Microwave theory

R. Edgar and R. Snider, in D. E. Clark and co-workers, eds.. Microwaves Theory and Application in Materials Processing, American Ceramics Society, Westerville, Ohio, 1991. [Pg.348]

A.J. Baden-Fuller, Microwaves An Introduction to Microwave Theory and Techniques, Pergamon Press, Oxford (1990). [Pg.164]

P. F. Goldsmith, C.-T. Hsieh, G. R. Huguenin, J. Kapitzky, and E. L. Moore. Focal Plane Imaging Systems for Millimeter Wavelengths , IEEE Trans. Microwave Theory and Techniques, Vol. 41, pp. 1664-1675, October 1993. [Pg.267]

Boriskina, S.V., Nosich, A.I., 1999, Radiation and absorption losses of the whispering-gallery-mode dielectric resonators excited by a dielectric waveguide, IEEE Trans. Microwave Theory Tech. 47 224-231. [Pg.62]

Gastine, M., Courtois, L., and Dormann, J.L., 1967, Electromagnetic resonances of free dielectric spheres, IEEE Trans. Microwave Theory Tech. 15(12) 694-700. [Pg.65]

Glisson, A.W., Kajfez, D., and James, J., 1983, Evaluation of modes in dielectric resonators using a surface integral-equation formulation, IEEE Trans. Microwave Theory Tech. 31(12) 1023-1029. [Pg.65]

P. Bienstman, H Derudder, R Baets, F Olyslager and D. De Zutter, Analysis of cylindrical waveguide discontinuities using vectorial eigenmodes and perfectly matched layers, TfiTiii Trans. Microwave Theory Tech. 49, 349-354 (2001). [Pg.99]

E. F. Kuester and D. C. Chang, Propagation, attenuation and dispersion characteristics of inhomogeneous dielectric slab waveguides, IEEE Trans Microwave Theory Tech. 23, 98-106 (1975). [Pg.99]

M. Koshiba, and K. Inoue, Simple and efficient finite-element analysis of microwave and optical waveguides, IEEE Transactions Microwave Theory Technology 40, 371-377 (1992). [Pg.276]

B. M. A. Rahman, and J. B. Davies, Penalty function improvement of waveguide solution by finite element, IEEE Transactions Microwave Theory and Techniques 32, 922-928 (1984). [Pg.279]

Bandler, J.W. IEEE Trans, on Microwave Theory Techn. 1969, MTT-17, 533. [Pg.217]

Figure 11.10 Theoretical power loss ratio for a sphere in a waveguide (upper curves) compared with measured transmission spectra (lower curves). The curves on the right are enlargements of the two bands the effect of absorption on the lowest frequency band is shown in the upper right. From P. Affolter and B. Eliasson, IEEE Trans. Microwave Theory Tech., MTT-21 (1973), 573-578 1973 IEEE.

Bates, R. H. T., 1975. Analytic constraints on electromagnetic field computations, IEEE Trans. Microwave Theory Tech., M iT-23, 605-623. [Pg.500]

Hippel 1954b). The values of e and e" were derived from microwave theory by placing a sample of material against the end of a short-circuited transmission line, such as a waveguide or a coaxial line. This technique has applicability to high and low loss materials and in the present day has found applicability for the measurement of powders, grains and pulses (Nelson 1972,1991). [Pg.220]

D. M. Sheen, D. L. McMakin, and T. E. Hall, Three-dimensional millimeter-wave imaging for concealed weapon detection, IEEE Transactions on Microwave Theory and Techniques, vol. 49, pp. 1581-1592, 2001. [Pg.275]

G. Chattopadhyay, E. Schlecht, I. S. Ward, I. I. Gill, H. H. S. lavadi, F. Maiwald, and I. Mehdi, An all-solid-state broad-band frequency multiplier chain at 1500 GHz, IEEE Transactions on Microwave Theory and Techniques, vol. 52, pp. 1538, 2004. [Pg.276]

Barnes, F. S. Hu, C. H. Model for some nonthermal effects of radio and microwave fields on biological membranes. IEEE Trans. Microwave Theory Tech. 1977, MTT-25, 742-746. [Pg.158]

MacGregor, R. J. A possible mechanism for the influence of electromagnetic radiation on neuroelectric potentials. IEEE Trans. Microwave Theory Tech. 1979, MTT-27, 914-921. [Pg.158]

Borth, D.E. and Cain, C.A., IEEE Trans. Microwave Theory... [Pg.330]

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