Wu, Zuan Hui.
Generalized Transmission Line Method to Study the Far-zone Radiation of Antennas Under a Multilayer Structure [electronic resource] / by Zuan Hui Wu, Ahmed A. Kishk, Allen W. Glisson. - 1st ed. 2008. - IX, 86 p. online resource. - Synthesis Lectures on Antennas, 1932-6084 . - Synthesis Lectures on Antennas, .
Antennas Under a Multilayer Dielectric Slab -- Antennas Under a Polarized Multilayer Structure -- Hertzian Dipole Model for an Antenna -- Bibliography -- Biography.
This book gives a step-by-step presentation of a generalized transmission line method to study the far-zone radiation of antennas under a multilayer structure. Normally, a radiation problem requires a full wave analysis which may be time consuming. The beauty of the generalized transmission line method is that it transforms the radiation problem for a specific type of structure, say the multilayer structure excited by an antenna, into a circuit problem that can be efficiently analyzed. Using the Reciprocity Theorem and far-field approximation, the method computes the far-zone radiation due to a Hertzian dipole within a multilayer structure by solving an equivalent transmission line circuit. Since an antenna can be modeled as a set of Hertzian dipoles, the method could be used to predict the far-zone radiation of an antenna under a multilayer structure. The analytical expression for the far-zone field is derived for a structure with or without a polarizer. The procedure of obtaining the Hertzian dipole model that is required by the generalized transmission line method is also described. Several examples are given to demonstrate the capabilities, accuracy, and efficiency of this method. Table of Contents: Antennas Under a Multilayer Dielectric Slab / Antennas Under a Polarized Multilayer Structure / Hertzian Dipole Model for an Antenna / Bibliography / Biography.
9783031015380
10.1007/978-3-031-01538-0 doi
Engineering.
Electrical engineering.
Telecommunication.
Technology and Engineering.
Electrical and Electronic Engineering.
Microwaves, RF Engineering and Optical Communications.
T1-995
620
Generalized Transmission Line Method to Study the Far-zone Radiation of Antennas Under a Multilayer Structure [electronic resource] / by Zuan Hui Wu, Ahmed A. Kishk, Allen W. Glisson. - 1st ed. 2008. - IX, 86 p. online resource. - Synthesis Lectures on Antennas, 1932-6084 . - Synthesis Lectures on Antennas, .
Antennas Under a Multilayer Dielectric Slab -- Antennas Under a Polarized Multilayer Structure -- Hertzian Dipole Model for an Antenna -- Bibliography -- Biography.
This book gives a step-by-step presentation of a generalized transmission line method to study the far-zone radiation of antennas under a multilayer structure. Normally, a radiation problem requires a full wave analysis which may be time consuming. The beauty of the generalized transmission line method is that it transforms the radiation problem for a specific type of structure, say the multilayer structure excited by an antenna, into a circuit problem that can be efficiently analyzed. Using the Reciprocity Theorem and far-field approximation, the method computes the far-zone radiation due to a Hertzian dipole within a multilayer structure by solving an equivalent transmission line circuit. Since an antenna can be modeled as a set of Hertzian dipoles, the method could be used to predict the far-zone radiation of an antenna under a multilayer structure. The analytical expression for the far-zone field is derived for a structure with or without a polarizer. The procedure of obtaining the Hertzian dipole model that is required by the generalized transmission line method is also described. Several examples are given to demonstrate the capabilities, accuracy, and efficiency of this method. Table of Contents: Antennas Under a Multilayer Dielectric Slab / Antennas Under a Polarized Multilayer Structure / Hertzian Dipole Model for an Antenna / Bibliography / Biography.
9783031015380
10.1007/978-3-031-01538-0 doi
Engineering.
Electrical engineering.
Telecommunication.
Technology and Engineering.
Electrical and Electronic Engineering.
Microwaves, RF Engineering and Optical Communications.
T1-995
620