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Ferrites (Magnetic materials)

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Ferrates
Ferrite (magnet)

Filed under: Ferrites (Magnetic materials)

Theory and Application of Ferrites (Englewood Cliffs, NJ: Prentice-Hall, 1960), by Ronald F. Soohoo (page images at HathiTrust)
Microwave Ferrites and Ferrimagnetics (New York et al.: McGraw-Hill, c1962), by Benjamin Lax and Kenneth J. Button (page images at HathiTrust)
Friction and morphology of magnetic tapes in sliding contact with nicle-zinc ferrite (National Aeronautics and Space Administration, Scientific and Technical Information Office ;, 1984), by Kazuhisa Miyoshi, Bharat Bhushan, Donald H. Buckley, and United States. National Aeronautics and Space Administration. Scientific and Technical Information Office (page images at HathiTrust)
Water-vapor effects on friction of mangetic tape in contact with nickel-zinc ferrite (National Aeronautics and Space Administration, Scientific and Technical Information Branch ;, 1984), by Kazuhisa Miyoshi, Donald H. Buckley, and United States. National Aeronautics and Space Administration. Scientific and Technical Information Branch (page images at HathiTrust)
Development of a monolithic ferrite memory array (National Aeronautics and Space Administration ;, 1972), by C. H. Heckler, N. C. Bhiwandker, Langley Research Center, and Ampex Corporation (page images at HathiTrust)
The properties of ferromagnetic ferrites (United States Atomic Energy Commission, Technical Information Service, 1951), by John P. Blewett, M. Hildred Blewett, Martin Plotkin, and Brookhaven National Laboratory (page images at HathiTrust)
Modeling of domain growth activity in polycrystalline ferrites. (Dept. of Computer Science, University of Illinois, 1969), by Richard Paul Harms (page images at HathiTrust)
The growth of single crystals (L.G. Hansom Field, Bedford, Massachusetts : Air Force Cambridge Research Laboratories, Office of Aerospace Research, United States Air Force, 1966., 1966), by C. S. Sahagian and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Anisotropic spin-wave propagation in ferrites (L.G. Hanscom Field, Massachusetts : Air Force Cambridge Research Laboratories, Office of Aerospace Research, United States Air Force, 1966., 1966), by James C. Sethares, Tom G. Purnhagen, and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Transmission line models of magnon-phonon modes in ferrites. Part I. Uncoupled modes (L. G. Hansom Field, Bedford, Massachusetts : Air Force Cambridge Research Laboratories, Office of Aerospace Research, United States Air Force, 1966., 1966), by James C. Sethares and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Transmission line models of Magnon-Phonon modes in ferrites. Part II. Coupled modes (L. G. Hansom Field, Bedford, Massachusetts : Air Force Cambridge Research Laboratories, Office of Aerospace Research, United States Air Force, 1967., 1967), by James C. Sethares and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Resistance to continued heating of powdered cover coats applied to enameling iron and ferritic alloy (Wright-Patterson Air Force Base, Ohio : Wright Air Development Center, Air Research and Development Command, United States Air Force, 1953., 1953), by Robert M. King, William E. Watkins, Robert J. Brinkman, United States. Air Force. Air Research and Development Command, Wright Air Development Center, and Ohio State University. Research Foundation (page images at HathiTrust)
Ferrimagnetic materials at microwave frequencies. (Wright-Patterson Air Force Base, Ohio : Materials Laboratory, Research and Technology Division, Air Force Systems Command, United States Air Force, 1964., 1964), by Arnold S. Boxer, J. F. Ollom, H. E. Noffke, H. L. Goldstein, Air Force Materials Laboratory (U.S.), United States. Air Force. Systems Command. Research and Technology Division, Western Electric Company, and Bell Telephone Laboratories (page images at HathiTrust)
Ferrimagnetic materials at microwave frequencies : attachment to technical documentary report no. 64-224 (Wright-Patterson Air Force Base, Ohio : Materials Laboratory, Research and Technology Division, Air Force Systems Command, United States Air Force, 1964., 1964), by Arnold S. Boxer, Robert F. Rauchmiller, J. F. Ollom, Air Force Materials Laboratory (U.S.), United States. Air Force. Systems Command. Research and Technology Division, Western Electric Company, and Bell Telephone Laboratories (page images at HathiTrust)

Filed under: Ferrites (Magnetic materials) -- Thermal properties

X-ray photoelectron spectroscopy and friction studies of nickel-zinc and manganese-zinc ferrites in contact with metals (National Aeronautics and Space Administration, Scientific and Technical Information Office ;, 1983), by Kazuhisa Miyoshi, Donald H. Buckley, United States. National Aeronautics and Space Administration. Scientific and Technical Information Office, and Lewis Research Center (page images at HathiTrust)

Filed under: Wustite

A thermodynamic study of the Wüstite Phase (Argonne National Laboratory, 1966), by R. J. Ackermann, R. W. Sandford, U.S. Atomic Energy Comission, and Argonne National Laboratory. Chemistry Division (page images at HathiTrust; US access only)
Dispersing antiferromagnetic precursors to prepare magnetic fluids (U.S. Dept. of Interior, Bureau of Mines, 1972), by G. W. Reimers, S. E. Khalafalla, Twin Cities Metallurgy Research Center (U.S.), and United States Bureau of Mines (page images at HathiTrust)

Filed under: Yttrium iron garnet

Magnetostatic surface waves on a cylinder (Air Force Cambridge Research Laboratories, Air Force Systems Command, United States Air Force, 1975), by James C. Sethares and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Magnetic anisotropy fields in single-crystal iron garnets (L.G. Hansom Field, Bedford, Massachusetts : Air Force Cambridge Research Laboratories, Office of Aerospace Research, United States Air Force, 1965., 1965), by Peter D. Gianino and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Disappearance of magnetocrystalline anisotropy effects on spin resonance of YIG (L.G. Hansom Field, Bedford, Massachusetts : Air Force Cambridge Research Laboratories, Office of Aerospace Research, United States Air Force, 1965., 1965), by E. Czerlinsky, P. D. Gianino, and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Anisotropic spin-wave propagation in ferrites (L.G. Hanscom Field, Massachusetts : Air Force Cambridge Research Laboratories, Office of Aerospace Research, United States Air Force, 1966., 1966), by James C. Sethares, Tom G. Purnhagen, and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Magnetostatic surface waves in ferrimagnets above 4 GHz (Air Force Cambridge Research Laboratories, Air Force Systems Command, United States Air Force, 1974), by J. C. Sethares, J. Bradford Merry, and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Cation distribution in aluminum-substituted yttrium iron garnets by Mössbauer effect spectroscopy (L.G. Hansom Field, Bedford, Massachusetts : Air Force Cambridge Research Laboratories, Office of Aerospace Research, United States Air Force, 1970., 1970), by Ernst R. Czerlinsky, Raymond A. Macmillan, and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)

Items below (if any) are from related and broader terms.

Filed under: Hall effect

The Hall effect and allied phenomena in silicon. ([Lancaster, Pa.] ; [Ithaca, N.Y.], 1914), by Oliver Ellsworth Buckley (page images at HathiTrust)
Galvanomagnetic and thermomagnetic effects; the Hall and allied phenomena (Longmans, Green and co., 1923), by L. L. Campbell (page images at HathiTrust; US access only)
Über den Halleffekt des wismuts bei hohen temperaturen ... (K. Universitäts-dr. von H. Sturtz, 1905), by Heinrich August Adolf Julius Rausch von Traubenberg (page images at HathiTrust; US access only)
The Hall effect and allied phenomena in tellurium. ([Lancaster, Pa.] ; [Ithaca, N.Y.], 1916), by Peter Irving Wold (page images at HathiTrust)
Effect of low hydrogen concentrations on hall effect in zircaloy-2 (Hanford Atomic Products Operation, 1961), by W. G. Magnuson, U.S. Atomic Energy Commission, Hanford Atomic Products Operation, and Pacific Northwest Laboratory (page images at HathiTrust)
Hall effect in a conductor due to its own magnetic field ... ([Princeton? N.J., 1924), by Walter van Braam Roberts (page images at HathiTrust)
The Hall effect and specific resistance in sputtered tellurium films. ([Ithaca, N. Y.], 1927), by Fred William Warburton (page images at HathiTrust)
Hall-effect instrumentation. (H.W. Sams, 1963), by Barron Kemp (page images at HathiTrust)
Experimental investigation of magnetoaerodynamic flow around blunt bodies (National Aeronautics and Space Administration ;, 1969), by S. Kranc, A. B. Cambel, M. C. Yuen, and Ill.) Northwestern University (Evanston (page images at HathiTrust)
NASA TN D-6466 (National Aeronautics and Space Administration :, 1971), by John A. Woollam, Lewis Research Center, and United States National Aeronautics and Space Administration (page images at HathiTrust)
NASA TN D-1695 (National Aeronautics and Space Administration, 1963), by Martin M. Sokoloski, Felix E. Geiger, Goddard Space Flight Center, and United States National Aeronautics and Space Administration (page images at HathiTrust)
Properties of crystalline bismuth selenide and its use as a Hall effect magnetometer (National Aeronautics and Space Administration ;, 1972), by John A. Woollam, Ian L. Spain, Harry Beale, and Lewis Research Center (page images at HathiTrust)
The Hall effect in bismuth with high frequency currents (n.p., 1912), by Alpheus W. Smith (page images at HathiTrust; US access only)
Microwave mobilities of holes in p-type germanium (Ames Laboratory, 1964), by Bou-loong Ho, G. C. Danielson, U.S. Atomic Energy Commission, and Ames Laboratory (page images at HathiTrust)
Electrical resistivity and Hall effect in sodium tungsten bronze (United States Atomic Energy Commission, Technical Information Service, 1953), by W. R. Gardner, G. C. Danielson, Ames Laboratory, and U.S. Atomic Energy Commission (page images at HathiTrust)
Measurement of magnetic field gradients by the hall effect (United States Atomic Energy Commission, Technical Information Service, 1955), by Robert D. Redin, G. C. Danielson, Ames Laboratory, and U.S. Atomic Energy Commission. Technical Information Service (page images at HathiTrust)
Hall coefficient and resistivity of a Mg₂Si single crystal from 4°K to 300°K (United States Atomic Energy Commission, Office of Technical Information Extension, 1959), by Donald Richard Zrudsky, Gordon Charles Danielson, Ames Laboratory, and U.S. Atomic Energy Commission (page images at HathiTrust)
Automated data collection system applied to Hall effect and resistivity measurements (National Aeronautics and Space Administration ;, 1967), by Ralph D. Thomas and Lewis Research Center (page images at HathiTrust)
The Hall effect in silver films (1917), by G. R. Wait, G. W. Stewart, and State University of Iowa. Graduate College (page images at HathiTrust; US access only)
Hall effect and specific resistance in evaporated films of silver, copper and iron. (1922), by John C. Steinberg (page images at HathiTrust; US access only)
The Hall effect in silver films (1915), by Jesse W. Doolittle and State University of Iowa. Graduate College (page images at HathiTrust; US access only)
Research on properties of rare metals : final report and supplements (Oak Ridge, Tennessee : United States Atomic Energy Commission, Technical Information Service, 1956., 1956), by J. E. Goldman, G. L. Guthrie, Simon Foner, U.S. Atomic Energy Commission. New York Operations Office, and Carnegie Institute of Technology. Laboratory for Magnetics Research (page images at HathiTrust)
Hall effect in solid solutions : technical report no. 33 (United States Atomic Energy Commission, Technical Information Service, 1955), by W. F. Flanagan, B. L. Averbach, U.S. Atomic Energy Commission. New York Operations Office, and Massachusetts Institute of Technology. Department of Metallurgy (page images at HathiTrust)
Galvanomagnetic and thermomagnetic effects ; the Hall and allied phenomena ([Johnson Reprint Corp.], 1960), by L. L. Campbell (page images at HathiTrust; US access only)
Development of an analog multiplier, based on the Hall effect (Wright-Patterson Air Force Base, Ohio : Aerospace Medical Research Laboratories, Aerospace Medical Division, Air Force Systems Command, United States Air Force, 1963., 1963), by R. G. Cameron, Battelle Memorial Institute, and Aerospace Medical Research Laboratories (U.S.) (page images at HathiTrust)

Filed under: Wave guides

Applications of waveguide and circuit theory to the development of accurate microwave measurement methods and standards (U.S. Dept. of Commerce, National Bureau of Standards ;, 1973), by Robert William Beatty (page images at HathiTrust)
Mechanical waveguides; the propagation of acoustic and ultrasonic waves in fluids and solids with boundaries. (Pergamon Press, 1960), by Martin Redwood (page images at HathiTrust)
Microwave impedance measurements and standards (U.S. Dept. of Commerce, National Bureau of Standards :, 1965), by Robert William Beatty and United States. National Bureau of Standards (page images at HathiTrust)
An introduction to the description and evaluation of microwave systems using terminal invariant parameters. (For sale by the Supt. of Docs., U.S. Govt. Print. Off., 1969), by Glenn F. Engen (page images at HathiTrust; US access only)
Mode conversion in the earth-ionosphere waveguide (U.S. Dept. of Commerce, National Bureau of Standards :, 1962), by James R. Wait (page images at HathiTrust)
Table of attenuation error as a function of vane-angle error for rotary vane attenuators (for sale by the Supt. of Docs., U.S Govt. Print. Off., 1963), by Wilbur Larson and Radio Standards Laboratory (U.S.) (page images at HathiTrust)
Operator methods in electromagnetic field theory (Microwave Research Institute, Polytechnic Institute of Brooklyn, 1957), by A. D. Bresler (page images at HathiTrust)
Waveguide handbook (McGraw-Hill, 1951), by Nathan Marcuvitz (page images at HathiTrust)
Electroforming of waveguide components for the millimeter-wavelength range (U.S. Dept. of Commerce, National Bureau of Standards, 1957), by Albert A. Feldmann and United States. National Bureau of Standards (page images at HathiTrust)
Calculated and measured S11, S21, and group delay for simple types of coaxial and rectangular waveguide 2-port standards (U.S. Dept. of Commerce, National Bureau of Standards :, 1974), by Robert William Beatty (page images at HathiTrust)
A method for designing multi-screw waveguide tuners (U.S. National Bureau of Standards :, 1970), by Manly P. Weidman and E. Campbell (page images at HathiTrust)
A broadband noncontacting sliding short (U.S. National Bureau of Standards :, 1971), by Wilbur Larson and Ronald D. Hunter (page images at HathiTrust)
WR15 thermal noise standard (U.S. Dept. of Commerce, National Bureau of Standards, 1972), by W. C. Daywitt, E. Campbell, W. J. Foot, Institute for Basic Standards (U.S.). Electromagnetics Division, and United States. National Bureau of Standards (page images at HathiTrust)
Field displacement effects in dielectric and ferrite loaded waveguides. (Gordon McKay Laboratory of Applied Science, Harvard University], 1959), by Thomas Michael Straus (page images at HathiTrust)
Circuit properties of dispersive coupled transmission lines and waveguides. ([Ithaca, N. Y.], 1971), by David F. Noble (page images at HathiTrust)
Rotary-vane attenuators (U.S. Dept. of Commerce, National Bureau of Standards ;, 1965), by Wilbur Larson, Radio Standards Laboratory (U.S.), and United States. National Bureau of Standards (page images at HathiTrust)
Wave propagation in continuously loaded waveguides. [Part I], Conditions for propagation of pure electric and magnetic wave types in a cylindrical system containing dielectric or magnetic boundaries (University of California Radiation Laboratory, 1955), by J. F. Waddell and Lawrence Radiation Laboratory (page images at HathiTrust)
A generalized network formulation for aperture problems (Air Force Cambridge Research Laboratories, Air Force Systems Command. U.S. Air Force, 1975), by Roger F. Harrington and Joseph R Mautz (page images at HathiTrust)
Microwaves and wave guides. ([Washington], 1954), by United States Department of the Navy Bureau of Ships (page images at HathiTrust)
Topics in the optimization of millimeter-wave mixers (National Aeronautics and Space Administration, Scientific and Technical Information Branch ;, 1984), by Peter H. Siegel, Wei Hwang, and Anthony R. Kerr (page images at HathiTrust)
The TE01 mode reflection coefficient of a ground-plane mounted parallel-plate waveguide illuminating a reflecting sheet (National Aeronautics and Space Administration ;, 1969), by L. L. Tsai, R. C. Rudduck, Ohio State University, and Langley Research Center (page images at HathiTrust)
Effects of dielectric covers over shunt slots in a waveguide (National Aeronautics and Space Administration :, 1964), by W. F. Croswell, Robert B. Higgins, and Langley Research Center (page images at HathiTrust)
Reduction of mutual coupling using perfectly conducting fences. (National Aeronautics and Space Administration :, 1971), by R. J. Mailloux, Electronics Research Center, and United States National Aeronautics and Space Administration (page images at HathiTrust)
Effects of dielectric covers over cross slots in a rectangular waveguide (National Aeronautics and Space Administration ;, 1967), by Marion Crawford Bailey and Langley Research Center (page images at HathiTrust)
NASA TN D-5180 (National Aeronautics and Space Administration ;, 1969), by Robert J. Mailloux, Electronics Research Center (U.S.), and United States National Aeronautics and Space Administration (page images at HathiTrust)
Telecommunications via certain guided wave structures (U.S. Dept. of Commerce, Office of Telecommunications, 1973), by R. L. Gallawa (page images at HathiTrust)
An engineering feasibility study of communications via a subterranean waveguide (U.S. Dept. of Commerce, Office of Telecommunications, 1972), by R. L. Gallawa and L. L. Haidle (page images at HathiTrust)
Numerical analysis of the eigenvalue problem of waves in cylindrical waveguides (University of Illinois, 1960), by Chien-hui T'ang, Yüan-chih Lo, and Electrical Engineering Research Laboratory University of Illinois at Urbana-Champaign : Antenna Laboratory (page images at HathiTrust)
Phase velocities in rectangular waveguide partially filled with dielectric (University of Illinois, 1957), by Walter L. Weeks and Electrical Engineering Research Laboratory University of Illinois at Urbana-Champaign : Antenna Laboratory (page images at HathiTrust)
Coupled waveguide excitation of traveling wave slot antennas (University of Illinois, 1957), by Walter L. Weeks and Electrical Engineering Research Laboratory University of Illinois at Urbana-Champaign : Antenna Laboratory (page images at HathiTrust)
Excitation of a surface wave on a dielectric cylinder (University of Illinois, 1958), by James Wilbur Duncan and Electrical Engineering Research Laboratory University of Illinois at Urbana-Champaign : Antenna Laboratory (page images at HathiTrust)
The excitation of a resonant cavity by waveguides of small cross-sectional dimensions (Midwestern Universities Research Association, 1962), by J. van Bladel, U.S. Atomic Energy Commission, and Midwestern Universities Research Association (page images at HathiTrust)
The excitation of a circular cylindrical cavity by a circular waveguide (Midwestern Universities Research Association, 1962), by C. Bjerke, J. van Bladel, U.S. Atomic Energy Commission, and Midwestern Universities Research Association (page images at HathiTrust)
The unbalanced line directional coupler (Sandia Corporation ;, 1961), by J. L. Allen and Sandia Corporation (page images at HathiTrust)
Shower development and heating in the waveguide structure with an 800 Mev electron beam (Stanford, California : Stanford University : Washington, D.C. : Office of Technical Services, Department of Commerce, 1962., 1962), by J. K. Cobb, J. J. Muray, Stanford Linear Accelerator Center, Stanford University, and U.S. Atomic Energy Commission (page images at HathiTrust)
Leaky wave radiation from a periodically slotted waveguide (Polytechnic Institute of Brooklyn, Microwave Research Institute, 1963), by Jean-Paul Renault, Air Force Cambridge Research Laboratories (U.S.), and Polytechnic Institute of Brooklyn. Microwave Research Institute (page images at HathiTrust)
Measurement of noise figure of a X-Band waveguide mixer with tunnel diode (L.G. Hanscom Field, Massachusetts : Air Force Cambridge Research Laboratories, Office of Aerospace Research, United States Air Force, 1964., 1964), by Gustav H. Blaeser and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Investigation of the element pattern in cylindrical phased arrays of circular waveguides (Bedford, Massachusetts : Raytheon Company, Missile Systems Division, Bedford Laboratories, Hartwell Road, 1972., 1972), by Quirino Balzano, Air Force Cambridge Research Laboratories (U.S.), and Raytheon Company (page images at HathiTrust)
Axial slot arrays on a circular cylinder for use on electrically small vehicles (The University of Michigan, Radiation Laboratory, Department of Electrical and Computer Engineering, 1975), by Dipak L. Sengupta, Joseph E. Ferris, University of Michigan. Department of Electrical and Computer Engineering. Radiation Laboratory, and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Ultra-Wideband Phased Arrays (Air Force Cambridge Research Laboratories, Air Force Systems Command, United States Air Force, 1973), by Chao Chun Chen, R. Tang, N. S. Wong, Air Force Cambridge Research Laboratories (U.S.), and Hughes Aircraft Company. Research Laboratories (page images at HathiTrust)
Wave guides with nonideal walls (Oak Ridge, Tennessee : United States Atomic Energy Commission, Technical Information Service, 1953., 1953), by B. Z. Kat︠s︡enelenbaum, U.S. Atomic Energy Commission, and National Science Foundation (U.S.) (page images at HathiTrust)
Passive radiating systems in wave-guides (Oak Ridge, Tennessee : U.S. Atomic Energy Commission, Technical Information Service, 1954., 1954), by M. L. Levin, U.S. Atomic Energy Commission, and National Science Foundation (U.S.) (page images at HathiTrust)
Calculated mode conversion coefficients for graded height change in the earth-ionosphere waveguide at VLF (Boulder, Colo. : ESSA Research Laboratories, Office of the Director, 1968., 1968), by Kenneth P. Spies, James R. Wait, and United States. Environmental Science Services Administration. Research Laboratories (page images at HathiTrust)
Very low frequency mode calculations for propagation across a land/sea boundary in the earth-ionosphere waveguide (Boulder, Colo. : ESSA Research Laboratories, Office of the Director, 1968., 1968), by James R. Wait, K. P. Spies, and United States. Environmental Science Services Administration. Research Laboratories (page images at HathiTrust)
Operator's manual for waveform generator, model RPG-6236-A (National Highway Traffic Safety Administration ;, 1988), by Transportation Systems Center, MGA Research Corporation, and United States. National Highway Traffic Safety Administration (page images at HathiTrust)
The dielectric and wire grid transmission line (L.G. Hansom Field, Bedford, Massachusetts : Air Force Cambridge Research Laboratories, Office of Aerospace Research, United States Air Force, 1964., 1964), by Otho E. Kerr and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
An experimental study of simulated plasma-covered slots (L. G. Hansom Field, Bedford, Massachusetts : Air Force Cambridge Research Laboratories, Office of Aerospace Research, United States Air Force, 1968., 1968), by N. V. Karas, J. D. Antonucci, and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Electron reduction in the reentry plasma sheath (L.G. Hansom Field, Bedford, Massachusetts : Air Force Cambridge Research Laboratories, Office of Aerospace Research, United States Air Force, 1969., 1969), by Daniel J. Jacavanco and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Surface and anomolous waves on phased arrays of TEM waveguides with fences (L.G. Hansom Field, Bedford, Massachusetts : Air Force Cambridge Research Laboratories, Office of Aerospace Research, United States Air Force, 1971., 1971), by Robert J. Mailloux and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Analysis of circular waveguide arrays on cylinders (Air Force Cambridge Research Laboratories, Air Force Systems Command, United States Air Force, 1974), by Hans Steyskal and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
Change in reflection coefficient induced by a spot on the surface of a dielectric inside a rectangular waveguide (L.G. Hanscom Field, Massachusetts : Air Force Cambridge Research Laboratories, Air Force Systems Command, United States Air Force, 1973., 1973), by Ronald L. Fante and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
A lightweight, low-profile antenna for airborne station-keeping application (L.G. Hanscom Field, Massachusetts : Air Force Cambridge Research Laboratories, Air Force Systems Command, United States Air Force, 1973., 1973), by William G. Mavroides, Robert J. Mailloux, Raymond A. Schofield, and Air Force Cambridge Research Laboratories (U.S.) (page images at HathiTrust)
The precision measurement of the equivalent circuit parameters of dissipative microwave structures (Electronics Research Directorate, Air Force Cambridge Research Center, 1953), by L. B. Felsen, Arthur A. Oliner, and United States. Air Force. Electronics Research Directorate (page images at HathiTrust; US access only)
Theory of thin dielectric cover on slitted rectangular waveguide antenna (Microwave Research Institute, Polytechnic Institute of Brooklyn, 1959), by S. Nishida, Polytechnic Institute of Brooklyn. Microwave Research Institute, and Air Force Cambridge Research Center (U.S.) (page images at HathiTrust)
The variational method for evaluation of scattering of electromagnetic waves by obstacles. I, Theory (Dept. of Electrical Engineering, College of Engineering, University of Washington, 1960), by Richard B. Kieburtz, Gedalia Held, Akira Ishimaru, University of Washington. Department of Electrical Engineering, United States. Air Force. Research Division, and Air Force Cambridge Research Laboratories (U.S.). Electronics Research Directorate (page images at HathiTrust)

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