Title :
Scattering from the quasi-optical ferrite circulator using a coupled integral equation/FEM solution
Author :
Epp, L.W. ; Hoppe, D.J. ; Chinn, G.C. ; Jin-Fa Lee
Author_Institution :
Jet Propulsion Lab., California Inst. of Technol., Pasadena, CA, USA
Abstract :
Transmitters of the JPL/NASA Deep Space Network (DSN) typically operate at power levels in excess of 100 kW. This causes heat dissipation and loss problems even in the conventional DSN transmit frequencies of the S and X bands. These problems are compounded by operation in continuous mode, rather than in pulsed operation where the average power is low. In an effort to avoid the heat dissipation, waveguide loss, and arcing problems aggravated by high average power, the DSN has helped pioneer the development of beam waveguide antennas. These beam waveguide antennas use quasi-optical techniques to confine the fields, eliminating waveguide usage and their associated losses. The development of quasi-optical, non-reciprocal devices is natural to the beam waveguide environment. The present paper discusses the use of a ferrite circulator in this context.
Keywords :
antenna accessories; electromagnetic wave scattering; ferrite circulators; finite element analysis; integral equations; microwave circulators; radio transmitters; transmitting antennas; waveguide antennas; 17 GHz; Deep Space Network; SHF; arcing; beam waveguide antennas; coupled integral equation FEM solution; heat dissipation; losses; nonreciprocal devices; power levels; quasi-optical ferrite circulator; scattering; transmitters; waveguide loss; waveguide usage; Anisotropic magnetoresistance; Ferrites; Frequency; Integral equations; Laboratories; Millimeter wave devices; Polarization; Propulsion; Scattering; Thermal conductivity;
Conference_Titel :
Antennas and Propagation Society International Symposium, 1994. AP-S. Digest
Conference_Location :
Seattle, WA, USA
Print_ISBN :
0-7803-2009-3
DOI :
10.1109/APS.1994.408236
