The Finite Difference Time Domain Method for Electromagnetics

Bibliographic Details
Main Author:	Kunz, KarlS
Corporate Author:	Taylor & Francis
Other Authors:	Luebbers, Raymond J.
Format:	eBook
Language:	English
Published:	Boca Raton : Routledge, 2018.
Subjects:	Electromagnetic fields > Mathematics. Time-domain analysis. Electronic books.
Online Access:	Connect to the full text of this electronic book

Table of Contents:

Cover; Title Page; Copyright Page; Table of Contents; Chapter 1: Introduction; Part 1: Fundamental Concepts; Chapter 2: Scattered Field FDTD Formulation; 2.1 Maxwell Curl Equations; 2.2 Separate Field Formalism; 2.3 Perfect Conductor FDTD Formulation; 2.4 Perfect Conductor FDTD FORTRAN Code; 2.5 Lossy Material Formulation; 2.6 Lossy Dielectric FDTD FORTRAN Code; 2.7 FDTD Code Requirements and Architecture; References; Chapter 3: FDTD Basics; 3.1 Introduction; 3.2 Determining the Cell Size; 3.3 Time Step Size for Stability; 3.4 Specifying the Incident Field; 3.5 Building an Object in Yee Cells
3.6 Direct Computation of Total Fields3.7 Radiation Boundary Condition; 3.8 Resource Requirements; References; Part 2: Basic Applications; Chapter 4: Coupling; 4.1 Introduction; 4.2 Electromagnetic Pulse; 4.3 Exterior Pulse Response; 4.3.1 Measurement; 4.3.2 FDTD Model of the; 4.3.3 Comparison of Predictions and Measurements; 4.4 Interior Electromagnetic Shielding; 4.4.1 Frequencies Above Aperture; 4.4.2 Frequencies Below Aperture; References; Chapter 5: Waveguide Aperture Coupling (Article by P. Alinikula and K.S. Kunz); 5.1 Introduction; 5.2 Approach; 5.3 Results; 5.4 Conclusion
AcknowledgmentReferences; Chapter 6: Lossy Dielectric Scattering; 6.1 Introduction; 6.2 Interpretation of the Scattered Field Method; 6.3 Near Zone Sphere Scattering; 6.3.1 Incident Field; 6.3.2 Special Notes; 6.3.3 Predictions; 6.4 Human Body Absorption; References; Part 3: Special Capabilities; Chapter 7: Far Zone; 7.1 Introduction; 7.2 Three-Dimensional Transformation; 7.3 Two-Dimensional Transformation; 7.4 Summary; References; Chapter 8: Frequency-Dependent Materials; 8.1 Introduction; 8.2 First Order Debye Dispersion; 8.3 First Order Drude Dispersion
8.4 Second Order Dispersive Materials8.5 Multiple Poles; 8.6 Differential Method; 8.7 Scattered Field Formulation; References; Chapter 9: Surface Impedance; 9.1 Introduction; 9.2 Constant Parameter Materials; 9.3 Frequency-Dependent Materials; 9.4 Recursive Evaluation; 9.5 Demonstrations; References; Chapter 10: Subcellular; 10.1 Introduction; 10.2 Integration Contours; 10.3 Thin Wires; 10.4 Lumped Circuit Elements; 10.5 Expansion Techniques; 10.6 Code Requirements, Limitations, and Utility; References; Chapter 11: Nonlinear Loads and Materials; 11.1 Introduction
11.2 Antenna with Nonlinear Diode11.3 Nonlinear Magnetic Sheet; References; Chapter 12: Visualization; 12.1 Introduction; 12.2 Types of Visualization; 12.3 Examples; 12.3.1 Model Fidelity; 12.3.2 Model Response; 12.3.3 Physical Process Insight; 12.3.4 Intuition Building; 12.4 Resources and Cost of Visualization; References; Part 4: Advanced Applications; Chapter 13: Far Zone Scattering; 13.1 Introduction; 13.2 Fundamentals; 13.3 Staircase Errors; 13.4 Impedance Sheets; 13.5 Distance to Outer Boundary; 13.6 Frequency-Dependent Materials; References; Chapter 14: Antennas; 14.1 Introduction