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【2008新书】John.Wiley.IEEE.Reflect.Array.Antennas.LRN.INT:

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Copyright © 2008 by Institute of Electrical and Electronics Engineers. All rights reserved.
Published by John Wiley & Sons, Inc., Hoboken, New Jersey.
Published simultaneously in Canada.
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Wiley Bicentennial Logo: Richard J. Pacifi co
Library of Congress Cataloging-in-Publication Data is available.
ISBN: 978-0-470-08491-5
Printed in the United States of America.
10 9 8 7 6 5 4 3 2 1

Preface ix
Acknowledgments xiii
1. Introduction to Refl ectarray Antenna 1
1.1 Description of Refl ectarray 1
1.2 Printed Refl ectarray 3
1.2.1 Advantages of Refl ectarray 3
1.2.2 Disadvantage of Refl ectarray 4
References 6
2. Development History 9
2.1 Early Innovations and Developments 9
2.1.1 Waveguide Refl ectarray in the 1960s 9
2.1.2 Spiralphase Refl ectarray in the 1970s 9
2.1.3 Microstrip Refl ectarray in the 1980s 11
2.2 Recent Developments 13
2.3 Comparison with Similar Technologies 20
2.3.1 Array Lens 20
2.3.2 Fresnel-Zone Plate Refl ector 22
References 24
3. Antenna Analysis Techniques 27
3.1 Introduction 27
3.2 Overview of Analysis Techniques 29
3.3 Phase-Shift Distribution 34
3.4 Analysis of Rectangular Patches with Attached Stubs 35
3.5 Full-Wave Analysis of Multilayer Periodic Structures 38
3.5.1 Characterization of a Periodic Interface as a
Building Block 40
CONTENTS
vi CONTENTS
3.5.2 Analysis of Refl ectarray Elements in a Periodic
Environment 44
3.6 Phase-Shifter Element Based on Single and Stacked
Variable-Sized Patches 48
3.6.1 Single-Layer Elements 49
3.6.2 Multilayer Elements 50
3.6.3 Measurements of Phase-Shift and Losses in
Waveguide Simulator 52
3.7 Phase-Shifter Element Based on Aperture-Coupled Patches 55
3.7.1 Design of Refl ectarray Element 56
3.7.2 Phase Delay Curves 57
3.8 Feed Model and Radiation Patterns 64
3.8.1 Field on the Refl ectarray Elements 66
3.8.2 Radiation Patterns 68
3.8.3 Experimental Results 72
3.8.4 Gain Computation 73
References 74
4. Practical Design Approach 79
4.1 Element Effects and Selection 79
4.1.1 Element Refl ection Phase 79
4.1.2 Element Beamwidth 81
4.1.3 Element Bandwidth 82
4.1.4 Element Refl ection Effi ciency 82
4.1.5 Element Spacing 83
4.2 Path Length and Phase Delay Calculation 84
4.3 Radiation Pattern Calculation 85
4.4 Refl ectarray Geometry Design 86
4.5 Refl ectarray Power Handling 91
References 91
5. Broadband Techniques 93
5.1 Bandwidth Limitation by the Refl ectarray Element 93
5.2 Broadband Phase-Shifter Elements 95
5.2.1 Aperture-Coupled Patches 96
5.2.2 Variable-Sized Stacked Patches 97
CONTENTS vii
5.2.3 Other Refl ectarray Elements for Bandwidth
Improvement 99
5.3 Bandwidth Limitation by Differential Spatial Phase Delay 100
5.4 Broadband Techniques for Large Refl ectarrays 104
5.4.1 True Time Delay Refl ectarrays 106
5.4.2 Compensation of Phase Delay in a Frequency Band 108
5.4.3 Multifacet Refl ectarrays 112
References 116
6. Dual-Band Refl ectarray 119
6.1 Dual-Band with a Single-Layer Substrate 119
6.1.1 Circular or Dual-Linear Polarization with Two
Widely Separated Frequencies 119
6.1.2 Circular Polarization with Two Closely Separated
Frequencies 120
6.1.3 Linear Polarization with Two Widely Separated
Frequencies 121
6.1.4 Linear Polarization with Two Closely Separated
Frequencies 123
6.2 Dual-Band with Two-Layer Substrates 123
6.2.1 High-Frequency Elements above Low-Frequency
Elements 124
6.2.2 Low-Frequency Elements above High-Frequency
Elements 125
6.3 Multiband Refl ectarray with More than Two Frequencies 131
References 134
7. Recent and Future Applications 137
7.1 Infl atable/Thin-Membrane Refl ectarrays 137
7.1.1 X-Band 1-m Infl atable Refl ectarray 138
7.1.2 Ka-Band 3-m Infl atable Refl ectarray 139
7.2 Contoured Beam Refl ectarrays for Space Applications 143
7.2.1 Pattern Synthesis 145
7.2.2 Practical Designs 150
7.3 Multi-Beam Refl ectarrays 169
7.4 Amplifying Refl ectarray 177
7.5 Folded Compact Refl ectarray 182
viii CONTENTS
7.6 Cassegrain Offset-Fed Confi gurations 190
7.7 Very Large Aperture Applications 194
7.8 Beam Scanning Refl ectarrays 195
References 201
Index 207

PREFACE
The concept of the refl ectarray antenna was introduced in 1963 using waveguide
elements, but the real interest in refl ectarrays only came about in the
late 1980s with the development of low - profi le printed antennas. For this
reason, the printed refl ectarray can be considered as a fairly new type of
antenna. A refl ectarray is made up of an array of radiating elements that
provide a preadjusted phasing to form a focused beam when it is illuminated
by a feed, in a similar way to a parabolic antenna. Printed refl ectarrays combine
certain advantages of refl ector antennas and phased arrays. They are manufactured
on a planar substrate using printed circuit technology and offer the
possibility of beam steering as phased arrays; on the other hand, the feeding
mechanism (as in a refl ector antenna) eliminates the complexity and losses of
the feeding network used in planar arrays, thus providing a higher effi ciency.
Refl ectarrays have demonstrated their capability to produce contoured beams,
which are conventionally generated by using shaped refl ectors or phased
arrays. Recently, some potential applications of refl ectarrays in space have
been researched, such as contoured beam antennas for Direct Broadcast Satellites
and very large infl atable antennas. However, there is one major shortcoming
of the refl ectarray, which is its narrow - bandwidth behavior, but the
bandwidth has been signifi cantly increased in recent developments.
The purpose of this book is to present a comprehensive overview of
refl ectarray antennas, including the operating principles, their advantages
over other antennas, their development history, analysis techniques, practical
design procedures, bandwidth issues, and wideband techniques, as well as
their applications and recent developments. This book can be used as a reference
book for graduate students, researchers, and antenna engineers. Furthermore,
it will allow the reader to become more familiar with this relatively
new type of antenna and will provide valuable support in designing these
antennas.
The book is organized into seven chapters. Chapter 1 presents a general
introduction to refl ectarray antennas, including their operating principles, the
most common implementations, their most signifi cant features, and a description
of the advantages and drawbacks with respect to other types of antenna.
A detailed development history of the refl ectarray since its invention is presented
in Chapter 2 . It will greatly enhance the ability of an engineer to
understand the refl ectarray system if he is familiar with the evolution of the
refl ectarray antenna. In the same chapter, performance comparisons with two
x PREFACE
similar technologies, array lens and Fresnel - Zone plate refl ector, are also
briefl y discussed.
The refl ectarray is a relatively complex antenna, and an accurate analysis
technique is essential for precise predictions of the radiation features, such
as effi ciency, gain, co - and cross - polar radiation patterns, and bandwidth.
Chapter 3 provides a detailed discussion of the different approaches used for
the analysis of refl ectarrays. A full - wave technique based on the Method of
Moments in the Spectral Domain and Floquet modal expansions, under the
assumption of local periodicity to account for mutual couplings, is described
in detail. Although the method of analysis has already been described in
journal papers, in this chapter the method is focused to the specifi c analysis
of refl ectarray antennas. The analysis technique is used to compute the
phase response and losses of different types of refl ectarray elements, such as
printed patches with attached or aperture - coupled stubs and varying - sized
patches in single - and multiple - layer confi gurations. Several results are presented
to validate the analysis tool and to show the capabilities and limitations
of each element type. Finally, the chapter describes a technique for the computation
of co - and cross - polar radiation patterns, including the modeling of
the feed - horn.
Chapter 4 is devoted to providing practical skills for the design of the
refl ectarray antenna. Apart from the analysis technique, there are some aspects
that must be taken into account during the design of a refl ectarray antenna,
such as the selection criteria for the phasing elements, the appropriate spacing
to provide enough phase - range and avoid the appearance of grating lobes, the
geometrical defi nition of the antenna, etc. These aspects are essential to achieving
a good effi ciency and are discussed in Chapter 4 .
The most severe drawback in refl ectarray operation is its narrow frequency
band, and much effort has been made in recent years to overcoming this limitation.
Chapter 4 is devoted to bandwidth improvement in refl ectarrays. The
bandwidth in refl ectarrrays is mainly limited by two different factors: the phase
response of the radiating element and the different path lengths from the feed
to the phase front. After discussing the two factors in detail, several solutions
are presented in Chapter 5 to improve the bandwidth. Two different types of
broadband refl ectarray elements are analyzed: one based on stacked patches
of varying size and the other using patches with aperture - coupled lines. A 16
percent bandwidth was achieved by using two stacked patches as refl ectarray
element. On the other hand, the effect of different path lengths is only signifi -
cant in large refl ectarrays as in the case of antennas for space applications.
Several techniques are described to overcome the bandwidth limitation
produced by the different path lengths and some results are given for large
antennas. The fi rst technique is based on the implementation of delay lines
aperture - coupled to printed patches to compensate for the real phase delay
in the whole range (several times 360 ° ), the second one consists of compensating
the spatial phase delay in a given frequency band with the phase of the
refl ection coeffi cient, and the last one, more suitable for very large apertures,
PREFACE xi
uses a faceted confi guration that approximates the shape of a parabolic
surface.
Chapter 6 presents dual - band and multi - band techniques for a single refl

ACKNOWLEDGMENTS
The work presented in this book was supported in part by the following
institutions:
National Aeronautics and Space Administration (NASA)
European Space Agency (ESA)
Jet Propulsion Laboratory (JPL), California Institute of Technology
Spanish Commission of Science and Technology (CICYT)
Mexican National Council of Science and Technology (CONACYT).
The authors wish to express their gratitude to E. Carrasco and M. Arrebola,
from Universidad Politecnica de Madrid, to Dr. Agustin Zornoza, from EADS
Astrium Ltd, to Dr. Herve Legay from Thales Alenia Space, and to Dr. Leri
Datashvili from Technical University of Munich, for providing some material
presented in this book. Special thanks are expressed to Professor W. Menzel
of University of Ulm (Germany) for making available some pictures and
results of his folded refl ector antennas. Special thanks are also extended to
Dr. R. J. Mailloux of USAF for his encouragement and suggestion of writing
this book.

【2008新书】John.Wiley.IEEE.Reflect.Array.Antennas.LRN.INT

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