HIGH POWER FERRITE PHASE SHIFTER

Abstract

Theoretical estimates of phase shifter performance as a function of material parameters are presented by examining the results obtained from the small perturbation model used by Button and Lax and from the fully ferrite loaded, parallel plane waveguide model used by Suhl and Walker. The extension of Suhl's theory on nonlinear effects at high power by Fletcher and Silence is applied to relate the material parameters and operating frequency to the magnetic field required to avoid high power subsidiary resonance effects. Experiments designed to demonstrate the relationship of phase shift and loss characteristics to material parameters and configuration for longitudinally magnetized ferrites in rectangular waveguide are described. Polycrystalline ferrites with both cubic and hexagonal structures are examined. Of the hexagonal materials, both uniaxial and planar types with oriented anisotropy fields are discussed. The experimental work leading to the growth of extremely large single crystals of lithium ferrite and their electrical and magnetic properties are reported. Experiments which reduced the linewidth of lithium ferrite samples by heat treatment and polishing are described. High power tests to 100 kw peak are reported for waveguide configurations containing (1) single crystal lithium ferrite; (2) polycrystalline cubic structure, nickel ferrite; and (3) polycrystalline hexagonal structure nickel-cobalt 'W' ferrite with its magnetic anisotropy oriented parallel to the applied magnetic field. These high power tests demonstrate that the nonlinear high power effects can be avoided by operating at magnetic fields above ferrimagnetic resonance as prescribed by Fletcher and Silence.

Document Details

Document Type

Technical Report

Publication Date

Oct 01, 1965

Accession Number

AD0621872

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