- CONTENTS
- Chapter 1 Introduction = 1
- 1.1 Historical Sketch = 1
- 1.1.1 High-Frequency Diffraction Theory = 2
- 1.1.2 Wave Interactions at Low and Moderate Frequencies = 3
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RISS 인기검색어
https://www.riss.kr/link?id=M367297
- 저자
-
발행사항
Boston : Artech House, c1993
-
발행연도
1993
-
작성언어
영어
- 주제어
-
DDC
537 판사항(20)
-
ISBN
0890065993
-
자료형태
일반단행본
-
발행국(도시)
Massachusetts
-
서명/저자사항
Computational electromagnetics / Konada Umashankar, Allen Taflove.
-
형태사항
viii, 717 p. : ill. ; 24 cm.
-
소장기관
- 가톨릭관동대학교 중앙도서관
- 고려대학교 세종학술정보원
- 광주대학교 도서관
- 국립중앙도서관
- 국민대학교 성곡도서관
- 동국대학교 중앙도서관
- 서강대학교 도서관
- 서울대학교 중앙도서관
- 성균관대학교 삼성학술정보관
- 아주대학교 도서관
- 연세대학교 학술문화처 도서관
- 영남대학교 도서관
- 전남대학교 중앙도서관
- 제주대학교 중앙도서관
- 홍익대학교 중앙도서관
- 가톨릭관동대학교 중앙도서관
-
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부가정보
목차 (Table of Contents)
- CONTENTS
- Chapter 1 Introduction = 1
- 1.1 Historical Sketch = 1
- 1.1.1 High-Frequency Diffraction Theory = 2
- 1.1.2 Wave Interactions at Low and Moderate Frequencies = 3
- 1.1.3 Hybrid and Iterative Formulations = 4
- 1.1.4 Finite-Difference Formulation = 6
- 1.1.5 Finite-Element Formulation = 7
- 1.1.6 Overall Perspective = 8
- 1.2 Synopsis of Contemporary Approaches = 9
- 1.2.1 Categorization of Approaches = 9
- 1.2.2 Direct Time-Domain Techniques = 11
- 1.2.3 Direct Frequency-Domain Techniques = 11
- 1.2.4 High-Frequency Diffraction Techniques = 13
- 1.3 Assessment of General Applicability = 14
- Chapter2 Maxwell's Equations = 19
- 2.1 Charge Density Distributions = 19
- 2.1.1 Electric Current Density = 23
- 2.1.2 Electric Current Density Distributions = 25
- 2.2 Continuity Equation = 29
- 2.3 Maxwell's Equations―Time Domain = 31
- 2.4 Summary of Electromagnetic Field Equations―Time Domain = 37
- 2.5 Gauss's Law for Electromagnetic Fields = 42
- 2.6 Electromagnetic Boundary Conditions = 43
- 2.6.1 Boundary Conditions for Tangential Components = 44
- 2.6.2 Boundary Conditions for Normal Components = 50
- 2.7 Power and Energy Stored = 55
- 2.8 Plane Wave Solution = 60
- 2.8.1 Wave Equation = 61
- 2.9 Solution to the Wave Equation = 66
- 2.10 Vector Plane Wave Fields = 76
- 2.11 Properties of Plane Wave Fields = 79
- 2.11.1 Intrinsic Impedance of the Medium = 81
- 2.12 One-Dimensional Field Problem = 84
- 2.12.1 Electromagnetic Fields in a Lossy Medium = 93
- 2.12.2 Finite-Difference Numerical Solution = 95
- 2.12.3 Propagation of a Half-Sine Pulse = 101
- 2.13 Frequency Domain = 104
- 2.14 Sources in Frequency Domain = 109
- 2.14.1 Electric Current Density = 109
- 2.14.2 Continuity Equation = 111
- 2.15 Maxwell's Equations in the Frequency Domain = 112
- 2.16 Boundary Conditions in the Frequency Domain = 115
- 2.17 Power and Energy Stored in Frequency Domain = 118
- 2.18 Helmholtz Equation = 123
- 2.19 Solution to the Helmholtz Equation = 128
- 2.20 Propagation Constant = 133
- 2.21 Electromagnetic Potentials = 134
- 2.21.1 Static Equations = 141
- 2.22 Solution for Potentials = 142
- 2.22.1 Potential Superposition Integrals = 148
- 2.23 Electric Dipole Fields = 151
- 2.24 Maxwell's Equations with Magnetic Sources = 156
- 2.24.1 Magnetic Source Distributions = 157
- 2.24.2 Continuity Equation = 159
- 2.25 Maxwell's Equations in Frequency Domain = 160
- 2.25.1 Electromagnetic Boundary Conditions = 161
- 2.26 Helmholtz Equations with Magnetic Sources = 165
- 2.27 Electromagnetic Potentials with Magnetic Sources = 170
- 2.28 Solution for Potentials with Magnetic Sources = 176
- Chapter 3 Two-Dimensional Perfectly Conducting Objects: TM Polarization = 181
- 3.1 General Field Equations = 183
- 3.1.1 Fields in Terms of Potentials = 189
- 3.2 Transverse Magnetic Polarization = 193
- 3.3 Field Equations in the Spectral Domain = 197
- 3.4 Solution for the Magnetic Vector Potential = 202
- 3.5 Electric Field Integral Equation―TM Case = 208
- 3.6 Equivalent Electric Current Sources = 215
- 3.6.1 EFIE―Perfect Conductor = 219
- 3.7 Method of Moments = 220
- 3.8 Perfectly Conducting Circular Cylinder = 222
- 3.8.1 Thin Conducting Wire = 231
- 3.8.2 Near- and Far-Field Distributions = 232
- 3.8.3 An Alternative Formulation = 237
- 3.9 Arbitrary Cross Section TM Excitation = 241
- 3.9.1 Expansion Functions = 244
- 3.9.2 Weighting Functions = 247
- 3.9.3 Reduction of EFIE to a Matrix Equation = 249
- 3.9.4 Square Conducting Cylinder = 257
- 3.10 Thin-Strip Conducting Scatterer = 278
- 3.10.1 Convergence Data = 285
- 3.11 Electrically Large Objects = 288
- 3.11.1 Spatial Decomposition Technique = 289
- 3.11.2 Matrix Condition Number = 302
- 3.12 Analysis of Apertures = 304
- 3.12.1 Aperture Equivalences = 305
- 3.13 Two-Dimensional Aperture = 316
- 3.13.1 Aperture Integral Equation―TE Case = 320
- Chapter 4 Two-Dimeiiaional Perfectly Conducting Object: TE Polarization = 327
- 4.1 General Field Equations = 328
- 4.1.1 Field Equations in the Spectral Domain = 329
- 4.1.2 Fields and Potentials = 333
- 4.1.3 Transformed Fields in Transverse Coordinates = 335
- 4.2 Transverse Electric Polarization = 337
- 4.2.1 Transverse Electric Fields = 339
- 4.3 Solution for Vector and Scalar Potentials = 342
- 4.4 Integral Equations―TE Case = 345
- 4.5 Equivalent Electric Current Sources = 351
- 4.5.1 MFIE―Perfect Conductor = 358
- 4.5.2 EFIE ̄Perfect Conductor = 361
- 4.6 Perfectly Conducting Circular Cylinder = 362
- 4.6.1 Alternative Formulation = 372
- 4.6.2 Scattered Near- and Far-Field Distributions = 374
- 4.7 Arbitrary Cross Section―EFIE-TE Excitation = 380
- 4.7.1 Expansion Functions = 383
- 4.8 Reduction to Matrix Equation = 386
- 4.8.1 Square Conducting Cylinder = 397
- 4.8.2 Thin-Strip Conducting Scatterer = 408
- 4.9 Arbitrary Cross Section―MFIE Excitation = 416
- 4.9.1 Reduction to a Matrix Equation = 418
- 4.9.2 EFIE and MFIE Validations = 423
- 4.10 SDT Approach―TE Case = 426
- 4.11 Analysis of Apertures = 436
- 4.11.1 Aperture Equivalences = 437
- 4.12 Two-Dimensionat Aperture = 441
- 4.12.1 Aperture Integral Equation―TM Case = 445
- Chapter 5 Two-Dimensional Homogeneous Dielectric Object: TM and TE Polarizations = 451
- 5.1 General Field Equations = 454
- 5.2 Field Equations in the Spectral Domain = 461
- 5.2.1 TM and TE Polarizations = 463
- 5.3 Formulation of Integral Equations = 470
- 5.4 Eiectromagnetic Equivalence = 475
- 5.4.1 Exterior Equivalence = 479
- 5.4.2 Interior Equivalence = 485
- 5.5 Combined Integral Equations = 492
- 5.5.1 CFIE―TM CASE = 497
- 5.6 Dielectric Circular Cylinder―TM Excitation = 508
- 5.6.1 Scattered Field Distribution = 517
- 5.7 Arbitrary Cross Section―CFIE-TM Excitation = 523
- 5.7.1 Expansion Functions = 527
- 5.8 Reduction to Partitioned Matrix Equation = 531
- 5.9 Numerical Results―TM Case = 553
- 5.10 Scattered Field Distributions = 560
- 5.10.1 Far-Field Distribution = 564
- 5.11 CFIE―TE Case = 569
- 5.12 Dielectric Circular Cylinder―TE Excitation = 561
- 5.12.1 Duality of the TM and TE Cases = 590
- 5.12.2 Scattered Field Distributions = 591
- 5.13 Arbitrary Cross Section―CFIE-TE Excitation = 595
- 5.14 Partitioned Matrix Equation = 599
- 5.15 Numerical Results―TE Case = 604
- 5.15.1 Far-Field Distribution = 607
- 5.16 Anisotropic Scatterer = 614
- 5.16.1 Interior Equivalence = 618
- 5.16.2 Potential Integrals―Anisotropic Medium = 623
- 5.16.3 CFIE―Anisotropic Case = 624
- Chapter 6 Two-Dimensional Conducting and Dielectric Layered Object: TM and TE Polarizations = 627
- 6.1 Formulation of Integral Equations = 630
- 6.2 Electromagnetic Equivalence―Layered Case = 634
- 6.2.1 Exterior Equivalence―Layer 1 = 635
- 6.2.2 Interior Equivalence―Layer 2 = 638
- 6.2.3 Inferior Equivalence―Layer 3 = 641
- 6.3 Combined Field Integral Equations―Layered Case = 643
- 6.3.1 CFIE―TM Case = 646
- 6.4 Layered Dielectric Circular Cylinder = 653
- 6.4.1 Circular Multilayer Loading = 658
- 6.5 Circular Conductor with Layered Dielectric = 663
- 6.5.1 Solution by Back Substitution = 670
- 6.5.2 Numerical Solution―Layered Case = 672
- 6.6 Layered Arbitrary Cross Section―TM Excitation = 681
- 6.7 Numerical Solution―Arbitrary Layered Case = 682
- 6.7.1 CFIE―TE Case = 696
- Appendix A Vector Identities = 697
- A.1 Vector Operations = 697
- A.2 Mixed Vector Operations and Derivatives = 698
- A.3 Differential Operator = 698
- A.4 Transformation of Vectors = 700
- A.5 Coordinate Representations = 701
- A.6 Integral Relationships = 703
- Appendix B Bessel Functions = 705
- B.1 Basic Equation = 705
- B.2 Integral Representation = 705
- B.3 Series Representation = 706
- B.4 Coordinate Transformation = 707
- Bibliography = 709
- Index = 711
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