Title :
Ruby masers for maximum G/Top
Author :
Shell, James S. ; Clauss, Robert C. ; Petty, Samuel M. ; Glass, Gary W. ; Fiore, Mark Steven ; Kovatch, Jason Jess ; Loreman, Jan Richard ; Neff, Dudley E. ; Quinn, Rex B. ; Trowbridge, David L.
Author_Institution :
Jet Propulsion Lab., California Inst. of Technol., Pasadena, CA, USA
fDate :
5/1/1994 12:00:00 AM
Abstract :
The Deep-Space Network (DSN) includes world-wide networks of 26-, 34- and 70-m antennas in Australia, Spain, and the USA. Ruby masers are used on the 34and 70-m antennas to maximize the system operating noise temperature and thereby maximize the DSN receiving system figure of merit, antenna gain divided by system operating noise temperature. These systems are used for deep-space telecommunications, solar system radar, and radio astronomy. Cavity, traveling-wave, and reflected-wave maser designs and performance characteristics from 960 MHz to 34 GHz are summarized. Effective noise temperatures of ruby masers are addressed with emphasis on a 33.68-GHz maser where quantum noise is a major source of noise
Keywords :
antenna feeders; masers; microwave antennas; preamplifiers; reflector antennas; ruby; space communication links; 960 to 34 MHz; DSN; Deep-Space Network; antenna gain; cavity maser; deep-space telecommunications; designs; maximum G/Top; performance; quantum noise; radio astronomy; receiving system figure of merit; reflected-wave maser; ruby masers; solar system radar; system operating noise temperature; traveling-wave maser; Australia; Frequency; Masers; Noise figure; Radio astronomy; Receiving antennas; Signal to noise ratio; Solar system; Space vehicles; Temperature;
Journal_Title :
Proceedings of the IEEE
