DOU WEN BIN SUN ZHONG LIANG WU HONG CHAO HU SHU XIN DENG (1 resultados)

Hardcover. Condición: New. Ship out in 2 business day, And Fast shipping, Free Tracking number will be provided after the shipment.Hardcover. pub Date: 2013 Pages: 280 Publisher: National Defense Industry Press ferrite devices are widely used in the millimeter-wave engineering components. Frequency much higher than the microwave band. the ferrite material parameters saturation magnetization can not be a corresponding increase in the case of need for a new approach to the design ferrite devices and the development of a new type of ferrite devices. Millimeter wave ferrite devices Theory and Technology (2nd Edition) divided into 11 chapters. introduced ferrite spin magnetic waveguide junction circulator. a variety of integration junction circulator. waveguide Faraday rotation devices and quasi-optical Faraday rotation devices. distributed non-reciprocal devices; ferrite loaded transmission line theory and technology of magnetic transfer device and antenna and scattering. Waveguide junction circulator and the microstrip junction circulator is given a rigorous treatment. elaborate on taking circulator ring when field structure and the corresponding external characteristics. which clearly describes the working mechanism of the circulator. The book basically reflects at home and abroad over the past decade in the progress of research in this area. The book is available in electromagnetic field and microwave technology. Physical Electronics and devices and radar. and other professional engineering and technical personnel to read. but also as institutions of higher learning relevant professional graduate and undergraduate reference books. Contents: Chapter I ferrite spin of 1.2 arbitrary direction of magnetization of the magnetic 1.1 permeability tensor permeability tensor 1.3 ferrite materials refer to the literature Chapter II of electromagnetic wave propagation and electromagnetic field equations for the limitations of the millimeter-wave band electromagnetic waves 2.1 the spread in the infinite ferrite medium ferrite medium electromagnetic field equations References Chapter waveguide Y-junction circulator 3.1 Y junction circulator of network theory. the 3.2 H surface waveguide Y-junction circulator field theory 3.3 2.2 waveguide bend head 3.4 Central line performance of high power waveguide junction ring line is 3.5 w band knot ring line is - higher-order-mode concept and application of 3.6 full height ferrite junction circulator 3.7 levy mode. knot resonant mode and their characteristics and applications 3.8 games Figure 3.9 E surface waveguide junction circulator 3.10 waveguide junction circulator structure and theoretical treatment References Chapter irregular analysis 4.1 Maxwell's equations in the FDTD method to derive 4.2 ferrite ferrite waveguide junction circulator finite difference time domain method body FDTD 4.3 excitation source settings 4.4 absorbing boundary conditions set 4.5 numerical analysis results 4.6 Conclusion References Chapter irregular ferrite waveguide junction circulator finite element analysis of 5.1 based on Helmholtz equation weak form 5.2 method of the basic principles of finite element and mode expand the combined method validation 5.3 circulator junction field structure 5.4 w band circulator dual-mode ring line of experimental verification reference literature Chapter other Y-junction circulator 6.1 microstrip ring line is 6.2 Section 7.1 of Chapter VII of the strip line circulator 6.3 fin line Y-junction circulator 6.4 non-radiative dielectric waveguide circulator Reference Faraday rotation device filled with longitudinal magnetization ferrite irregular waveguide 7.2 quasi-optical circulator and isolator 7.3 Summary References Chapter VIII distributed non-reciprocal devices the 8.1 coupled mode theory 8.2 distributed non-reciprocal easy to structure the network theory 8.3 distributed non-reciprocal devices to achieve References Chapter ferrite loaded transmission line 9.1 mode-s 9.2 transfer matrix method 9.3 phase shifters.