An ultra-wide bandwidth (704 to 4 032 MHz) receiver for the Parkes radio telescope
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Published:2020
Issue:
Volume:37
Page:
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ISSN:1323-3580
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Container-title:Publications of the Astronomical Society of Australia
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language:en
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Short-container-title:Publ. Astron. Soc. Aust.
Author:
Hobbs GeorgeORCID, Manchester Richard N., Dunning Alex, Jameson Andrew, Roberts Paul, George Daniel, Green J. A., Tuthill John, Toomey Lawrence, Kaczmarek Jane F., Mader Stacy, Marquarding Malte, Ahmed Azeem, Amy Shaun W., Bailes Matthew, Beresford Ron, Bhat N. D. R., Bock Douglas C.-J., Bourne Michael, Bowen Mark, Brothers Michael, Cameron Andrew D., Carretti Ettore, Carter Nick, Castillo Santy, Chekkala Raji, Cheng Wan, Chung Yoon, Craig Daniel A., Dai Shi, Dawson Joanne, Dempsey James, Doherty Paul, Dong Bin, Edwards Philip, Ergesh Tuohutinuer, Gao Xuyang, Han JinLin, Hayman Douglas, Indermuehle Balthasar, Jeganathan Kanapathippillai, Johnston Simon, Kanoniuk Henry, Kesteven Michael, Kramer Michael, Leach Mark, Mcintyre Vince, Moss Vanessa, Osłowski Stefan, Phillips Chris, Pope Nathan, Preisig Brett, Price Daniel, Reeves Ken, Reilly Les, Reynolds John, Robishaw Tim, Roush Peter, Ruckley Tim, Sadler Elaine, Sarkissian John, Severs Sean, Shannon Ryan, Smart Ken, Smith Malcolm, Smith Stephanie, Sobey Charlotte, Staveley-Smith Lister, Tzioumis Anastasios, van Straten Willem, Wang Nina, Wen Linqing, Whiting Matthew
Abstract
Abstract
We describe an ultra-wide-bandwidth, low-frequency receiver recently installed on the Parkes radio telescope. The receiver system provides continuous frequency coverage from 704 to 4032 MHz. For much of the band (
${\sim}60\%$
), the system temperature is approximately 22 K and the receiver system remains in a linear regime even in the presence of strong mobile phone transmissions. We discuss the scientific and technical aspects of the new receiver, including its astronomical objectives, as well as the feed, receiver, digitiser, and signal processor design. We describe the pipeline routines that form the archive-ready data products and how those data files can be accessed from the archives. The system performance is quantified, including the system noise and linearity, beam shape, antenna efficiency, polarisation calibration, and timing stability.
Publisher
Cambridge University Press (CUP)
Subject
Space and Planetary Science,Astronomy and Astrophysics
Reference47 articles.
1. Primary beam effects of radio astronomy antennas – I. Modelling the Karl G. Jansky Very Large Array (VLA) L-band beam using holography 2. HIPSR: A Digital Signal Processor for the Parkes 21-cm Multibeam Receiver 3. The Effects of Digitization on Nonstationary Stochastic Signals with Applications to Pulsar Signal Baseband Recording 4. Hobbs, G. , & Dai, S. 2017. A review of pulsar timing array gravitational wave research (arXiv:1707.01615) 5. Haslam, C. G. T. , Salter, C. J. , Stoffel, H. , & Wilson, W. E. 1982. A&AS, 47, 1
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