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E-grāmata: Modern Antenna Design 2e 2nd Edition [Wiley Online]

(Milligan & Associates, Inc.)
  • Formāts: 640 pages
  • Sērija : IEEE Press
  • Izdošanas datums: 29-Jul-2005
  • Izdevniecība: Wiley-IEEE Press
  • ISBN-10: 471720615
  • ISBN-13: 9780471720614
Citas grāmatas par šo tēmu:
  • Wiley Online
  • Cena: 259,67 €*
  • * this price gives unlimited concurrent access for unlimited time
Modern Antenna Design 2e 2nd EditionPalielināt
  • Formāts: 640 pages
  • Sērija : IEEE Press
  • Izdošanas datums: 29-Jul-2005
  • Izdevniecība: Wiley-IEEE Press
  • ISBN-10: 471720615
  • ISBN-13: 9780471720614
Citas grāmatas par šo tēmu:
Wiley Online E-booksMore info about Wiley Online
Rokasgrāmatas mājas lapa: https://onlinelibrary.wiley.com/doi/book/10.1002/0471720615
Milligan, a wireless communications consultant, distills essential theory of antenna design without becoming buried in mathematics. He demonstrates real-world applications across a variety of fields, including telecommunications, remote sensing, and broadcasting. He begins with a basic discussion of properties of antennas, then moves on to specific design topics, including radiation structures and numerical methods, aperture distributions, Gaussian beam analysis and waveguide horns, traveling wave antennas, and phased arrays. This second edition reflects developments in antenna design. The book is for antenna designers in all fields of industry and communications. Annotation ©2005 Book News, Inc., Portland, OR (booknews.com)

* A practical book written for engineers who design and use antennas
* The author has many years of hands on experience designing antennas that were used in such applications as the Venus and Mars missions of NASA
* The book covers all important topics of modern antenna design for communications
* Numerical methods will be included but only as much as are needed for practical applications
Preface xv
Properties of Antennas
1(41)
Antenna Radiation
2(1)
Gain
3(3)
Effective Area
6(1)
Path Loss
6(1)
Radar Range Equation and Cross Section
7(2)
Why Use an Antenna?
9(1)
Directivity
10(1)
Directivity Estimates
11(5)
Pencil Beam
11(2)
Butterfly or Omnidirectional Pattern
13(3)
Beam Efficiency
16(1)
Input-Impedance Mismatch Loss
17(1)
Polarization
18(9)
Circular Polarization Components
19(2)
Huygens Source Polarization
21(1)
Relations Between Bases
22(1)
Antenna Polarization Response
23(2)
Phase Response of Rotating Antennas
25(1)
Partial Gain
26(1)
Measurement of Circular Polarization Using Amplitude Only
26(1)
Vector Effective Height
27(2)
Antenna Factor
29(1)
Mutual Coupling Between Antennas
29(1)
Antenna Noise Temperature
30(5)
Communication Link Budget and Radar Range
35(1)
Multipath
36(1)
Propagation Over Soil
37(2)
Multipath Fading
39(3)
References
40(2)
Radiation Structures and Numerical Methods
42(60)
Auxiliary Vector Potentials
43(8)
Radiation from Electric Currents
44(5)
Radiation from Magnetic Currents
49(2)
Apertures: Huygens Source Approximation
51(6)
Near- and Far-Field Regions
55(2)
Huygens Source
57(1)
Boundary Conditions
57(2)
Physical Optics
59(8)
Radiated Fields Given Currents
59(1)
Applying Physical Optics
60(5)
Equivalent Currents
65(1)
Reactance Theorem and Mutual Coupling
66(1)
Method of Moments
67(9)
Use of the Reactance Theorem for the Method of Moments
68(1)
General Moments Method Approach
69(2)
Thin-Wire Moment Method Codes
71(1)
Surface and Volume Moment Method Codes
71(1)
Examples of Moment Method Models
72(4)
Finite-Difference Time-Domain Method
76(8)
Implementation
76(1)
Central Difference Derivative
77(1)
Finite-Difference Maxwell's Equations
77(2)
Time Step for Stability
79(1)
Numerical Dispersion and Stability
80(1)
Computer Storage and Execution Times
80(1)
Excitation
81(2)
Waveguide Horn Example
83(1)
Ray Optics and the Geometric Theory of Diffraction
84(18)
Fermat's Principle
85(1)
H-Plane Pattern of a Dipole Located Over a Finite Strip
85(2)
E-Plane Pattern of a Rectangular Horn
87(2)
H-Plane Pattern of a Rectangular Horn
89(1)
Amplitude Variations Along a Ray
90(3)
Extra Phase Shift Through Caustics
93(1)
Snell's Laws and Reflection
93(1)
Polarization Effects in Reflections
94(1)
Reflection from a Curved Surface
94(2)
Ray Tracing
96(1)
Edge Diffraction
96(2)
Slope Diffraction
98(1)
Corner Diffraction
99(1)
Equivalent Currents
99(1)
Diffraction from Curved Surfaces
99(1)
References
100(2)
Arrays
102(34)
Two-Element Array
104(5)
Linear Array of N Elements
109(5)
Hansen and Woodyard End-Fire Array
114(1)
Phased Arrays
115(2)
Grating Lobes
117(1)
Multiple Beams
118(2)
Planar Array
120(5)
Grating Lobes in Planar Arrays
125(2)
Mutual Impedance
127(1)
Scan Blindness and Array Element Pattern
127(1)
Compensating Array Feeding for Mutual Coupling
128(1)
Array Gain
129(4)
Arrays Using Arbitrarily Oriented Elements
133(3)
References
135(1)
Aperture Distributions and Array Synthesis
136(81)
Amplitude Taper and Phase Error Efficiencies
137(3)
Separable Rectangular Aperture Distributions
139(1)
Circularly Symmetrical Distributions
140(1)
Simple Linear Distributions
140(4)
Taylor One-Parameter Linear Distribution
144(3)
Taylor n Line Distribution
147(5)
Taylor Line Distribution with Edge Nulls
152(3)
Elliott's Method for Modified Taylor Distribution and Arbitrary Sidelobes
155(3)
Bayliss Line-Source Distribution
158(4)
Woodward Line-Source Synthesis
162(2)
Schelkunoff's Unit-Circle Method
164(6)
Dolph--Chebyshev Linear Array
170(2)
Villeneuve Array Synthesis
172(1)
Zero Sampling of Continuous Distributions
173(2)
Fourier Series Shaped-Beam Array Synthesis
175(3)
Orchard Method of Array Synthesis
178(10)
Series-Fed Array and Traveling-Wave Feed Synthesis
188(3)
Circular Apertures
191(3)
Circular Gaussian Distribution
194(1)
Hansen Single-Parameter Circular Distribution
195(1)
Taylor Circular-Aperture Distribution
196(4)
Bayliss Circular-Aperture Distribution
200(2)
Planar Arrays
202(1)
Convolution Technique for Planar Arrays
203(5)
Aperture Blockage
208(3)
Quadratic Phase Error
211(3)
Beam Efficiency of Circular Apertures with Axisymmetric Distribution
214(3)
References
215(2)
Dipoles, Slots, and Loops
217(68)
Standing-Wave Currents
218(2)
Radiation Resistance (Conductance)
220(2)
Babinet-Booker Principle
222(1)
Dipoles Located Over a Ground Plane
223(2)
Dipole Mounted Over Finite Ground Planes
225(6)
Crossed Dipoles for Circular Polarization
231(3)
Super Turnstile or Batwing Antenna
234(3)
Corner Reflector
237(5)
Monopole
242(1)
Sleeve Antenna
242(3)
Cavity-Mounted Dipole Antenna
245(2)
Folded Dipole
247(1)
Shunt Feeding
248(1)
Discone Antenna
249(2)
Baluns
251(9)
Folded Balun
252(1)
Sleeve or Bazooka Baluns
253(2)
Split Coax Balun
255(1)
Half-Wavelength Balun
256(1)
Candelabra Balun
256(1)
Ferrite Core Baluns
256(2)
Ferrite Candelabra Balun
258(1)
Transformer Balun
258(1)
Split Tapered Coax Balun
259(1)
Natural Balun
260(1)
Small Loop
260(1)
Alford Loop
261(2)
Resonant Loop
263(1)
Quadrifilar Helix
264(2)
Cavity-Backed Slots
266(1)
Stripline Series Slots
266(3)
Shallow-Cavity Crossed-Slot Antenna
269(1)
Waveguide-Fed Slots
270(1)
Rectangular-Waveguide Wall Slots
271(5)
Circular-Waveguide Slots
276(2)
Waveguide Slot Arrays
278(7)
Nonresonant Array
279(3)
Resonant Array
282(1)
Improved Design Methods
282(1)
References
283(2)
Microstrip Antennas
285(51)
Microstrip Antenna Patterns
287(6)
Microstrip Patch Bandwidth and Surface-Wave Efficiency
293(6)
Rectangular Microstrip Patch Antenna
299(11)
Quarter-Wave Patch Antenna
310(3)
Circular Microstrip Patch
313(3)
Circularly Polarized Patch Antennas
316(3)
Compact Patches
319(4)
Directly Fed Stacked Patches
323(2)
Aperture-Coupled Stacked Patches
325(2)
Patch Antenna Feed Networks
327(2)
Series-Fed Array
329(1)
Microstrip Dipole
330(2)
Microstrip Franklin Array
332(1)
Microstrip Antenna Mechanical Properties
333(3)
References
334(2)
Horn Antennas
336(44)
Rectangular Horn (Pyramidal)
337(11)
Beamwidth
341(2)
Optimum Rectangular Horn
343(3)
Designing to Given Beamwidths
346(1)
Phase Center
347(1)
Circular-Aperture Horn
348(5)
Beamwidth
350(2)
Phase Center
352(1)
Circular (Conical) Corrugated Horn
353(6)
Scalar Horn
357(1)
Corrugation Design
357(1)
Choke Horns
358(1)
Rectangular Corrugated Horns
359(1)
Corrugated Ground Plane
359(3)
Gaussian Beam
362(3)
Ridged Waveguide Horns
365(7)
Box Horn
372(2)
T-Bar-Fed Slot Antenna
374(2)
Multimode Circular Horn
376(1)
Biconical Horn
376(4)
References
378(2)
Reflector Antennas
380(67)
Paraboloidal Reflector Geometry
381(2)
Paraboloidal Reflector Aperture Distribution Losses
383(2)
Approximate Spillover and Amplitude Taper Trade-offs
385(2)
Phase Error Losses and Axial Defocusing
387(2)
Astigmatism
389(1)
Feed Scanning
390(3)
Random Phase Errors
393(3)
Focal Plane Fields
396(1)
Feed Mismatch Due to the Reflector
397(2)
Front-to-Back Ratio
399(1)
Offset-Fed Reflector
399(6)
Reflections from Conic Sections
405(3)
Dual-Reflector Antennas
408(8)
Feed Blockage
410(3)
Diffraction Loss
413(1)
Cassegrain Tolerances
414(2)
Feed and Subreflector Support Strut Radiation
416(5)
Gain/Noise Temperature of a Dual Reflector
421(1)
Displaced-Axis Dual Reflector
421(3)
Offset-Fed Dual Reflector
424(3)
Horn Reflector and Dragonian Dual Reflector
427(2)
Spherical Reflector
429(3)
Shaped Reflectors
432(10)
Cylindrical Reflector Synthesis
433(1)
Circularly Symmetrical Reflector Synthesis
434(3)
Doubly Curved Reflector for Shaped Beams
437(2)
Dual Shaped Reflectors
439(3)
Optimization Synthesis of Shaped and Multiple-Beam Reflectors
442(5)
References
443(4)
Lens Antennas
447(27)
Single Refracting Surface Lenses
448(3)
Zoned Lenses
451(3)
General Two-Surface Lenses
454(5)
Single-Surface or Contact Lenses
459(2)
Metal Plate Lenses
461(2)
Surface Mismatch and Dielectric Losses
463(1)
Feed Scanning of a Hyperboloidal Lens
464(1)
Dual-Surface Lenses
465(5)
Coma-Free Axisymmetric Dielectric Lens
466(2)
Specified Aperture Distribution Axisymmetric Dielectric Lens
468(2)
Bootlace Lens
470(2)
Luneburg Lens
472(2)
References
472(2)
Traveling-Wave Antennas
474(47)
General Traveling Waves
475(6)
Slow Wave
478(2)
Fast Waves (Leaky Wave Structure)
480(1)
Long Wire Antennas
481(4)
Beverage Antenna
481(1)
V Antenna
482(1)
Rhombic Antenna
483(2)
Yagi-Uda Antenna
485(12)
Multiple-Feed Yagi-Uda Antennas
492(3)
Resonant Loop Yagi-Uda Antennas
495(2)
Corrugated Rod (Cigar) Antenna
497(2)
Dielectric Rod (Polyrod) Antenna
499(3)
Helical Wire Antenna
502(7)
Helical Modes
503(1)
Axial Mode
504(2)
Feed of a Helical Antenna
506(1)
Long Helical Antenna
507(1)
Short Helical Antenna
508(1)
Short Backfire Antenna
509(3)
Tapered Slot Antennas
512(4)
Leaky Wave Structures
516(5)
References
518(3)
Frequency-Independent Antennas
521(52)
Spiral Antennas
522(2)
Modal Expansion of Antenna Patterns
524(2)
Archimedean Spiral
526(1)
Equiangular Spiral
527(3)
Pattern Analysis of Spiral Antennas
530(5)
Spiral Construction and Feeding
535(3)
Spiral Construction
535(1)
Balun Feed
536(2)
Infinite Balun
538(1)
Beamformer and Coaxial Line Feed
538(1)
Spiral and Beamformer Measurements
538(2)
Feed Network and Antenna Interaction
540(1)
Modulated Arm Width Spiral
541(2)
Conical Log Spiral Antenna
543(6)
Mode 2 Conical Log Spiral Antenna
549(1)
Feeding Conical Log Spirals
550(1)
Log-Periodic Antennas
550(1)
Log-Periodic Dipole Antenna
551(10)
Feeding a Log-Periodic Dipole Antenna
556(2)
Phase Center
558(1)
Elevation Angle
559(1)
Arrays of Log-Periodic Dipole Antennas
560(1)
Other Log-Periodic Types
561(2)
Log-Periodic Antenna Feeding Paraboloidal Reflector
563(4)
V Log-Periodic Array
567(2)
Cavity-Backed Planar Log-Periodic Antennas
569(4)
References
571(2)
Phased Arrays
573(34)
Fixed Phase Shifters (Phasers)
574(4)
Quantization Lobes
578(2)
Array Errors
580(2)
Nonuniform and Random Element Existence Arrays
582(6)
Linear Space Tapered Array
582(2)
Circular Space Tapered Array
584(3)
Statistically Thinned Array
587(1)
Array Element Pattern
588(2)
Feed Networks
590(9)
Corporate Feed
590(2)
Series Feed
592(1)
Variable Power Divider and Phase Shifter
592(2)
Butler Matrix
594(2)
Space Feeding
596(1)
Tapered Feed Network with Uniform-Amplitude Subarrays
597(2)
Pattern Null Formation in Arbitrary Array
599(2)
Phased Array Application to Communication Systems
601(1)
Near-Field Measurements on Phased Arrays
602(5)
References
604(3)
Index 607


THOMAS A. MILLIGAN is Chief Engineer for Milligan & Associates, Inc., a consulting firm that offers wireless communications solutions. He previously was principal engineer at Lockheed Martin Astronautics, where he specialized in microwave antenna design and analysis. Mr. Milligan is the author of the first edition of Modern Antenna Design and coauthor of Antenna Engineering Using Physical Optics.
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