Seidel aberrations, Telescope - The chromatic aberrations, Telescope - Famous optical telescopes, Telescope - Related lists | | | Telescope, Telescope - Famous optical telescopes, Telescope - History, Telescope - Imperfect images, Telescope - Related lists, Telescope - Research telescopes, Telescope - Telescope mountings, Telescope - The chromatic aberrations, Telescope - The five Seidel aberrations, Telescope - Types, Amateur telescope making, Aperture synthesis, Depth of field, Eyepiece, First light, F-number, History of telescopes, Maksutov telescope, Microscope, Optical telescope, Radio telescope, Reflector telescope, Refracting telescope, Robotic telescope, Timeline of telescopes, observatories, and observing technology | | |
| | | Telescope: Encyclopedia II - Telescope - Research telescopes
Telescope - Research telescopes
Most large research telescopes can operate as either a Cassegrain telescope (longer focal length, and a narrower field with higher magnification) or a Newtonian telescope (brighter field). They have a pierced primary mirror, a Newtonian focus, and a spider to mount a variety of replaceable secondary mirrors.
A new era of telescope making was inaugurated by the Multiple Mirror Telescope (MMT), with a mirror composed of six segments synthesizing a mirror of 4.5 meters diameter. This has now been replaced by a single 6.5m mirror. Its example was followed by the Keck telescopes with 10 m segmented mirrors.
The largest current ground-based telescopes have primary mirrors of between 6 and 11 meters in diameter. In this generation of telescopes, the mirror is usually very thin, and is kept in an optimal shape by an array of actuators (see active optics). This technology has driven new designs for future telescopes with diameters of 30, 50 and even 100 meters.
Relatively cheap, mass-produced ~2 meter telescopes have recently been developed and have made a significant impact on astronomy research. These allow many astronomical targets to be monitored continuously, and for large areas of sky to be surveyed. Many are robotic telescopes, computer controlled over the internet (see e.g. the Liverpool Telescope and the Faulkes Telescope North and South), allowing automated follow-up of astronomical events.
Initially the detector used in telescopes was the human eye. Later, the sensitized photographic plate took its place, and the spectrograph was introduced, allowing the gathering of spectral information. After the photographic plate, successive generations of electronic detectors, such as the charge-coupled device (CCDs), have been perfected, each with more sensitivity and resolution, and often with a wider wavelength coverage.
Current research telescopes have several instruments to choose from such as:
- imagers, of different spectral responses
- spectrographs, useful in different regions of the spectrum
- polarimeters, that detect light polarization.
In recent years, some technologies to overcome the distortions caused by atmosphere on ground-based telescopes were developed, with good results. See adaptive optics, speckle imaging and optical interferometry.
The phenomenon of optical diffraction sets a limit to the resolution and image quality that a telescope can achieve, which is the effective area of the Airy disc, which limits how close two such discs can be placed. This absolute limit is called the diffraction limit (or sometimes the Rayleigh criterion, Dawes limit or Sparrow's resolution limit). This limit depends on the wavelength of the studied light (so that the limit for red light comes much earlier than the limit for blue light) and on the diameter of the telescope mirror. This means that a telescope with a certain mirror diameter can resolve up to a certain limit at a certain wavelength. If greater resolution is needed at that wavelength, a wider mirror has to be built or aperture synthesis performed using an array of nearby telescopes.
Other related archives10th century, 1608, 1609, 1888, 1919, 2002, 2005, Dobsonian mount, altitude-azimuth or altazimuth mount, equatorial mount, Airy disc, Amateur telescope making, Aperture Masking Interferometry, Aperture synthesis, Arabs, As of 2005, Astigmatism, Atacama desert, CHARA (Center for High Angular Resolution Astronomy) array, Cassegrain telescope, Chile, Coma, Dawes limit, Depth of field, Earth, Edwin Hubble, European Southern Observatory, Eyepiece, F-number, Faulkes Telescope North, First light, France, Galileo, Galileo Galilei, Gran Telescopio Canarias, Greek, HALCA, Hale telescope, Hans Lippershey, History of telescopes, Hooker Telescope, Hubble Space Telescope, Jacob Metius, Japanese, Johannes Kepler, Keck telescopes, Leonard Digges, Lick Observatory, List of largest optical reflecting telescopes, List of largest optical refracting telescopes, List of telescope types, Liverpool Telescope, Maksutov telescope, Microscope, Mount Wilson Observatory, Multiple Mirror Telescope, Navy Prototype Optical Interferometer, Newtonian telescope, Nice refractor, Optical telescope, Overwhelmingly Large Telescope, Palomar Mountain, Persians, Petzval, Philipp Ludwig von Seidel, Pyrex, Radio telescope, Radio telescopes, Rayleigh criterion, Reflector telescope, Refracting telescope, Robotic telescope, Saint-Gobain, South, Southern African Large Telescope, Spherical aberration, Timeline of telescopes, observatories, and observing technology, Very Large Telescope, Very Long Baseline Interferometry, Vikings, Visby lenses, Wisconsin, X-ray, Yerkes Telescope, Zacharias Jansen, aberrations, active optics, adaptive optics, angular size, antennas, aperture synthesis, astronomical, astronomical seeing, astronomy, atmosphere, azimuth, binoculars, borosilicate, brightness, camera lenses, charge-coupled device, degrees, detector, diameter, diffraction, diffraction limit, electromagnetic radiation, eye, focus, focuses, galaxies, gamma-ray, heavy metals, interferometer, lenses, meridian, meters, mirrors, monoculars, optical, optical interferometers, optical interferometry, optical telescopes, optics, panoramic photo, parabola, photographic plate, polarization, radio, redshift, reflecting, reflective, refracting, refractive, robotic telescopes, sidérostat, speckle imaging, spectrograph, spectrum, spotting scopes, spyglasses, telescope mount, terrestrial, theodolites, tool, transits, ultraviolet, wavelength
 Adapted from the Wikipedia article "Research telescopes", under the G.N U Free Docmentation License. Please also see http://en.wikipedia.org/wiki |
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