Electromagnetic wave propagation, radiation, and scattering : from fundamentals to applications

One of the most methodical treatments of electromagnetic wave propagation, radiation, and scattering-including new applications and ideas Presented in two parts, this book takes an analytical approach on the subject and emphasizes new ideas and applications used today. Part one covers fundamentals of electromagnetic wave propagation, radiation, and scattering. It provides ample end-of-chapter problems and offers a 90-page solution manual to help readers check and comprehend their work. The second part of the book explores up-to-date applications of electromagnetic waves-including radiometry, geophysical remote sensing and imaging, and biomedical and signal processing applications. Written by a world renowned authority in the field of electromagnetic research, this new edition of Electromagnetic Wave Propagation, Radiation, and Scattering: From Fundamentals to Applications presents detailed applications with useful appendices, including mathematical formulas, Airy function, Abel's equation, Hilbert transform, and Riemann surfaces. The book also features newly revised material that focuses on the following topics: Statistical wave theories-which have been extensively applied to topics such as geophysical remote sensing, bio-electromagnetics, bio-optics, and bio-ultrasound imaging Integration of several distinct yet related disciplines, such as statistical wave theories, communications, signal processing, and time reversal imaging New phenomena of multiple scattering, such as coherent scattering and memory effects Multiphysics applications that combine theories for different physical phenomena, such as seismic coda waves, stochastic wave theory, heat diffusion, and temperature rise in biological and other media Metamaterials and solitons in optical fibers, nonlinear phenomena, and porous media Primarily a textbook for graduate courses in electrical engineering, Electromagnetic Wave Propagation, Radiation, and Scattering is also ideal for graduate students in bioengineering, geophysics, ocean engineering, and geophysical remote sensing. The book is also a useful reference for engineers and scientists working in fields such as geophysical remote sensing, bio-medical engineering in optics and ultrasound, and new materials and integration with signal processing.

About The Author Xix Preface Xxi Preface To The First Edition Xxv Acknowledgments Xxvii Part I Fundamentals 1 1 Introduction 3 2 Fundamental Field Equations 7 2.1 Maxwell's Equations / 7 2.2 Time-Harmonic Case / 10 2.3 Constitutive Relations / 11 2.4 Boundary Conditions / 15 2.5 Energy Relations and Poynting's Theorem / 18 2.6 Vector and Scalar Potentials / 22 2.7 Electric Hertz Vector / 24 2.8 Duality Principle and Symmetry of Maxwell's Equations / 25 2.9 Magnetic Hertz Vector / 26 2.10 Uniqueness Theorem / 27 2.11 Reciprocity Theorem / 28 2.12 Acoustic Waves / 30 Problems / 33 3 Waves In Inhomogeneous And Layered Media 35 3.1 Wave Equation for a Time-Harmonic Case / 35 3.2 Time-Harmonic Plane-Wave Propagation in Homogeneous Media / 36 3.3 Polarization / 37 3.4 Plane-Wave Incidence on a Plane Boundary: Perpendicular Polarization (s Polarization) / 39 3.5 Electric Field Parallel to a Plane of Incidence: Parallel Polarization (p Polarization) / 43 3.6 Fresnel Formula, Brewster's Angle, and Total Reflection / 44 3.7 Waves in Layered Media / 47 3.8 Acoustic Reflection and Transmission from a Boundary / 50 3.9 Complex Waves / 51 3.10 Trapped Surface Wave (Slow Wave) and Leaky Wave / 54 3.11 Surface Waves Along a Dielectric Slab / 57 3.12 Zenneck Waves and Plasmons / 63 3.13 Waves in Inhomogeneous Media / 66 3.14 WKB Method / 68 3.15 Bremmer Series / 72 3.16 WKB Solution for the Turning Point / 76 3.17 Trapped Surface-Wave Modes in an Inhomogeneous Slab / 77 3.18 Medium With Prescribed Profile / 80 Problems / 81 4 Waveguides And Cavities 85 4.1 Uniform Electromagnetic Waveguides / 85 4.2 TM Modes or E Modes / 86 4.3 TE Modes or H Modes / 87 4.4 Eigenfunctions and Eigenvalues / 89 4.5 General Properties of Eigenfunctions for Closed Regions / 91 4.6 k- Diagram and Phase and Group Velocities / 95 4.7 Rectangular Waveguides / 98 4.8 Cylindrical Waveguides / 100 4.9 TEM Modes / 104 4.10 Dispersion of a Pulse in a Waveguide / 106 4.11 Step-Index Optical Fibers / 109 4.12 Dispersion of Graded-Index Fibers / 116 4.13 Radial and Azimuthal Waveguides / 117 4.14 Cavity Resonators / 120 4.15 Waves in Spherical Structures / 123 4.16 Spherical Waveguides and Cavities / 128 Problems / 133 5 Green's Functions 137 5.1 Electric and Magnetic Dipoles in Homogeneous Media / 137 5.2 Electromagnetic Fields Excited by an Electric Dipole in a Homogeneous Medium / 139 5.3 Electromagnetic Fields Excited by a Magnetic Dipole in a Homogeneous Medium / 144 5.4 Scalar Green's Function for Closed Regions and Expansion of Green's Function in a Series of Eigenfunctions / 145 5.5 Green's Function in Terms of Solutions of the Homogeneous Equation / 150 5.6 Fourier Transform Method / 155 5.7 Excitation of a Rectangular Waveguide / 157 5.8 Excitation of a Conducting Cylinder / 159 5.9 Excitation of a Conducting Sphere / 163 Problems / 166 6 Radiation From Apertures And Beam Waves 169 6.1 Huygens' Principle and Extinction Theorem / 169 6.2 Fields Due to the Surface Field Distribution / 173 6.3 Kirchhoff Approximation / 176 6.4 Fresnel and Fraunhofer Diffraction / 178 6.5 Fourier Transform (Spectral) Representation / 182 6.6 Beam Waves / 183 6.7 Goos-Hanchen Effect / 187 6.8 Higher-Order Beam-Wave Modes / 191 6.9 Vector Green's Theorem, Stratton-Chu Formula, and Franz Formula / 194 6.10 Equivalence Theorem / 197 6.11 Kirchhoff Approximation for Electromagnetic Waves / 198 Problems / 199 7 Periodic Structures And Coupled-Mode Theory 201 7.1 Floquet's Theorem / 202 7.2 Guided Waves Along Periodic Structures / 203 7.3 Periodic Layers / 209 7.4 Plane Wave Incidence on a Periodic Structure / 213 7.5 Scattering from Periodic Surfaces Based on the Rayleigh Hypothesis / 219 7.6 Coupled-Mode Theory / 224 Problems / 229 8 Dispersion And Anisotropic Media 233 8.1 Dielectric Material and Polarizability / 233 8.2 Dispersion of Dielectric Material / 235 8.3 Dispersion of Conductor and Isotropic Plasma / 237 8.4 Debye Relaxation Equation and Dielectric Constant of Water / 240 8.5 Interfacial Polarization / 240 8.6 Mixing Formula / 241 8.7 Dielectric Constant and Permeability for Anisotropic Media / 244 8.8 Magnetoionic Theory for Anisotropic Plasma / 244 8.9 Plane-Wave Propagation in Anisotropic Media / 247 8.10 Plane-Wave Propagation in Magnetoplasma / 248 8.11 Propagation Along the DC Magnetic Field / 249 8.12 Faraday Rotation / 253 8.13 Propagation Perpendicular to the DC Magnetic Field / 255 8.14 The Height of the Ionosphere / 256 8.15 Group Velocity in Anisotropic Medium / 257 8.16 Warm Plasma / 259 8.17 Wave Equations for Warm Plasma / 261 8.18 Ferrite and the Derivation of Its Permeability Tensor / 263 8.19 Plane-Wave Propagation in Ferrite / 266 8.20 Microwave Devices Using Ferrites / 267 8.21 Lorentz Reciprocity Theorem for Anisotropic Media / 270 8.22 Bi-Anisotropic Media and Chiral Media / 272 8.23 Superconductors, London Equation, and the Meissner Effects / 276 8.24 Two-Fluid Model of Superconductors at High Frequencies / 278 Problems / 280 9 Antennas, Apertures, And Arrays 285 9.1 Antenna Fundamentals / 285 9.2 Radiation Fields of Given Electric and Magnetic Current Distributions / 289 9.3 Radiation Fields of Dipoles, Slots, and Loops / 292 9.4 Antenna Arrays with Equal and Unequal Spacings / 296 9.5 Radiation Fields from a Given Aperture Field Distribution / 301 9.6 Radiation from Microstrip Antennas / 305 9.7 Self- and Mutual Impedances of Wire Antennas with Given Current Distributions / 308 9.8 Current Distribution of a Wire Antenna / 313 Problems / 314 10 Scattering Of Waves By Conducting And Dielectric Objects 317 10.1 Cross Sections and Scattering Amplitude / 318 10.2 Radar Equations / 321 10.3 General Properties of Cross Sections / 322 10.4 Integral Representations of Scattering Amplitude and Absorption Cross Sections / 325 10.5 Rayleigh Scattering for a Spherical Object / 328 10.6 Rayleigh Scattering for a Small Ellipsoidal Object / 330 10.7 Rayleigh-Debye Scattering (Born Approximation) / 334 10.8 Elliptic Polarization and Stokes Parameters / 338 10.9 Partial Polarization and Natural Light / 341 10.10 Scattering Amplitude Functions f11, f12, f21, and f22 and the Stokes Matrix / 342 10.11 Acoustic Scattering / 344 10.12 Scattering Cross Section of a Conducting Body / 346 10.13 Physical Optics Approximation / 347 10.14 Moment Method: Computer Applications / 350 Problems / 354 11 Waves In Cylindrical Structures, Spheres, And Wedges 357 11.1 Plane Wave Incident on a Conducting Cylinder / 357 11.2 Plane Wave Incident on a Dielectric Cylinder / 361 11.3 Axial Dipole Near a Conducting Cylinder / 364 11.4 Radiation Field / 366 11.5 Saddle-Point Technique / 368 11.6 Radiation from a Dipole and Parseval's Theorem / 371 11.7 Large Cylinders and the Watson Transform / 373 11.8 Residue Series Representation and Creeping Waves / 376 11.9 Poisson's Sum Formula, Geometric Optical Region, and Fock Representation / 379 11.10 Mie Scattering by a Dielectric Sphere / 382 11.11 Axial Dipole in the Vicinity of a Conducting Wedge / 390 11.12 Line Source and Plane Wave Incident on a Wedge / 392 11.13 Half-Plane Excited by a Plane Wave / 394 Problems / 395 12 Scattering By Complex Objects 401 12.1 Scalar Surface Integral Equations for Soft and Hard Surfaces / 402 12.2 Scalar Surface Integral Equations for a Penetrable Homogeneous Body / 404 12.3 EFIE and MFIE / 406 12.4 T-Matrix Method (Extended Boundary Condition Method) / 408 12.5 Symmetry and Unitarity of the T-Matrix and the Scattering Matrix / 414 12.6 T-Matrix Solution for Scattering from Periodic Sinusoidal Surfaces / 416 12.7 Volume Integral Equations for Inhomogeneous Bodies: TM Case / 418 12.8 Volume Integral Equations for Inhomogeneous Bodies: TE Case / 423 12.9 Three-Dimensional Dielectric Bodies / 426 12.10 Electromagnetic Aperture Integral Equations for a Conducting Screen / 427 12.11 Small Apertures / 430 12.12 Babinet's Principle and Slot and Wire Antennas / 433 12.13 Electromagnetic Diffraction by Slits and Ribbons / 439 12.14 Related Problems / 441 Problems / 441 13 Geometric Theory Of Diffraction And Lowfrequency Techniques 443 13.1 Geometric Theory of Diffraction / 444 13.2 Diffraction by a Slit for Dirichlet's Problem / 447 13.3 Diffraction by a Slit for Neumann's Problem and Slope Diffraction / 452 13.4 Uniform Geometric Theory of Diffraction for an Edge / 455 13.5 Edge Diffraction for a Point Source / 457 13.6 Wedge Diffraction for a Point Source / 461 13.7 Slope Diffraction and Grazing Incidence / 463 13.8 Curved Wedge / 463 13.9 Other High-Frequency Techniques / 465 13.10 Vertex and Surface Diffraction / 466 13.11 Low-Frequency Scattering / 467 Problems / 470 14 Planar Layers, Strip Lines, Patches, And Apertures 473 14.1 Excitation of Waves in a Dielectric Slab / 473 14.2 Excitation of Waves in a Vertically Inhomogeneous Medium / 481 14.3 Strip Lines / 485 14.4 Waves Excited by Electric and Magnetic Currents Perpendicular to Dielectric Layers / 492 14.5 Waves Excited by Transverse Electric and Magnetic Currents in Dielectric Layers / 496 14.6 Strip Lines Embedded in Dielectric Layers / 500 14.7 Periodic Patches and Apertures Embedded in Dielectric Layers / 502 Problems / 506 15 Radiation From A Dipole On The Conducting Earth 509 15.1 Sommerfeld Dipole Problem / 509 15.2 Vertical Electric Dipole Located Above the Earth / 510 15.3 Reflected Waves in Air / 514 15.4 Radiation Field: Saddle-Point Technique / 517 15.5 Field Along the Surface and the Singularities of the Integrand / 519 15.6 Sommerfeld Pole and Zenneck Wave / 521 15.7 Solution to the Sommerfeld Problem / 524 15.8 Lateral Waves: Branch Cut Integration / 528 15.9 Refracted Wave / 536 15.10 Radiation from a Horizontal Dipole / 538 15.11 Radiation in Layered Media / 541 15.12 Geometric Optical Representation / 545 15.13 Mode and Lateral Wave Representation / 549 Problems / 550 Part II Applications 553 16 Inverse Scattering 555 16.1 Radon Transform and Tomography / 555 16.2 Alternative Inverse Radon Transform in Terms of the Hilbert Transform / 559 16.3 Diffraction Tomography / 561 16.4 Physical Optics Inverse Scattering / 567 16.5 Holographic Inverse Source Problem / 570 16.6 Inverse Problems and Abel's Integral Equation Applied to Probing of the Ionosphere / 572 16.7 Radar Polarimetry and Radar Equation / 575 16.8 Optimization of Polarization / 578 16.9 Stokes Vector Radar Equation and Polarization Signature / 580 16.10 Measurement of Stokes Parameter / 582 Problems / 584 17 Radiometry, Noise Temperature, And Interferometry 587 17.1 Radiometry / 587 17.2 Brightness and Flux Density / 588 17.3 Blackbody Radiation and Antenna Temperature / 589 17.4 Equation of Radiative Transfer / 592 17.5 Scattering Cross Sections and Absorptivity and Emissivity of a Surface / 594 17.6 System Temperature / 598 17.7 Minimum Detectable Temperature / 600 17.8 Radar Range Equation / 601 17.9 Aperture Illumination and Brightness Distributions / 602 17.10 Two-Antenna Interferometer / 604 Problems / 607 18 Stochastic Wave Theories 611 18.1 Stochastic Wave Equations and Statistical Wave Theories / 612 18.2 Scattering in Troposphere, Ionosphere, and Atmospheric Optics / 612 18.3 Turbid Medium, Radiative Transfer, and Reciprocity / 612 18.4 Stochastic Sommerfeld Problem, Seismic Coda, and Subsurface Imaging / 613 18.5 Stochastic Green's Function and Stochastic Boundary Problems / 615 18.6 Channel Capacity of Communication Systems with Random Media Mutual Coherence Function / 619 18.7 Integration of Statistical Waves with Other Disciplines / 621 18.8 Some Accounts of Historical Development of Statistical Wave Theories / 622 19 Geophysical Remote Sensing And Imaging 625 19.1 Polarimetric Radar / 626 19.2 Scattering Models for Geophysical Medium and Decomposition Theorem / 630 19.3 Polarimetric Weather Radar / 632 19.4 Nonspherical Raindrops and Differential Reflectivity / 634 19.5 Propagation Constant in Randomly Distributed Nonspherical Particles / 636 19.6 Vector Radiative Transfer Theory / 638 19.7 Space-Time Radiative Transfer / 639 19.8 Wigner Distribution Function and Specific Intensity / 641 19.9 Stokes Vector Emissivity from Passive Surface and Ocean Wind Directions / 644 19.10 Van Cittert-Zernike Theorem Applied to Aperture Synthesis Radiometers Including Antenna Temperature / 646 19.11 Ionospheric Effects on SAR Image / 650 20 Biomedical Em, Optics, And Ultrasound 657 20.1 Bioelectromagnetics / 658 20.2 Bio-EM and Heat Diffusion in Tissues / 659 20.3 Bio-Optics, Optical Absorption and Scattering in Blood / 663 20.4 Optical Diffusion in Tissues / 666 20.5 Photon Density Waves / 670 20.6 Optical Coherence Tomography and Low Coherence Interferometry / 672 20.7 Ultrasound Scattering and Imaging of Tissues / 677 20.8 Ultrasound in Blood / 680 21 Waves In Metamaterials And Plasmon 685 21.1 Refractive Index n and - Diagram / 686 21.2 Plane Waves, Energy Relations, and Group Velocity / 688 21.3 Split-Ring Resonators / 689 21.4 Generalized Constitutive Relations for Metamaterials / 692 21.5 Space-Time Wave Packet Incident on Dispersive Metamaterial and Negative Refraction / 697 21.6 Backward Lateral Waves and Backward Surface Waves / 701 21.7 Negative Goos-Hanchen Shift / 704 21.8 Perfect Lens, Subwavelength Focusing, and Evanescent Waves / 708 21.9 Brewster's Angle in NIM and Acoustic Brewster's Angle / 712 21.10 Transformation Electromagnetics and Invisible Cloak / 716 21.11 Surface Flattening Coordinate Transform / 720 22 Time-Reversal Imaging 723 22.1 Time-Reversal Mirror in Free Space / 724 22.2 Super Resolution of Time-Reversed Pulse in Multiple Scattering Medium / 729 22.3 Time-Reversal Imaging of Single and Multiple Targets and DORT (Decomposition of Time- eversal Operator) / 731 22.4 Time-Reversal Imaging of Targets in Free Space / 735 22.5 Time-Reversal Imaging and SVD (Singular Value Decomposition) / 739 22.6 Time-Reversal Imaging with MUSIC (Multiple Signal Classification) / 739 22.7 Optimum Power Transfer by Time-Reversal Technique / 740 23 Scattering By Turbulence, Particles, Diffuse Medium, And Rough Surfaces 743 23.1 Scattering by Atmospheric and Ionospheric Turbulence / 743 23.2 Scattering Cross Section per Unit Volume of Turbulence / 746 23.3 Scattering for a Narrow Beam Case / 748 23.4 Scattering Cross Section Per Unit Volume of Rain and Fog / 750 23.5 Gaussian and Henyey-Greenstein Scattering Formulas / 751 23.6 Scattering Cross Section Per Unit Volume of Turbulence, Particles, and Biological Media / 752 23.7 Line-of-Sight Propagation, Born and Rytov Approximation / 753 23.8 Modified Rytov Solution with Power Conservation, and Mutual Coherence Function / 754 23.9 MCF for Line-of-Sight Wave Propagation in Turbulence / 756 23.10 Correlation Distance and Angular Spectrum / 759 23.11 Coherence Time and Spectral Broadening / 760 23.12 Pulse Propagation, Coherence Bandwidth, and Pulse Broadening / 761 23.13 Weak and Strong Fluctuations and Scintillation Index / 762 23.14 Rough Surface Scattering, Perturbation Solution, Transition Operator / 765 23.15 Scattering by Rough Interfaces Between Two Media / 771 23.16 Kirchhoff Approximation of Rough Surface Scattering / 774 23.17 Frequency and Angular Correlation of Scattered Waves from Rough Surfaces and Memory Effects / 779 24 Coherence In Multiple Scattering And Diagram Method 785 24.1 Enhanced Radar Cross Section in Turbulence / 786 24.2 Enhanced Backscattering from Rough Surfaces / 787 24.3 Enhanced Backscattering from Particles and Photon Localization / 789 24.4 Multiple Scattering Formulations, the Dyson and Bethe-Salpeter Equations / 791 24.5 First-Order Smoothing Approximation / 793 24.6 First- and Second-Order Scattering and Backscattering Enhancement / 794 24.7 Memory Effects / 795 25 Solitons And Optical Fibers 797 25.1 History / 797 25.2 KDV (Korteweg-De Vries) Equation for Shallow Water / 799 25.3 Optical Solitons in Fibers / 802 26 Porous Media, Permittivity, Fluid Permeability Of Shales And Seismic Coda 807 26.1 Porous Medium and Shale, Superfracking / 808 26.2 Permittivity and Conductivity of Porous Media, Archie's Law, and Percolation and Fractal / 809 26.3 Fluid Permeability and Darcy's Law / 811 26.4 Seismic Coda, P-Wave, S-Wave, and Rayleigh Surface Wave / 812 26.5 Earthquake Magnitude Scales / 813 26.6 Waveform Envelope Broadening and Coda / 814 26.7 Coda in Heterogeneous Earth Excited by an Impulse Source / 815 26.8 S-wave Coda and Rayleigh Surface Wave / 819 Appendices 821 References 913 Index 929