Ryle Telescope

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Ryle Telescope
Mrao ami lba ryle.jpg
The Ryle Telescope was re-arranged to form the AMI Large Array after this photo was taken in 2005
Alternative names5-km Array OOjs UI icon edit-ltr-progressive.svg
Named after Martin Ryle   OOjs UI icon edit-ltr-progressive.svg
Part of Arcminute Microkelvin Imager
Mullard Radio Astronomy Observatory   OOjs UI icon edit-ltr-progressive.svg
Location(s) Cambridgeshire, East of England, England
Coordinates 52°10′11″N0°03′34″E / 52.1698°N 0.0594°E / 52.1698; 0.0594 OOjs UI icon edit-ltr-progressive.svg
Telescope styleradio interferometer  OOjs UI icon edit-ltr-progressive.svg
United Kingdom relief location map.jpg
Red pog.svg
Location of Ryle Telescope
  Commons-logo.svg Related media on Commons
The three AMI-LA antennas left of the hut in this June 2014 photograph were the ones moved in 2014 Cmglee Cambridge MRAO AMI Large Array.jpg
The three AMI-LA antennas left of the hut in this June 2014 photograph were the ones moved in 2014

The Ryle Telescope (named after Martin Ryle, and formerly known as the 5-km Array) was a linear east-west radio telescope array at the Mullard Radio Astronomy Observatory. [1] In 2004, three of the telescopes were moved to create a compact two-dimensional array of telescopes at the east end of the interferometer. The eight antennas have now become the Arcminute Microkelvin Imager Large Array.

The Ryle Telescope was an eight-element interferometer operating at 15 GHz (2cm wavelength). The elements were equatorially mounted 13-m Cassegrain antennas, on an (almost) east-west baseline. Four aerials were mounted on a 1.2 km rail track, and the others were fixed at 1.2 km intervals. Baselines between 18 m and 4.8 km were therefore available, in a variety of configurations. For high-resolution imaging, the mobile aerials were arranged along the track, to give uniform baseline coverage to 4.8 km; for low-brightness astronomy (e.g. the Sunyaev-Zel'dovich effect) the mobile aerials were arranged in a 'compact array', with a maximum baseline of about 100 m. All antenna pairs were correlated, so some long baseline data were always available, even in the 'compact array' configuration.

As the telescope was an east-west instrument, most imaging observations involved 12-hour observations in order to fill the synthesised aperture (calibration observations are routinely interleaved). Another consequence of the geometry was that it is not practical to image sources near the equator, or in the south. The two-dimensional Large Array overcomes this problem with its new north-south baselines.

Although the telescope was not designed as a common user instrument, the operators were happy to accept proposals for observing time on the instrument from outside observers, provided that they did not overlap substantially with existing observing programmes, on a 'best efforts' basis. Monitoring variable sources was possible using short observations which could often be inserted between longer 'standard' observations.

The telescope had three main scientific programs: study of the Sunyaev-Zel'dovich effect in galaxy clusters, particularly in determining the Hubble constant; surveying for radio sources that would contaminate degree-scale observations of the cosmic microwave background made with the Very Small Array, and flux monitoring of galactic variable sources.

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References

  1. Pooley, Guy G. (1 January 2006). Radio monitoring with the Ryle Telescope. Bibcode:2006smqw.confE..19P.