Multiresolution Time Domain Scheme for Electromagnetic Engineering Wiley Series in Microwave and Optical Engineering Series

Langue : Anglais

Auteurs : Chen Yinchao, Cao Qunsheng, Mittra Raj

Couverture de l’ouvrage Multiresolution Time Domain Scheme for Electromagnetic Engineering

Résumé
Sommaire
Biographie

Multiresolution Time Domain Scheme for Electromagnetic Engineering examines the multiresolution time domain (MRTD) scheme and shows how it can be used to satisfy a variety of technical needs. This comprehensive resource presents a combination of theoretically advanced mathematical topics and their application in time domain Maxwell solution techniques. These topics include concepts of signal space, the multiresolution analysis (MRA), and scaling and wavelet functions; construction of MRA families; interconnection among the MRTD, finite difference time domain (FDTD), and MoM; MRTD boundary truncations; MRTD plane wave incidence, near-to-far-field transform, and scattering analysis; MRTD applications on microwave and millimeter wave integrated circuits; and generalized differential matrix operators (GDMOs). This text offers an invaluable, stand-alone reference for scientists, engineers, and students in a wide range of fields.

Preface.

Acknowledgments.

1. Introduction.

1.1 Prologue.

1.2 Objectives.

1.3 Overview.

2. Introduction to the Multiresolution Analysis.

2.1 Introduction.

2.2 Vectors and Signal Space.

2.3 Multiresolution Analysis.

2.4 Scaling Functions and Wavelets.

2.5 MRA in the Frequency Domain.

2.6 Examples.

2.7 Biorthogonal MRA and Wavelets.

2.8 Multidimensional Wavelets.

2.9 Field Expansions in the MRTD Analysis.

3. MRA Families in MRTD Analysis.

3.1 Introduction.

3.2 Basic Spline MRA Family.

3.3 Battle–Lemari´e Spline MRA Family.

3.4 Cubic Spline Battle–Lemari´e MRA—An Example.

3.5 Daubechies’ Procedure of MRA Construction.

3.6 Daubechies’ Original Family.

3.7 Coiflet Family.

3.8 Biorthogonal MRA.

3.9 Biorthogonal Cohen–Daubechies–Feauveau Family.

4. Kernel of Multiresolution Time Domain Scheme.

4.1 Introduction.

4.2 Relationships Among the FDTD, MoM, and MRTD.

4.3 The MRTD Scheme.

4.4 Stability Criteria.

4.5 Computation of Total Fields.

4.6 Orthogonal and Integral Relations.

5. PEC Boundary Truncations.

5.1 Introduction.

5.2 Method of Analysis.

5.3 Numerical Results.

5.4 Conclusions.

6. Open Boundary Truncation.

6.1 Introduction.

6.2 MRTD Update Equations in APML Regions.

6.3 Numerical Results.

6.4 Conclusion.

7. One-Dimensional MRTD Analysis.

7.1 Introduction.

7.2 MRTD Formulations.

7.3 Application Results.

7.4 Conclusion.

8. Two-Dimensional MRTD Analysis.

8.1 Introduction.

8.2 MRTD Analysis for Printed Transmission Lines.

8.3 Application Results for Printed Transmission Lines.

8.4 MRTD Analysis for Parallel Waveguide Structures.

8.5 Application Results for Parallel-Waveguide Structures.

8.6 Conclusions.

References.

9. Three-Dimensional MRTD Analysis.

9.1 Introduction.

9.2 Method of Analysis.

9.3 Application Results.

9.4 Conclusions.

10. MRTD Analysis for MMICs.

10.1 Introduction.

10.2 Microwave Networks.

10.3 Extraction of MMIC Characteristics.

10.4 Application Results.

10.5 Conclusions.

11. MRTD Scattering Analysis: 2D Cases.

11.1 Introduction.

11.2 Scattering Fundamentals.

11.3 Governing Equations of MRTD.

11.4 MRTD Scattering Algorithm for TMz Wave.

11.5 MRTD Scattering Algorithm for TEz Wave.

11.6 Application Results.

11.7 Conclusions.

12. MRTD Scattering Analysis: 3D Cases.

12.1 Introduction.

12.2 Governing Equations of MRTD.

12.3 MRTD Implementations.

12.4 Application Results.

12.5 Conclusions.

APPENDIX A: Generalized Differential Matrix Operators.

A.1 Generalized Differential Matrix Operators.

A.2 GDMO Representation of Maxwell and Wave Equations.

A.3 GDMOs for Differential and Integral Formulations.

APPENDIX B: MRTD Orthogonal and Integral Relations.

B.1 Orthogonal and Integral Relations.

B.2 Orthogonal Relations.

B.3 Integral Relations of the Pulse Function.

B.4 Integral Relations for the Scaling Functions.

B.5 Integral Relations for Mixed Functions.

B.6 Integral Relations for Wavelet Functions.

B.7 Integral Coefficients.

APPENDIX C: Update Equations in APML Regions.

C.1 Maxwell Equations in APML Regions.

C.2 Field Expansions.

C.3 Update Equations for Face-APML Regions.

C.4 Update Equations for Edge-APML Regions.

C.5 Update Equations for Corner-APML Regions.

APPENDIX D: Expressions and Properties of the Cubic Battle–Lemari´e Functions.

D.1 Expression for the B-Spline Function in the Frequency Domain.

D.2 Orthogonality Condition in the Frequency Domain.

D.3 Expression of B-Spline Functions in the Frequency and Space Domains.

D.4 Cubic Spline Battle–Lemari´e Wavelet Function in the Frequency Domain.

Index.

YINCHAO CHEN, PHD, is Associate Professor in the Department of Electrical Engineering at the University of South Carolina. Dr. Chen has published over 140 international articles in refereed journals (and conference proceedings), and is also the coauthor, coeditor, and contributing author of several books.

QUNSHENG CAO, PHD, earned his doctorate degree at the Hong Kong Polytechnic Institute in 2001. He is currently a postdoctoral research associate in the Army High Performance Computing Research Center at the University of Minnesota in Minneapolis.

RAJ MITTRA, PHD, is Professor in the Electrical Engineering Department of The Pennsylvania State University and the Director of the Electromagnetic Communication Laboratory. Dr. Mittra is a Life Fellow of the IEEE, a past president of APS, and has served as the editor of the IEEE Transactions of Antennas and Propagation.