Your search keyword '"John Sarkissian"' showing total 3 results

1. The Breakthrough Listen search for intelligent life: Wide-bandwidth digital instrumentation for the CSIRO Parkes 64-m telescope

Author

Andrew Jameson, David MacMahon, Howard Isaacson, Andrew Siemion, J. Emilio Enriquez, Matt Lebofsky, Steve Croft, John Sarkissian, Nectaria A. B. Gizani, Greg Hellbourg, Philip G. Edwards, David DeBoer, Danny C. Price, L. Ball, Dan Craig, Douglas C.-J. Bock, John Reynolds, James Green, B. Preisig, Dan Werthimer, S. W. Amy, Vishal Gajjar, Stacy Mader, Griffin Foster, and Mal Smith

Subjects

010504 meteorology & atmospheric sciences, Astronomy, Digital data, FOS: Physical sciences, 01 natural sciences, law.invention, Telescope, Software, law, 0103 physical sciences, Instrumentation and Methods for Astrophysics (astro-ph.IM), 010303 astronomy & astrophysics, Search for extraterrestrial intelligence, 0105 earth and related environmental sciences, Physics, business.industry, Digital instrumentation, Bandwidth (signal processing), Electrical engineering, Astronomy and Astrophysics, Space and Planetary Science, Extraterrestrial life, Experimental High Energy Physics, Systems architecture, Astrophysics - Instrumentation and Methods for Astrophysics, business

Abstract

Breakthrough Listen is a ten-year initiative to search for signatures of technologies created by extraterrestrial civilizations at radio and optical wavelengths. Here, we detail the digital data recording system deployed for Breakthrough Listen observations at the 64-m aperture CSIRO Parkes Telescope in New South Wales, Australia. The recording system currently implements two recording modes: a dual-polarization, 1.125 GHz bandwidth mode for single beam observations, and a 26-input, 308-MHz bandwidth mode for the 21-cm multibeam receiver. The system is also designed to support a 3 GHz single-beam mode for the forthcoming Parkes ultra-wideband feed. In this paper, we present details of the system architecture, provide an overview of hardware and software, and present initial performance results., v2, accepted to PASA

Published

2018

2. Base Band Data for Testing Interference Mitigation Algorithms

Author

Peter J. Hall, Franklin H. Briggs, Malcolm R. Smith, Robert J. Sault, Rick J. Smegal, Matthew Bailes, Warwick Wilson, John D. Bunton, M. W. Sinclair, J. F. Bell, Willem van Straten, R. G. Gough, Michael Kesteven, John Sarkissian, Graham J. Carrad, R. H. Ferris, and Kapteyn Astronomical Institute

Subjects

Physics, Signal processing, instrumentation : detectors, business.industry, RADIO ASTRONOMY, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy, methods : data analysis, Astronomy and Astrophysics, Software-defined radio, CANCELLATION, GLONASS, law.invention, Telescope, interferometers, Interference (communication), Space and Planetary Science, law, Reference antenna, Global Positioning System, Baseband, business, Digital signal processing, Computer hardware, techniques : interferometric

Abstract

Digital signal processing is one of many valuable tools for suppressing unwanted signals or inter-ference. Building hardware processing engines seems to be the way to best implement some classes of interference suppression but is, unfortunately, expensive and time-consuming, especially if several miti-gation techniques need to be compared. Simulations can be useful, but are not a substitute for real data. CSIRO’s Australia Telescope National Facility has recently commenced a ‘software radio telescope’ project designed to fill the gap between dedicated hardware processors and pure simulation. In this approach, real telescope data are recorded coherently, then processed offline. This paper summarises the current contents of a freely available database of base band recorded data that can be used to experiment with signal processing solutions. It includes data from the following systems: single dish, multi-feed receiver; single dish with reference antenna; and an array of six 22 m antennas with and without a reference antenna. Astronomical sources such as OH masers, pulsars and continuum sources subject to interfering signals were recorded. The interfering signals include signals from the US Global Positioning System (GPS) and its Russian equivalent (GLONASS), television, microwave links, a low-Earth-orbit satellite, various other transmitters, and signals leaking from local telescope systems with fast clocks. The data are available on compact disk, allowing use in general purpose computers or as input to laboratory hardware prototypes.

Published

2001

3. On Eagle's Wings: The Parkes Observatory's Support of the Apollo 11 Mission

Author

John Sarkissian

Subjects

Physics, Eagle, biology, Apollo, Astronomy, Astronomy and Astrophysics, biology.organism_classification, law.invention, Telescope, Radio telescope, Space and Planetary Science, law, visual_art, biology.animal, visual_art.visual_art_medium, Space Science, Parkes Observatory, Goldstone, Radio astronomy

Abstract

At 12:56 p.m., on Monday 21 July 1969 (AEST), six hundred million people witnessed Neil Armstrong's historic first steps on the Moon through television pictures transmitted to Earth from the lunar module, Eagle. Three tracking stations were receiving the signals simultaneously. They were the CSIRO's Parkes Radio Telescope, the Honeysuckle Creek tracking station near Canberra, and NASA's Goldstone station in California. During the first nine minutes of the broadcast, NASA alternated between the signals being received by the three stations. When they switched to the Parkes pictures, they were of such superior quality that NASA remained with them for the rest of the 2-hour moonwalk. The television pictures from Parkes were received under extremely trying and dangerous conditions. A violent squall struck the telescope on the day of the historic moonwalk. The telescope was buffeted by strong winds that swayed the support tower and threatened the integrity of the telescope structure. Fortunately, cool heads prevailed and as Aldrin activated the TV camera, the Moon rose into the field-of-view of the Parkes telescope. This report endeavours to explain the circumstances of the Parkes Observatory's support of the Apollo 11 mission, and how it came to be involved in the historic enterprise.

Published

2001