Time-Domain Electromagnetic Reciprocity in Antenna Modeling [electronic resource] /
Martin Štumpf.
- Hoboken : Wiley, c2020.
- 1 online resource (249 p.).
- IEEE Press Series on Electromagnetic Wave Theory .
- IEEE Press series on electromagnetic wave theory. .
Description based upon print version of record. 14.5 EXTENSION TO A WIDE-STRIP ANTENNA
Includes bibliographical references and index.
Intro; TITLE PAGE; COPYRIGHT PAGE; CONTENTS; PREFACE; ACRONYMS; CHAPTER 1 INTRODUCTION; 1.1 SYNOPSIS; 1.2 PREREQUISITES; 1.2.1 One-Sided Laplace Transformation; 1.2.2 Lorentz's Reciprocity Theorem; CHAPTER 2 CAGNIARD-DEHOOP METHOD OF MOMENTS FOR THIN-WIRE ANTENNAS; 2.1 PROBLEM DESCRIPTION; 2.2 PROBLEM FORMULATION; 2.3 PROBLEM SOLUTION; 2.4 ANTENNA EXCITATION; 2.4.1 Plane-Wave Excitation; 2.4.2 Delta-Gap Excitation; ILLUSTRATIVE EXAMPLE; CHAPTER 3 PULSED EM MUTUAL COUPLING BETWEEN PARALLEL WIRE ANTENNAS; 3.1 PROBLEM DESCRIPTION; 3.2 PROBLEM FORMULATION; 3.3 PROBLEM SOLUTION CHAPTER 4 INCORPORATING WIRE-ANTENNA LOSSES4.1 MODIFICATION OF THE IMPEDANCE MATRIX; CHAPTER 5 CONNECTING A LUMPED ELEMENT TO THE WIRE ANTENNA; 5.1 MODIFICATION OF THE IMPEDANCE MATRIX; CHAPTER 6 PULSED EM RADIATION FROM A STRAIGHT WIRE ANTENNA; 6.1 PROBLEM DESCRIPTION; 6.2 SOURCE-TYPE REPRESENTATIONS FOR THE TD RADIATED EM FIELDS; 6.3 FAR-FIELD TD RADIATION CHARACTERISTICS; CHAPTER 7 EM RECIPROCITY BASED CALCULATION OF TD RADIATION CHARACTERISTICS; 7.1 PROBLEM DESCRIPTION; 7.2 PROBLEM SOLUTION; ILLUSTRATIVE NUMERICAL EXAMPLE CHAPTER 8 INFLUENCE OF A WIRE SCATTERER ON A TRANSMITTING WIRE ANTENNA8.1 PROBLEM DESCRIPTION; 8.2 PROBLEM SOLUTION; ILLUSTRATIVE NUMERICAL EXAMPLE; CHAPTER 9 INFLUENCE OF A LUMPED LOAD ON EM SCATTERING OF A RECEIVING WIRE ANTENNA; 9.1 PROBLEM DESCRIPTION; 9.2 PROBLEM SOLUTION; ILLUSTRATIVE NUMERICAL EXAMPLE; CHAPTER 10 INFLUENCE OF A WIRE SCATTERER ON A RECEIVING WIRE ANTENNA; 10.1 PROBLEM DESCRIPTION; 10.2 PROBLEM SOLUTION; ILLUSTRATIVE NUMERICAL EXAMPLE; CHAPTER 11 EM-FIELD COUPLING TO TRANSMISSION LINES; 11.1 INTRODUCTION; 11.2 PROBLEM DESCRIPTION; 11.3 EM-FIELD-TO-LINE INTERACTION 11.4 RELATION TO AGRAWAL COUPLING MODEL11.5 ALTERNATIVE COUPLING MODELS BASED ON EM RECIPROCITY; 11.5.1 EM Plane-Wave Incidence; 11.5.2 Known EM Source Distribution; CHAPTER 12 EM PLANE-WAVE INDUCED THEV́ENIN'S VOLTAGE ON TRANSMISSION LINES; 12.1 TRANSMISSION LINE ABOVE THE PERFECT GROUND; 12.1.1 Thévenin's Voltage at x = x1; 12.1.2 Thévenin's Voltage at x = x2; 12.2 NARROW TRACE ON A GROUNDED SLAB; 12.2.1 Thévenin's Voltage at x = x1; 12.2.2 Thévenin's Voltage at x = x2; ILLUSTRATIVE NUMERICAL EXAMPLE; CHAPTER 13 VED-INDUCED THEV́ENIN'S VOLTAGE ON TRANSMISSION LINES 13.1 TRANSMISSION LINE ABOVE THE PERFECT GROUND13.1.1 Excitation EM Fields; 13.1.2 Thévenin's Voltage at x = x1; 13.1.3 Thévenin's Voltage at x = x2; 13.2 INFLUENCE OF FINITE GROUND CONDUCTIVITY; 13.2.1 Excitation EM Fields; 13.2.2 Correction to Thévenin's Voltage at x = x1; 13.2.3 Correction to Thévenin's Voltage at x = x2; ILLUSTRATIVE NUMERICAL EXAMPLE; CHAPTER 14 CAGNIARD-DEHOOP METHOD OF MOMENTS FOR PLANAR-STRIP ANTENNAS; 14.1 PROBLEM DESCRIPTION; 14.2 PROBLEM FORMULATION; 14.3 PROBLEM SOLUTION; 14.4 ANTENNA EXCITATION; 14.4.1 Plane-Wave Excitation; 14.4.2 Delta-Gap Excitation