(Ebook) Antenna Theory and Design 3rd Edition by Warren L Stutzman, Gary A Thiele ISBN 0470576642 9780470576649

(Ebook) Antenna Theory and Design 3rd Edition by Warren L Stutzman, Gary A Thiele ISBN 0470576642 9780470576649

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ISBN 10: 0470576642 
ISBN 13: 9780470576649
Author: Warren L Stutzman, Gary A Thiele

This introduction to antenna theory and design is suitable for senior undergraduate and graduate courses on the subject.

Its emphasis on both principles and design makes it perfect both as a college text and as a reference to the practicing engineer. The final three chapters on computational electromagnetics for antennas are suitable for graduate work. Stutzman provides more of a pedagogical approach than its competitors, placing a greater emphasis on a concise easily understandable presentation of fundamentals and applications as well as computational methods. This third edition has been completely revised.

New topics have been added on antennas for personal and mobile communications and base station antennas. Coverage of systems applications of antennas, arrays, microstrip and low-profile antennas, and antenna measurements has been updated and expanded, including more examples applied to modern applications.

(Ebook) Antenna Theory and Design 3rd Table of contents:

Chapter 1: Introduction
1.1: The History of Antennas
1.1.1: Overview of the History of Communications
1.1.2: The Significant Contributions to the Understanding of Electromagnetic Waves
1.1.3: Key Developments in Communication Technology
1.1.4: Long-Distance Wireless Communications
1.1.5: The Modern Era of Wireless
1.2: What Is an Antenna and When Is it Used?
1.2.1: What Is an Antenna?
1.2.2: When Is an Antenna Used?
1.3: How Antennas Radiate
1.4: The Four Antenna Types
References
Problems
Chapter 2: Antenna Fundamentals
2.1: Fundamentals of Electromagnetics
2.2: Solution of Maxwell's Equations for Radiation Problems
2.3: The Ideal Dipole
2.4: Radiation Patterns
2.4.1: Radiation Pattern Basics
2.4.2: Radiation from Line Currents
2.4.3: Far-Field Conditions and Field Regions
2.4.4: Steps in the Evaluation of Radiation Fields
2.4.5: Radiation Pattern Definitions
2.4.6: Radiation Pattern Parameters
2.5: Directivity and Gain
2.6: Antenna Impedance
2.7: Radiation Efficiency
2.8: Antenna Polarization
References
Problems
Chapter 3: Simple Radiating Systems
3.1: Electrically Small Dipoles
3.2: Half-Wave Dipoles
3.3: Monopoles and Image Theory
3.3.1: Image Theory
3.3.2: Monopoles
3.4: Small Loop Antennas and Duality
3.4.1: Duality
3.4.2: The Small Loop Antenna
3.5: Two-Element Arrays
References
Problems
Chapter 4: System Applications for Antennas
4.1: Introduction
4.2: Receiving Properties of Antennas
4.3: Antenna Noise and Radiometry
4.4: Antennas in Communication Systems
4.4.1: Directivity, Gain, and Effective Aperture
4.4.2: Communication Links
4.4.3: Effective Isotropically Radiated Power (EIRP)
4.4.4: Impedance Mismatch
4.4.5: Polarization Mismatch
4.5: Antennas In Wireless Communication Systems
4.5.1: Spatial Frequency Reuse and Cellular Systems
4.5.2: Propagation Effects on Communication Links
4.5.3: Gain Estimation
4.6: Antennas in Radar Systems
4.7: Antennas As Unintentional Radiators
References
Problems
Chapter 5: Line Sources
5.1: The Uniform Line Source
5.2: Tapered Line Sources
5.3: Fourier Transform Relations Between the Far-Field Pattern and the Source Distribution
5.4: Fast Wave And Slow Wave Distributions
5.5: Superdirective Line Sources
References
Problems
Chapter 6: Wire Antennas
6.1: Dipole Antennas
6.1.1: Straight Wire Dipoles
6.1.2: The Vee Dipole
6.2: Folded Dipole Antennas
6.3: Yagi-Uda Antennas
6.4: Feeding Wire Antennas
6.4.1: Transmission Lines
6.4.2: Matching Networks
6.4.3: Baluns
6.5: Loaded Wire Antennas
6.5.1: Lumped Loaded Wire Antennas
6.5.2: Distributively Loaded Wire Antennas and Fractals
6.6: Ground Plane Backed Wire Antennas
6.6.1: The Flat Plate Reflector
6.6.2: Corner Reflector Antennas
6.6.3: Backfire Antennas
6.7: Wire Antennas Above an Imperfect Ground Plane
6.7.1: Pattern Effects of a Real Earth Ground Plane
6.7.2: Ground Plane Construction
6.8: Large Loop Antennas
References
Problems
Chapter 7: Broadband Antennas
7.1: Introduction
7.2: Traveling-Wave Wire Antennas
7.3: Helical Antennas
7.3.1: Normal Mode Helix Antennas
7.3.2: Axial Mode Helix Antennas
7.4: Biconical Antennas
7.4.1: The Infinite Biconical Antenna
7.4.2: Finite Biconical Antennas
7.4.3: Discone Antennas
7.5: Sleeve Antennas
7.5.1: Sleeve Monopoles
7.5.2: Sleeve Dipoles
7.6: Principles of Frequency-Independent Antennas
7.7: Spiral Antennas
7.7.1: Equiangular Spiral Antennas
7.7.2: Archimedean Spiral Antennas
7.7.3: Conical Equiangular Spiral Antennas
7.7.4: Related Configurations
7.8: Log-Periodic Antennas
7.9: Wideband EMC Antennas
7.10: Ultra-Wideband Antennas
References
Problems
Chapter 8: Array Antennas
8.1: Introduction
8.2: The Array Factor for Linear Arrays
8.3: Uniformly Excited, Equally Spaced Linear Arrays
8.3.1: The Array Factor Expression
8.3.2: Main Beam Scanning and Beamwidth
8.3.3: The Ordinary Endfire Array
8.3.4: The Hansen-Woodyard Endfire Array
8.4: The Complete Array Pattern and Pattern Multiplication
8.5: Directivity of Uniformly Excited, Equally Spaced Linear Arrays
8.6: Nonuniformly Excited, Equally Spaced Linear Arrays
8.7: Mutual Coupling in Arrays
8.7.1: Impedance Effects of Mutual Coupling
8.7.2: Array Pattern Evaluation Including Mutual Coupling
8.8: Multidimensional Arrays
8.9: Phased Arrays and Array Feeding Techniques
8.9.1: Scan Principles
8.9.2: Feed Networks and Array Technology
8.9.3: Operational Array Examples and the Future of Arrays
8.10: Elements for Arrays
8.11: Wideband Phased Arrays
References
Problems
Chapter 9: Aperture Antennas
9.1: Radiation from Apertures and Huygens' Principle
9.2: Rectangular Apertures
9.2.1: Uniform Rectangular Apertures
9.2.2: Tapered Rectangular Apertures
9.3: Techniques for Evaluating Gain
9.3.1: Directivity
9.3.2: Gain and Efficiencies
9.3.3: Simple Directivity Formulas
9.4: Rectangular Horn Antennas
9.4.1: The H-Plane Sectoral Horn Antenna
9.4.2: The E-Plane Sectoral Horn Antenna
9.4.3: The Pyramidal Horn Antenna
9.5: Circular Apertures
9.5.1: The Uniform Circular Aperture
9.5.2: Tapered Circular Apertures
9.6: Reflector Antennas
9.6.1: Parabolic Reflector Antenna Principles
9.6.2: The Axisymmetric Parabolic Reflector Antenna
9.6.3: Offset Parabolic Reflectors
9.6.4: Dual Reflector Antennas
9.6.5: Cross-Polarization and Scanning Properties of Reflector Antennas
9.6.6: Gain Calculations for Reflector Antennas
9.6.7: Other Reflector Antennas
9.7: Feed Antennas for Reflectors
9.7.1: Field Representations
9.7.2: Matching the Feed to the Reflector
9.7.3: A General Feed Model
9.7.4: Feed Antennas Used in Practice
9.8: Lens Antennas
9.8.1: Dielectric Lens Antennas
9.8.2: Constrained Lens Antennas
References
Problems
Chapter 10: Antenna Synthesis
10.1: The Antenna Synthesis Problem
10.1.1: Formulation of the Synthesis Problem
10.1.2: Synthesis Principles
10.2: Line Source Shaped Beam Synthesis Methods
10.2.1: The Fourier Transform Method
10.2.2: The Woodward–Lawson Sampling Method
10.3: Linear Array Shaped Beam Synthesis Methods
10.3.1: The Fourier Series Method
10.3.2: The Woodward–Lawson Sampling Method
10.3.3: Comparison of Shaped Beam Synthesis Methods
10.4: Low Side Lobe, Narrow Main Beam Synthesis Methods
10.4.1: The Dolph-Chebyshev Linear Array Method
10.4.2: The Taylor Line Source Method
10.5: The Iterative Sampling Method
References
Problems
Chapter 11: Low-Profile Antennas and Personal Communication Antennas
11.1: Introduction
11.2: Microstrip Antenna Elements
11.2.1: Rectangular Microstrip Patch Antennas
11.2.2: Other Microstrip Patch Antennas and Their Applications
11.2.3: Broadband Microstrip Patch Antennas
11.3: Microstrip Arrays
11.4: Microstrip Leaky Wave Antennas
11.4.1: Characteristics of Leaky Wave Antennas
11.4.2: Microstrip Modes
11.4.3: Propagation Regimes
11.5: Fundamental Limits on Antenna Size
11.5.1: The Fundamental Limit on Antenna Size
11.5.2: Practical Aspects of Antenna Size Limits
11.5.3: Antenna Loading and Impedance Matching
11.6: Antennas for Compact Devices
11.6.1: Normal Mode Helix Type Antennas
11.6.2: Quadrifilar Antennas
11.6.3: Planar Inverted-F Type Antennas
11.6.4: Other Compact Antennas, Including Multiband/Broadband Handset Antennas
11.6.5: Radio Frequency Identification (RFID) Antennas
11.7: Dielectric Resonator Antennas
11.8: Near Fields of Electrically Large Antennas
11.8.1: Near Field of a Uniform Rectangular Aperture
11.8.2: Calculating Near Fields
11.9: Human Body Effects on Antenna Performance
11.10: Radiation Hazards
References
Problems
Chapter 12: Terminal and Base Station Antennas for Wireless Applications
12.1: Satellite Terminal Antennas
12.2: Base Station Antennas
12.3: Mobile Terminal Antennas
12.4: Smart Antennas
12.5: Adaptive and Spatial Filtering Antennas
12.5.1: Switched Beam Antenna Systems
12.5.2: Adaptive Antennas in General
12.5.3: Van Atta Retrodirective Array
12.5.4: Adaptive Receiving Arrays
References
Problems
Chapter 13: Antenna Measurements
13.1: Reciprocity and Antenna Measurements
13.2: Pattern Measurement and Antenna Ranges
13.3: Gain Measurement
13.3.1: Gain Measurement of Linearly Polarized Antennas
13.3.2: Gain Measurement of Circularly Polarized Antennas
13.3.3: Radiation Efficiency Measurement
13.3.4: Gain Measurement of Large Antennas
13.3.5: Summary of Gain Determination Methods
13.4: Polarization Measurement
13.4.1: The Polarization Pattern Method
13.4.2: The Spinning Linear Method
13.4.3: The Dual-Linear Pattern Method
13.5: Field Intensity Measurement
13.6: Mobile Radio Antenna Measurements
13.7: Rules for Experimental Investigations
References
Problems
Chapter 14: CEM for Antennas: The Method of Moments
14.1: General Introduction to CEM
14.2: Introduction to the Method of Moments
14.3: Pocklington's Integral Equation
14.4: Integral Equations and Kirchhoff's Network Equations
14.5: Source Modeling
14.6: Weighted Residuals and the Method of Moments
14.7: Two Alternative Approaches to the Method of Moments
14.7.1: Reaction
14.7.2: Linear Algebra Formulation of MoM
14.8: Formulation and Computational Considerations
14.8.1: Other Expansion and Weighting Functions
14.8.2: Other Electric Field Integral Equations for Wires
14.8.3: Computer Time Considerations
14.8.4: Toeplitz Matrices
14.8.5: Block Toeplitz Matrices
14.8.6: Compressed Matrices
14.8.7: Validation
14.9: Calculation of Antenna and Scatterer Characteristics
14.10: The Wire Antenna or Scatterer as an N-Port Network
14.10.1: Series Connections
14.10.2: Parallel Connections
14.11: Antenna Arrays
14.11.1: The Linear Array
14.11.2: The Circular Array
14.11.3: Two-Dimensional Planar Array of Dipoles
14.11.4: Summary
14.12: Radar Cross Section of Antennas
14.13: Modeling of Solid Surfaces
14.13.1: Wire-Grid Model
14.13.2: Continuous Surface Model
14.14: Summary
References
Problems
Chapter 15: CEM for Antennas: Finite Difference Time Domain Method
15.1: Maxwell's Equations for the FDTD Method
15.1.1: Three-Dimensional Formulation
15.1.2: Two-Dimensional Formulation
15.1.3: One-Dimensional Formulation
15.2: Finite Differences and the Yee Algorithm
15.3: Cell Size, Numerical Stability, and Dispersion
15.4: Computer Algorithm and FDTD Implementation
15.5: Absorbing Boundary Conditions
15.6: Source Conditions
15.6.1: Source Functionality
15.6.2: The Hard Source
15.6.3: The Soft Source
15.6.4: Total-Field/Scattered-Field Formulation
15.6.5: Pure Scattered-Field Formulation
15.7: Near Fields and Far Fields
15.8: A Two-Dimensional Example: An E–Plane Sectoral Horn Antenna
15.9: Antenna Analysis and Applications
15.9.1: Impedance, Efficiency, and Gain
15.9.2: The Monopole over a PEC Ground Plane
15.9.3: Microstrip Leaky Wave Antennas
15.10: Summary
References
Problems
Chapter 16: CEM for Antennas: High-Frequency Methods
16.1: Geometrical Optics
16.2: Wedge Diffraction Theory
16.3: The Ray-Fixed Coordinate System
16.4: A Uniform Theory of Wedge Diffraction
16.5: E-Plane Analysis of Horn Antennas
16.6: Cylindrical Parabolic Reflector Antennas
16.7: Radiation by a Slot on a Finite Ground Plane
16.8: Radiation by a Monopole on a Finite Ground Plane
16.9: Equivalent Current Concepts
16.10: A Multiple Diffraction Formulation
16.11: Diffraction by Curved Surfaces
16.12: Application of UTD to Wireless Mobile Propagation
16.13: Extension of Moment Method Using the UTD
16.14: Physical Optics
16.15: Frequency Dependence of First-Order Scattering Sources
16.16: Method of Stationary Phase
16.17: Physical Theory of Diffraction
16.18: Cylindrical Parabolic Reflector Antennas—PTD

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