Development of complex electromagnetic problems using FDTD subgridding in hybrid computational techniques / Khairan N. Ramli, Raed A. Abd-Alhameed, and Peter S. Excell, editors.

Includes bibliographical references and index.

Description based on print version record and CIP data provided by publisher.

""DEVELOPMENT OF COMPLEX ELECTROMAGNETIC PROBLEMS USING FDTD SUBGRIDDING IN HYBRID COMPUTATIONALTECHNIQUES""; ""DEVELOPMENT OF COMPLEX ELECTROMAGNETIC PROBLEMS USING FDTD SUBGRIDDING IN HYBRID COMPUTATIONALTECHNIQUES""; ""Library of Congress Cataloging-in-Publication Data""; ""CONTENTS""; ""PREFACE""; ""Chapter 1: NUMERICAL SOLUTION OF MAXWELL EQUATIONS USING FDTD AND MOM""; ""ABSTRACT""; ""1.1. BACKGROUND AND MOTIVATIONS""; ""1.2. HISTORY OF FDTD""; ""1.3. HISTORY OF MOM""; ""1.4. STATE OF ART OF THE ORIGINAL CONTRIBUTION""; ""1.5. OVERVIEW OF THE BOOK""; ""REFERENCES""

""Chapter 2: FDTD TECHNIQUE FOR FIELD TRUNCATION""""2.1. INTRODUCTION""; ""2.2. FDTD UPDATING STENCILS""; ""2.3. NUMERICAL DISPERSION""; ""2.4. INCIDENT WAVE SOURCE CONDITIONS""; ""2.5. ABSORBING BOUNDARY CONDITIONS (ABC)""; ""CONCLUSION""; ""REFERENCES""; ""Chapter 3: SURFACE KERNEL SOLUTION OF THE METHOD OF MOMENTS""; ""ABSTRACT""; ""3.1. INTRODUCTION""; ""3.2.MAXWELL�S EQUATIONS""; ""3.3.MOMENT METHOD""; ""3.4. ONE-DIMENSIONAL ANTENNAS""; ""3.5. TWO-DIMENSIONAL ANTENNAS""; ""3.6. THREE-DIMENSIONAL ANTENNAS""; ""3.7. NORMAL-MODE HELICAL ANTENNA""; ""3.8. SURFACE CURRENT FORMULATION""

""3.9. EVALUATION OF IMPEDANCE MATRIX ELEMENTS""""3.10. SOLUTION FOR SINGULARITY""; ""3.11. SIMULATION AND RESULTS""; ""CONCLUSION""; ""REFERENCES""; ""APPENDIX A""; ""APPENDIX B""; ""Chapter 4: QUASI-STATIC FINITE-DIFFERENCE TIME-DOMAIN SUBGRIDDING TECHNIQUE""; ""ABSTRACT""; ""4.1. INTRODUCTION""; ""4.2. QUASI-STATIC THEOREM""; ""4.3. VALIDATION OF SUBGRIDDING METHOD""; ""4.4. INTERACTION BETWEEN OHTL AND BURIED PIPELINE""; ""4.5. NEAR FIELD SIMULATION""; ""CONCLUSION""; ""REFERENCES""; ""Chapter 5: EFFECT OF ANISOTROPIC MAGNETO-CHIRALITY ON MICROSTRIP RESONATOR CHARACTERISTICS""

""ABSTRACT""""5.1. INTRODUCTION""; ""5.2. THEORETICAL FORMULATION""; ""5.3. GREEN�S TENSOR EVALUATION""; ""5.4. INTEGRAL EQUATION SOLUTION""; ""5.5. HALF-POWER BANDWIDTH""; ""5.6. SURFACE WAVES INVESTIGATION""; ""5.7. COMPLEX MEDIA PARAMETER EFFECT ON THE INPUT IMPEDANCE""; ""5.8. RECTANGULAR MICROSTRIP ANTENNA WITH UNIAXIAL BIANISOTROPIC CHIRAL SUBSTRATE-SUPERSTRATE""; ""5.9. ASYMMETRICAL EFFECTS OF BIANISOTROPIC SUBSTRATE-SUPERSTRATE SANDWICH STRUCTURE""; ""CONCLUSION""; ""REFERENCES""; ""Chapter 6: INTERACTION OF EMFIELDS TO THE HUMAN BODY USING HYBRID COMPUTATIONAL METHOD""

""ABSTRACT""""6.1. INTRODUCTION""; ""6.2. HYBRID MOM-FDTD-SGFDTD THEORETICAL FORMULATION""; ""6.3. VALIDATION OF RADIATED FIELD""; ""6.4. HYBRID MODEL TECHNIQUE""; ""CONCLUSION""; ""REFERENCES""; ""Chapter 7: QUASI-STATIC FDTD SCHEME FOR ELECTRICALLY-SMALL REGIONS IN FREE SPACE, LOSSLESS AND LOSSY PENETRABLE MEDIA""; ""7.1. INTRODUCTION""; ""7.2. ANALYTICAL SOLUTION""; ""7.3.MODIFIED BERENGER�S PML""; ""7.4. VERIFICATION METHOD""; ""CONCLUSION""; ""REFERENCES""; ""Chapter 8: COMPUTATION OF ELECTROMAGNETIC FIELD INSIDE A TISSUE USING QUASI-STATIC AND LUMPED-ELEMENT FDTD SCHEME""

Complex electromagnetic problems using new hybridised computational techniques combining the frequency domain Method of Moments (MoM), Finite-Difference Time-Domain (FDTD) and a subgridded Finite-Difference Time-Domain (SGFDTD) method are studied and discussed in detail. The techniques are desirable to predict electromagnetic absorption in inhomogeneous, anisotropic and lossy dielectric materials irradiated by geometrically intricate sources. In Method of Moments modelling, the surface kernel solution is derived for 1-D, 2-D and 3-D. The electric surface patch integral formulation is solved by.

Master record variable field(s) change: 050, 082