Yuriy M. Penkin; Victor A. Katrich; Mikhail V. Nesterenko; Sergey L. Berdnik; Victor M. Dakhov Springer International Publishing AG (2018) Kovakantinen kirja
Yuriy M. Penkin; Victor A. Katrich; Mikhail V. Nesterenko; Sergey L. Berdnik; Victor M. Dakhov Springer Nature Switzerland AG (2019) Pehmeäkantinen kirja
Mikhail V. Nesterenko; Victor A. Katrich; Yuriy M. Penkin; Victor M. Dakhov; Sergey L. Berdnik Springer-Verlag New York Inc. (2014) Pehmeäkantinen kirja
This book discusses the problem of electromagnetic wave excitation in spatial regions with spherical boundaries and the accurate mathematical modeling based on numerical and analytical methods to significantly reduce the time required for developing new antenna devices. It particularly focuses on elements and systems on mobile objects of complex shape that are made of new technological materials. The experimental development of such devices and systems is an extremely time-consuming, lengthy, and expensive process. The book is intended for senior and postgraduate students and researchers working in the fields of radiophysics, radio engineering and antenna design. The authors assume that readers understand the basics of vector and tensor analysis, as well as the general theory of electrodynamics. The original results presented can be directly used in the development of spherical antennas and antenna systems for the mobile objects.
The book addresses problems concerning the construction of Green’s functions for Hertz potentials in electrodynamic volumes with spherical boundaries, and solves these clearly and concisely. It also uses specific examples to analyze areas where the results could potentially be applied. The book covers the following topics:
· excitation of electromagnetic fields in coordinate electrodynamic volumes;
· Green’s functions for spherical resonators;
· Green’s functions for infinite space outside of spherical scatterers;
· electromagnetic fields of dipole radiators on spherical scatterers;
· electromagnetic fields of thin radial impedance vibrators on perfectly conducting spheres;
· electrodynamic characteristics of narrow slots in spherical surfaces;
· multi-element and combined vibrator-slot radiators on spherical surfaces.