Başlık:
Electromagnetics, microwave circuit, and antenna design for communications engineering
Yazar:
Russer, P. (Peter), 1943-
ISBN:
9781580535328
Ek Yazar:
Yayım Bilgisi:
Boston : Artech House, c2003.
Fiziksel Tanım:
xii, 424 p. : ill. ; 24 cm.
Series:
Artech House antennas and propagation library
Series Title:
Artech House antennas and propagation library
Mevcut:*
Library | Materyal Türü | Barkod | Yer Numarası | Durum |
|---|---|---|---|---|
Searching... Pamukkale Merkez Kütüphanesi | Kitap | 0036793 | TK454.4.E5R87 2003 | Searching... Unknown |
Bound With These Titles
On Order
Özet
Özet
A clear, comprehensive overview of basic electromagnetics principles and applications to antenna and microwave circuit design for communications. Including concise explanations of all required mathematical concepts needed to fully comprehend the material, the book is a complete resource for understanding electromagnetics in current, emerging and future broadband communication systems, as well as high-speed analogue and digital electronic circuits and systems. transmission lines and waveguides, to linear multiports, microwave circuits and antennas, you get expert guidance in a wide range of key areas to help you solve design problems in communications engineering. Supported with over 200 illustrations and 900 equations, the book explains electromagnetics in an easy-to-understand manner.
Author Notes
Peter Russer received his Dipl.-Ing. and Dr. techn. degrees in Electrical Engineering from the Vienna University of Technology.
He is a Professor and Head of the Institute for High Frequency Engineering at Technische Universität München in Germany. He is a Fellow of the IEEE.
050
Table of Contents
| Preface | p. xvii |
| Chapter 1 Introduction | p. 1 |
| References | p. 6 |
| Chapter 2 Basic Electromagnetics | p. 9 |
| 2.1 The Electromagnetic Field Concept | p. 9 |
| 2.2 Field Intensities | p. 12 |
| 2.3 Current and Flux Densities | p. 16 |
| 2.4 Constitutive Relations | p. 18 |
| 2.5 The Charge Density | p. 23 |
| 2.6 The Maxwell Puzzle | p. 24 |
| 2.7 The Integral Form of Maxwell's Equations | p. 26 |
| 2.8 The Electromagnetic Wave | p. 29 |
| 2.8.1 The Wave Equation | p. 35 |
| 2.8.2 The Polarization of Electromagnetic Waves | p. 36 |
| 2.9 Kirchhoff's Laws | p. 38 |
| 2.10 Maxwell's Equations in Local Form | p. 41 |
| 2.11 Time-Harmonic Electromagnetic Fields | p. 43 |
| 2.12 Maxwell's Equations in the Frequency Domain | p. 44 |
| 2.13 Curvilinear Coordinates | p. 46 |
| 2.14 Boundary Conditions | p. 47 |
| 2.15 Problems | p. 56 |
| References | p. 59 |
| Chapter 3 Potentials and Waves | p. 61 |
| 3.1 The Electromagnetic Potentials | p. 61 |
| 3.2 The Helmholtz Equation | p. 65 |
| 3.3 Time-Harmonic Plane Waves | p. 67 |
| 3.3.1 Time-Harmonic Plane Waves in Lossless Medium | p. 69 |
| 3.3.2 Complex Waves | p. 72 |
| 3.4 TM and TE Fields and Waves | p. 74 |
| 3.5 Reflection and Transmission of Plane Waves | p. 77 |
| 3.5.1 Reflection and Diffraction of a TE Wave at a Plane Boundary | p. 80 |
| 3.5.2 Reflection and Diffraction of a TM Wave at a Plane Boundary | p. 83 |
| 3.5.3 Total Reflection | p. 86 |
| 3.6 Waves in Planar Layered Media | p. 89 |
| 3.7 Thin Conducting Sheets | p. 93 |
| 3.8 The Vector Wave Equation | p. 94 |
| 3.9 Circular Cylindrical Waves | p. 98 |
| 3.9.1 Excitation of a Cylindric Wave by a Uniform Current Filament | p. 101 |
| 3.10 Spherical Waves | p. 106 |
| 3.11 Problems | p. 106 |
| References | p. 107 |
| Chapter 4 Concepts, Methods, and Theorems | p. 109 |
| 4.1 Energy and Power | p. 109 |
| 4.2 Field Theoretic Formulation of Tellegen's Theorem | p. 116 |
| 4.3 Sources of the Electromagnetic Field | p. 118 |
| 4.4 The Uniqueness Theorem | p. 120 |
| 4.5 The Equivalence Principle | p. 121 |
| 4.6 Babinet's Principle | p. 123 |
| 4.7 Reciprocity | p. 125 |
| 4.7.1 The Lorentz Reciprocity Theorem | p. 125 |
| 4.7.2 The Reciprocity Theorem for Impressed Sources | p. 126 |
| 4.8 Green's Function | p. 128 |
| 4.9 The Integral Equation Method | p. 133 |
| 4.10 The Free-Space Green's Dyadic Form | p. 136 |
| 4.11 Green's Theorems | p. 136 |
| 4.11.1 The Scalar Green's Theorems | p. 136 |
| 4.11.2 Green's Theorems in Two Dimensions | p. 138 |
| 4.11.3 The Vector Green's Theorems | p. 140 |
| 4.12 Integral Formulation of the Equivalence Principle | p. 141 |
| 4.13 The Sturm-Liouville Equation | p. 143 |
| 4.14 Spectral Representation of Green's Functions | p. 146 |
| 4.15 Problems | p. 148 |
| References | p. 148 |
| Chapter 5 Static and Quasistatic Fields | p. 151 |
| 5.1 Conditions for Static and Quasistatic Fields | p. 151 |
| 5.2 Static and Quasistatic Electric Fields | p. 153 |
| 5.2.1 Green's Function for the Static Electric Field | p. 153 |
| 5.2.2 Capacitance | p. 155 |
| 5.3 Static and Quasistatic Magnetic Fields | p. 161 |
| 5.3.1 Green's Function for the Static Magnetic Field | p. 161 |
| 5.3.2 Inductance | p. 163 |
| 5.4 The Laplace Equation | p. 169 |
| 5.4.1 Potential Separation Planes | p. 170 |
| 5.4.2 Three-Dimensional Laplace Equation in Cartesian Coordinates | p. 171 |
| 5.5 Conformal Mapping | p. 174 |
| 5.5.1 Field of an Elliptic Cylindric Line | p. 181 |
| 5.5.2 Field of a Coaxial Line | p. 183 |
| 5.5.3 Parallel Wire Line | p. 186 |
| 5.6 The Schwarz-Christoffel Transformation | p. 191 |
| 5.6.1 The Coplanar Line | p. 193 |
| 5.6.2 The Coplanar Stripline | p. 196 |
| 5.6.3 The Stripline | p. 197 |
| 5.7 Problems | p. 201 |
| References | p. 204 |
| Chapter 6 Waves at the Surface of Conducting Media | p. 207 |
| 6.1 Transverse Magnetic Surface Waves | p. 208 |
| 6.2 Surface Currents | p. 216 |
| 6.3 Surface Current Losses | p. 221 |
| 6.4 Induced Surface Currents | p. 224 |
| 6.5 Problems | p. 227 |
| References | p. 228 |
| Chapter 7 Transmission-Lines and Waveguides | p. 229 |
| 7.1 Introduction | p. 229 |
| 7.2 Phase and Group Velocity | p. 232 |
| 7.3 The Field Components | p. 233 |
| 7.4 Waveguides for Transverse Electromagnetic Waves | p. 235 |
| 7.5 Multiconductor Transmission-Lines | p. 249 |
| 7.6 Quasi-TEM Modes of Transmission-Lines | p. 254 |
| 7.6.1 Quasi-TEM Modes of Two-Conductor Transmission-Lines | p. 254 |
| 7.6.2 Quasi-TEM Modes of Multiconductor Transmission-Lines | p. 259 |
| 7.7 Planar Transmission-Lines | p. 260 |
| 7.7.1 The Microstrip Line | p. 260 |
| 7.7.2 Quasistatic Approximation for the Microstrip Line | p. 262 |
| 7.7.3 Coplanar Waveguide and Coplanar Stripline | p. 265 |
| 7.8 Hollow Waveguides | p. 266 |
| 7.8.1 TE Modes | p. 266 |
| 7.8.2 TM Modes | p. 270 |
| 7.8.3 Modal Expansions in Waveguides | p. 272 |
| 7.9 Rectangular Waveguides | p. 276 |
| 7.9.1 Transverse Electric Modes | p. 276 |
| 7.9.2 Transverse Magnetic Modes | p. 282 |
| 7.9.3 Power Flow in the Waveguide | p. 284 |
| 7.9.4 Orthogonality of the Waveguide Modes | p. 285 |
| 7.9.5 Generalized Currents and Voltages in Waveguides | p. 286 |
| 7.9.6 Attenuation Due to Conductor Losses | p. 289 |
| 7.9.7 Attenuation Due to Dielectric Losses | p. 291 |
| 7.10 Circular Cylindric Waveguides | p. 292 |
| 7.10.1 The Circular Waveguide Modes | p. 292 |
| 7.10.2 Power Flow and Attenuation in the TE[subscript 01] Mode | p. 298 |
| 7.11 Radial Waveguides | p. 300 |
| 7.11.1 Radial Parallel Plate Waveguide | p. 300 |
| 7.11.2 Wedged Radial Parallel Plate Waveguide | p. 307 |
| 7.12 Spherical Waveguides | p. 309 |
| 7.12.1 Conical Waveguide | p. 311 |
| 7.12.2 Biconical Waveguide | p. 313 |
| 7.13 Dielectric Waveguides and Optical Fibers | p. 316 |
| 7.13.1 Homogeneous Planar Dielectric Waveguides | p. 316 |
| 7.13.2 Dielectric Slab with Single-Sided Metallization | p. 320 |
| 7.13.3 Circular Dielectric Waveguides with Step Index Profile | p. 322 |
| 7.14 Problems | p. 329 |
| References | p. 333 |
| Chapter 8 The Transmission-Line Equations | p. 335 |
| 8.1 The Transmission-Line Concept | p. 335 |
| 8.2 Generalized Voltages and Currents | p. 337 |
| 8.3 Solution of the Transmission-Line Equations | p. 341 |
| 8.4 Wave Amplitudes | p. 344 |
| 8.5 Reflection Coefficient and Smith Chart | p. 346 |
| 8.5.1 Impedance Matching with Lumped Elements | p. 353 |
| 8.5.2 Impedance Matching with Stubs | p. 355 |
| 8.6 Solution of the Multiconductor Transmission-Line Equations | p. 356 |
| 8.7 Multimode Excitation of Uniform Hollow Waveguides | p. 363 |
| 8.7.1 The Transverse Field Equations | p. 363 |
| 8.7.2 Modal Field Representation | p. 366 |
| 8.7.3 Multimode Transmission-Line Equations for Hollow Waveguides | p. 368 |
| 8.7.4 Multimode Transmission-Line Equations of Lossless Waveguides without Internal Sources | p. 374 |
| 8.8 Green's Functions for Transmission-Lines | p. 375 |
| 8.8.1 Green's Function for the Transmission-Line with Matched Terminations | p. 378 |
| 8.8.2 Green's Function for the Transmission-Line with Arbitrary Linear Passive Terminations | p. 379 |
| 8.9 Problems | p. 381 |
| References | p. 384 |
| Chapter 9 Resonant Circuits and Resonators | p. 385 |
| 9.1 The Linear Passive One-Port | p. 385 |
| 9.2 The Reactance Theorem | p. 387 |
| 9.3 Resonant Circuits | p. 389 |
| 9.4 The Transmission-Line Resonator | p. 392 |
| 9.5 Cavity Resonators | p. 395 |
| 9.5.1 The Rectangular Cavity Resonator | p. 395 |
| 9.5.2 The Circular Cylindric Cavity Resonator | p. 399 |
| 9.6 Coupling of Resonant Circuits and Resonators | p. 402 |
| 9.6.1 The Loaded Quality Factor | p. 402 |
| 9.6.2 Termination of a Transmission-Line with a Resonant Circuit | p. 403 |
| 9.6.3 Inductive Coupling of Cavity Resonators | p. 405 |
| 9.7 Orthogonality of the Resonator Modes | p. 407 |
| 9.8 Excitation of Resonators by Internal Sources | p. 409 |
| 9.9 Problems | p. 411 |
| References | p. 412 |
| Chapter 10 Passive Microwave Circuits | p. 413 |
| 10.1 Linear Multiports | p. 413 |
| 10.2 Source-Free Linear Multiports | p. 414 |
| 10.2.1 Impedance and Admittance Representations | p. 414 |
| 10.2.2 The Chain Matrix | p. 415 |
| 10.2.3 The Scattering Matrix | p. 419 |
| 10.2.4 The Transmission Matrix | p. 424 |
| 10.3 Tellegen's Theorem | p. 425 |
| 10.3.1 Connection Networks | p. 428 |
| 10.3.2 Tellegen's Theorem for Discretized Fields | p. 429 |
| 10.4 The Power Properties | p. 430 |
| 10.5 Reciprocal Multiports | p. 431 |
| 10.6 Elementary Two-Ports | p. 433 |
| 10.7 Signal Flow Graphs | p. 436 |
| 10.8 Lumped Element Equivalent Circuits | p. 439 |
| 10.8.1 Foster Representation of Reactance Multiports | p. 439 |
| 10.8.2 Cauer Representation of Radiating Structures | p. 445 |
| 10.9 Obstacles in Waveguides | p. 450 |
| 10.10 The Symmetry Properties of Waveguide Junctions | p. 456 |
| 10.10.1 Symmetric Three-Port Waveguide Junctions | p. 457 |
| 10.10.2 Symmetric Four-Port Waveguide Junctions | p. 460 |
| 10.11 Problems | p. 463 |
| References | p. 466 |
| Chapter 11 Periodic Structures and Filters | p. 467 |
| 11.1 Periodic Electromagnetic Structures | p. 467 |
| 11.1.1 TE Modes in Rectangular Periodic Waveguides | p. 467 |
| 11.1.2 Sinusoidal Variation of the Permittivity | p. 472 |
| 11.2 Wave Parameter Theory of Two-Ports | p. 474 |
| 11.3 Lumped Low-Pass Filter Prototypes | p. 481 |
| 11.3.1 The Butterworth Prototype | p. 482 |
| 11.3.2 The Chebyshev Prototype | p. 485 |
| 11.4 Ladder Filter Networks | p. 488 |
| 11.4.1 Butterworth Ladder Networks | p. 489 |
| 11.4.2 Chebyshev Ladder Networks | p. 490 |
| 11.5 Frequency Transformation | p. 492 |
| 11.5.1 Low-Pass to High-Pass Transformation | p. 492 |
| 11.5.2 Low-Pass to Band-Pass Transformation | p. 493 |
| 11.5.3 Low-Pass to Band-Stop Transformation | p. 495 |
| 11.6 Transmission-Line with Periodic Load | p. 497 |
| 11.7 Plane Wave Scattering by Periodic Structures | p. 501 |
| 11.7.1 Scattering of te Waves by Periodic Structures | p. 501 |
| 11.7.2 Scattering of tm Waves by Periodic Structures | p. 505 |
| 11.8 Metamaterials | p. 507 |
| 11.9 Problems | p. 515 |
| References | p. 517 |
| Chapter 12 Radiation from Dipoles | p. 519 |
| 12.1 The Hertzian Dipole | p. 519 |
| 12.2 Aperiodic Spherical Waves | p. 524 |
| 12.3 Vertically Oriented Electric Dipole over Lossy Half-Space | p. 528 |
| 12.3.1 The Far-Field of the Vertical Dipole over Ground | p. 538 |
| 12.3.2 The Surface Wave | p. 539 |
| 12.4 Horizontally Oriented Electric Dipole over Lossy Half-Space | p. 540 |
| 12.5 Problems | p. 544 |
| References | p. 545 |
| Chapter 13 Antennas | p. 547 |
| 13.1 Introduction | p. 547 |
| 13.2 Linear Antennas | p. 549 |
| 13.3 The Integral Equation for the Linear Antenna | p. 555 |
| 13.4 The Impedance of the Linear Antenna | p. 558 |
| 13.5 The Loop Antenna | p. 560 |
| 13.6 Receiving Antennas | p. 563 |
| 13.6.1 The Hertzian Dipole as Receiving Antenna | p. 563 |
| 13.6.2 The Loop Antenna as Receiving Antenna | p. 564 |
| 13.6.3 The Linear Dipole Antenna as Receiving Antenna | p. 565 |
| 13.7 Gain and Effective Antenna Aperture | p. 569 |
| 13.8 Antenna Arrays | p. 575 |
| 13.8.1 Linear Antenna Arrays | p. 575 |
| 13.8.2 Circular Antenna Arrays | p. 577 |
| 13.9 Aperture Antennas | p. 578 |
| 13.9.1 Radiating Apertures | p. 578 |
| 13.9.2 Horn Antennas | p. 582 |
| 13.9.3 Gain and Effective Area of Aperture Antennas | p. 585 |
| 13.9.4 Mirror and Lens Antennas | p. 587 |
| 13.9.5 Slot Antennas | p. 589 |
| 13.10 Microstrip Antennas | p. 591 |
| 13.10.1 Planar Rectangular Patch Antenna | p. 593 |
| 13.11 Broadband Antennas | p. 595 |
| 13.12 Problems | p. 597 |
| References | p. 601 |
| Chapter 14 Numerical Electromagnetics | p. 603 |
| 14.1 Introduction | p. 603 |
| 14.2 The Method of Moments | p. 605 |
| 14.3 The Transmission-Line Matrix Method | p. 611 |
| 14.4 The Mode Matching Method | p. 617 |
| References | p. 623 |
| Appendix A Vectors and Differential Forms | p. 627 |
| A.1 Vectors | p. 627 |
| A.2 Differential Forms | p. 631 |
| A.2.1 Products of Exterior Differential Forms | p. 632 |
| A.2.2 The Contraction | p. 633 |
| A.2.3 The Exterior Derivative | p. 634 |
| A.2.4 The Laplace Operator | p. 635 |
| A.3 Stokes' Theorem | p. 636 |
| A.4 Curvilinear Coordinates | p. 640 |
| A.4.1 General Cylindrical Coordinates | p. 646 |
| A.4.2 Circular Cylindric Coordinates | p. 647 |
| A.4.3 Spherical Coordinates | p. 650 |
| A.4.4 Twisted Forms | p. 653 |
| A.4.5 Integration of Differential Forms by Pullback | p. 653 |
| A.5 Double Differential Forms | p. 654 |
| A.6 Relations between Exterior Calculus and Conventional Vector Notation | p. 656 |
| A.6.1 Differential Operators | p. 656 |
| A.6.2 Maxwell's Equations | p. 656 |
| References | p. 657 |
| Appendix B Special Functions | p. 659 |
| B.1 Ordinary Bessel Functions | p. 659 |
| B.2 Modified Bessel Functions | p. 662 |
| B.3 Spherical Bessel Functions | p. 665 |
| B.4 Legendre Polynomials | p. 667 |
| B.5 Spherical Harmonics | p. 670 |
| References | p. 672 |
| Appendix C Linear Algebra | p. 673 |
| C.1 Unitary Vector Space | p. 673 |
| C.2 Diagonalization of a Matrix | p. 679 |
| C.3 Matrix Functions | p. 681 |
| C.4 The Hilbert Space | p. 683 |
| C.4.1 Linear Operators in Hilbert Space | p. 686 |
| C.4.2 Function Spaces | p. 691 |
| C.4.3 Function Spaces with Biorthogonal Basis | p. 693 |
| References | p. 696 |
| Appendix D Fourier Series and Fourier Transform | p. 697 |
| D.1 The Fourier Series | p. 697 |
| D.2 The Fourier Integral | p. 699 |
| D.3 The Delta Distribution | p. 701 |
| References | p. 704 |
| Appendix E Complex Integration | p. 705 |
| E.1 Analytic Functions | p. 705 |
| E.2 The Residue Theorem | p. 707 |
| E.3 The Saddle-Point Method | p. 708 |
| References | p. 710 |
| List of Symbols | p. 711 |
| About the Author | p. 717 |
| Index | p. 719 |
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