Algonquin 46m radio telescope

Algonquin 46m radio telescope

Organisation	Thoth Technology Inc.
Location(s)	Algonquin Provincial Park
Coordinates	45°57′20″N 78°04′23″W / 45.955503°N 78.073042°W / 45.955503; -78.073042Coordinates: 45°57′20″N 78°04′23″W / 45.955503°N 78.073042°W / 45.955503; -78.073042
Wavelength	radio (L-band S-band and X-band)
Built	1966
Telescope style	Fully steerable (Gregorian reflector) comprising parabolic reflector and focus house on tetrapod support currently operated in prime focus mode
Diameter	45.7 m (149 ft 11 in)
Collecting area	~1,640 m²
Focal length	18.3 m (60 ft)
Mounting	Alt-azimuth
Website	www.arocanada.com
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The Algonquin 46m radio telescope (ARO) is a radio telescope at the Algonquin Radio Observatory, Canada. This radio telescope is historically famous for taking part in the first successful very long baseline interferometry experiment in the 1960s, where it was experimentally arrayed with the 26-metre Telescope at the Dominion Radio Astrophysical Observatory near Penticton, British Columbia.

History

In 1961, the site was selected by the National Research Council of Canada as suitable for the construction of a 120 ft (37 m) fully steerable antenna.^[1] By 1962, plans showed that the main instrument had grown to a 150 ft (46 m) antenna; construction of this commenced in 1964.

Construction of the 150 ft (46 m) telescope started in the spring of 1964. The concrete base weighed 300 tons, the steel dish and the its rotating mount another 900 tons. An equatorial mount in the base, only five feet high, positioned the instrument. The telescope was designed to operate at higher frequencies than existing instruments, requiring much of it to be constructed of flat plates instead of an open mesh in order to accurately focus these signals. The surface was built to be accurate to 1/5 of a centimeter, allowing it to accurately focus wavelengths to around 1.5 cm. Construction was completed in early 1966, and the telescope started operations in May 1966. Work was also completed a polar mounted paraboloid microwave horn and an 11 m equatorial mount dish north of the main antenna complex.

One of the earliest extended projects carried out on the instrument was the first successful very long baseline interferometry (VLBI) experiment. Long Baseline Interferometry compares the signals from two or more telescopes, using the differences in phase between the signals to resolve the objects. Earlier experiments had used direct electrical links or microwave relays to extend the distance between the two telescopes, while still allowing real-time comparison of the phase of the two signals in a common instrument. However this limited the distance between the two instruments, to the distance the signal could travel while still remaining in-phase. The NRC invented a new technique that eliminated the need to directly compare the signals in real-time. Their technique used 2 inch Quadruplex videotape to record the signals along with a clock signal from an atomic clock. The clock signal allowed the two signals to be later compared with the same accuracy that had formerly required direct realtime connections. NRC funded the installation of identical instruments at the ARO and a smaller telescope at DRAO. Combining the signals would simulated a single 3,074 km diameter radio telescope.

Having learned that the Americans were also attempting a similar VLBI experiment, they tried to be the first to successfully use the technique. Their target for the experiment was quasar 3C 273. Recordings were made into the early morning of April 17, 1967. DRAOs tapes and atomic clock were shipped to the ARO for comparison, and after a month of trying to get the data to "line up", on May 21 they succeeded. After a few more days they had made the first highly accurate measurement of the size of the quasar, showing it was less than 100 light years across, about 1/1000 the span of the Milky Way. Further experiments revealed the fact that 3C 273 had a distinct "jet".^[2]

In 1968 the 150 ft (46 m) telescope was used in a geodesy experiment that measured the distance between the ARO and space-tracking telescopes in Prince Albert, Saskatchewan to 2143 km ± 20 m.^[3] Other early experiments included a study of flare stars by Queen's University. It was also used by Alan Bridle and Paul Feldman in 1974 for the first SETI search to be carried out at the 1.35 cm wavelength, emitted by water molecules in space.^[4]

Later uses

The 46m Thoth telescope (left) and 11m telescope (right) viewed from the entrance road at the Algonquin Radio Observatory.

The original surface of the 150 ft (46 m) telescope consisted of a mix of aluminum mesh and plates. The mesh was almost transparent to wavelengths less than around a centimeter, and the plated area was not smooth enough to focus shorter wavelengths either. As attention in radio telescopy turned to shorter wavelengths, representing higher energy events, the ARO became less useful. After planning to resurface it so that it could operate at wavelengths as small as 3 mm, the NRC decided to close the ARO in 1987 and purchase a 25% share in the new James Clerk Maxwell Telescope, which would include a radio telescope that could operate at 0.3 to 2 mm.^[2]

References

↑ National Research Council of Canada: Proposed 120ft Telescope, Freeman Fox and Partners, Drawing 384, March 1961
1 2 The Algonquin Radio Observatory, Home to the largest parabolic antenna in Canada
↑ Algonquin Radio Observatory
↑ Algonquin Radio Observatory

Radio astronomy

Concepts

Astronomical interferometer (History)
Very Long Baseline Interferometry (VLBI)
Radio telescope (Radio window)
Astronomical radio source
Units (watt and jansky)

Radio telescopes (List)

Individual telescopes	RATAN-600 Radio Telescope (Russia) 500 m Aperture Spherical Telescope (FAST, China) Arecibo Observatory (Puerto Rico, US) Caltech Submillimeter Observatory (CSO, US) Effelsberg Telescope (Germany) Large Millimeter Telescope (Mexico) Yevpatoria RT-70 (Ukraine) Galenki RT-70 (Russia) Suffa RT-70 (Uzbekistan) Green Bank Telescope (West Virginia, US) Lovell Telescope (UK) Ooty Telescope (India) UTR-2 decameter radio telescope (Ukraine) Sardinia Radio Telescope (Italy) Usuda Telescope (Japan) Qitai Radio Telescope (China) Southern Hemisphere HartRAO (South Africa) Parkes Observatory (Australia) Warkworth Radio Astronomical Observatory (NZ)

Interferometers	Allen Telescope Array (ATA, California, US) Atacama Large Millimeter Array (ALMA, Chile) Australia Telescope Compact Array (ATCA, Australia) Australian Square Kilometre Array Pathfinder (ASKAP, Australia) Canadian Hydrogen Intensity Mapping Experiment (CHIME, Canada) Combined Array for Research in Millimeter-wave Astronomy (CARMA, California, US) European VLBI Network (Europe) Green Bank Interferometer (GBI, West Virginia, US) Giant Metrewave Radio Telescope (GMRT, India) Korean VLBI Network (KVN, South Korea) Low-Frequency Array (LOFAR, Netherlands) MeerKAT (South Africa) Large Latin American Millimeter Array (LLAMA, Argentina/Brazil) Murchison Widefield Array (MWA, Australia) Multi-Element Radio Linked Interferometer Network (MERLIN, UK) Molonglo Observatory Synthesis Telescope (MOST, Australia) Northern Cross Radio Telescope (Italy) Northern Extended Millimeter Array (France) One-Mile Telescope (UK) Primeval Structure Telescope (PaST, China) Square Kilometre Array (SKA, Australia, South Africa) Submillimeter Array (SMA, US) Very Large Array (VLA, New Mexico, US) Very Long Baseline Array (VLBA, US) Westerbork Synthesis Radio Telescope (WSRT, Netherlands)

Space-based telescopes	Spektr-R (Russia) HALCA (Japan)

Observatories

Multi Use

People

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