Design of a 90 deg 12 GHz Faraday rotator polariser using a cavity technique
Abstract
Ferrite devices based on Faraday rotation remain of interest at both microwave and millimeter wavelengths. Although a complete mathematical description of ferrite cylinders in round waveguides is available, the experimental verification of rotation or differential phase shift in a round waveguide is not simple. The paper describes a resonant cavity procedure which permits the evaluation of the two propagation constants in such a magnetized waveguide. It is obtained by incorporating the Faraday rotator section into a resonator structure by closing both ends of the waveguide and separately tuning its length for each of the two split branches of the magnetized resonator to the frequency of the demagnetized one. The paper includes a lower bound on the length of the rotator bit (or an upper bound on the splitting between the phase constants) in terms of the directivity of the section.
 Publication:

IEE Proceedings H: Microwaves Antennas and Propagation
 Pub Date:
 July 1985
 Bibcode:
 1985IPMAP.132..237H
 Keywords:

 Cavity Resonators;
 Circular Waveguides;
 Faraday Effect;
 Ferrites;
 Microwave Transmission;
 Phase Shift Circuits;
 Polarizers;
 Directional Couplers;
 Ferromagnetic Materials;
 Impedance Matching;
 Magnetization;
 Propagation Modes;
 Electronics and Electrical Engineering