Compact Multifunctional Antennas for Wireless Systems E-Book

Table of Contents

Series Page

Title Page

Copyright

Preface

Chapter 1: Compact Multifunctional Antennas in Microwave Wireless Systems

1.1 Introduction

1.2 Microwave Components in Wireless Systems

1.3 Planar and Nonplanar Antennas in Compact Wireless Systems

1.4 Multifunctional Antennas and Microwave Circuits

1.5 Miniaturization Techniques for Multifunctional Antennas

1.6 Design Processes and Considerations

1.7 Design Tools and Software

1.8 Overview of the Book

References

Chapter 2: Multifunctional Passive Integrated Antennas and Components

2.1 Development of Passive Integrated Antennas and Components

2.2 Antenna Filters

2.3 Balun Filters

2.4 Antenna Package

2.5 Conclusions

References

Chapter 3: Reconfigurable Antennas

3.1 Introduction

3.2 Design Considerations and Recent Developments

3.3 Frequency-Reconfigurable Antennas

3.4 Pattern-Reconfigurable Antennas

3.5 Multi-reconfigurable Antennas

3.6 Conclusions

References

Chapter 4: Receiving Amplifying Antennas

4.1 Introduction

4.2 Design Criteria and Considerations

4.3 Wearable Low-noise Amplifying Antenna

4.4 Active Broadband Low-Noise Amplifying Antenna

4.5 Conclusions

References

Chapter 5: Oscillating Antennas

5.1 Introduction

5.2 Design Methods for Microwave Oscillators

5.3 Recent Developments and Issues of Antenna Oscillators

5.4 Reflection-Amplifier Antenna Oscillators

5.5 Coupled-load Antenna Oscillators

5.6 Conclusions

References

Chapter 6: Solar-Cell-Integrated Antennas

6.1 Integration of Antennas with Solar Cells

6.2 Nonplanar Solar-cell-integrated Antennas

6.3 Planar Solar-cell-integrated Antennas

6.4 Conclusions

References

Index

Wiley Series

For further information visit: the book web page http://www.openmodelica.org, the Modelica Association web page http://www.modelica.org, the authors research page http://www.ida.liu.se/labs/pelab/modelica, or home page http://www.ida.liu.se/~petfr/, or email the author at [email protected]. Certain material from the Modelica Tutorial and the Modelica Language Specification available at http://www.modelica.org has been reproduced in this book with permission from the Modelica Association under the Modelica License 2 Copyright © 1998–2011, Modelica Association, see the license conditions (including the disclaimer of warranty) at http://www.modelica.org/modelica-legal-documents/ModelicaLicense2.html. Licensed by Modelica Association under the Modelica License 2.

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Copyright © 2011 by the Institute of Electrical and Electronics Engineers, Inc.

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Library of Congress Cataloging-in-Publication Data:

Lim, Eng Hock, 1974-

Compact multifunctional antennas for wireless systems / Eng Hock Lim and Kwok Wa Leung.

p. cm.

Includes bibliographical references.

ISBN 978-0-470-40732-5

1. Antennas (Electronics) 2. Wireless communication systems-Equipment and supplies.

I. Leung, K. W. (Kwok Wa), 1967- II. Title.

TK7871.6.L56 2012

621.384'135–dc23

2011040051

Preface

The objective of this book is to provide up-to-date information on modern multifunctional antennas and microwave circuits. Today, it is a trend to bundle multiple components into a single module to achieve high compactness and good signal quality. In the last two decades, the multifunctional concept has already been applied extensively to miniaturize various active and passive radio-frequency devices. Active antennas can be considered one of the earliest multifunctional antennas that have received a high level of attention from both academia and industry. Due to the rapid advancement of packaging technologies, various multifunctional devices can be made easily using such new techniques as antenna-on-package, antenna-in-package, and low-temperature-co-fired. Although there are many books describing the design of active and passive microwave systems, the multifunctional concept has yet to be fully explored for antennas and microwave circuits.

In this book, antennas are incorporated with active and passive microwave devices to design various multifunctional modules. The first part of the book introduces several novel passive components, such as an antenna filter and an antenna packaging cover. To make the coverage more complete, the development of the balun filter, a relatively new component, is also covered. Then, switches are integrated into antenna structures to achieve reconfiguration. Some recent work from the Institute of Applied Physics at the University of Electronic Science and Technology of China in Chengdu on frequency-, pattern-, and multireconfigurable antennas is discussed. Oscillating and amplifying antennas, which are among the conventional active antennas that have received much interest in recent decades, are featured in the book. Since the 1970s, oscillating antennas have been explored extensively as to power combining, phase locking, and beam switching. The reflection amplifier and coupled-load antenna oscillators are both visited and attention has been directed to their special applications. For example, it is shown that such active antennas can be made wearable as well as being used as a packaging cover. We focus on studying the receiving amplifying antennas, as the transmitting counterparts have been well explored in many other books. The co-design process of the amplifying antenna is discussed in detail. In the final part of the book, antennas are combined with solar cells to provide new applications. The design methods for various multifunctional antennas and microwave circuits are discussed, along with the elucidation of some important contemporary issues. We also explore the use of multiple software design tools in co-designing multifunctional antennas.

Acknowledgments

First, we would like to express our sincere gratitude to Professor Kai Chang (University of Texas, A&M) for his support of publishing this book. Special thanks go to Professor Kwai Man Luk for his kind encouragement of writing up this book. Another important person to whom we are thankful is Professor Quan Xue (City University of Hong Kong) for sharing his knowledge and experience in many discussions. We are particularly appreciative of the assistance provided by many colleagues at the State Key Laboratory of Millimeter Wave, City University of Hong Kong.

Our appreciation goes to Dr. Xue-Song Yang, Professor Shao-Qiu Xiao, and Professor Bing-Zhong Wang, all from the University of Electronic Science and Technology of China, for sharing their recent research work on reconfigurable antennas (Chapter 3).  We would like to express many thanks to Professor Jian-Xin Chen (Nantung University, China), Dr. Jin Shi (I2R, Singapore), Dr. Yong-Mei Pan (City University of Hong Kong), Dr. Shao-yong Zheng (City University of Hong Kong), and Dr. Kok Keong Chong (Universiti Tunku Abdul Rahman, Malaysia) for their help on countless occasions and their willingness to share much useful information.

Heartfelt gratitude to the following friends and students for their hard work in broadening the horizon of multifunctional antennas and microwave circuits: Xiao-Sheng Fang (City University of Hong Kong), Hong-Yik Wong (Universiti Tunku Abdul Rahman, Malaysia), Choon-Chung Su (Universiti Tunku Abdul Rahman, Malaysia), Chi-Hwa Ng (Agilent Technologies Sdn. Bhd., Malaysia), Gim-Hui Khor, and Kwan-Keen Chan.

Finally, we would like to express our sincere thanks to Dr. Fook-Long Lo (Universiti Tunku Abdul Rahman, Malaysia) for spending many hours polishing the manuscript.

E. H. Lim

K. W. Leung

City University of Hong Kong

Kowloon, Hong Kong SAR

January 8, 2012

Chapter 1

Compact Multifunctional Antennas in Microwave Wireless Systems

1.1 Introduction

The mission of a communication system is to get messages delivered with minimum distortion. Messages such as voices, pictures, and movies are a series of natural signals over time, operating at frequencies ranging from a few to hundreds of kilohertz. Figure 1.1 shows the signal flows in a communication system. There are two types of communication systems: wired and wireless. Examples of wired systems are telephony and optical systems in which cables and fibers are deployed for transmitting signals, respectively. The telephone, patented by Alexander Graham Bell in 1876 (1), was the earliest available communication gadget that enabled the conversion of vocal messages into electronic signals. In 1966, Charles Kao (2) showed that a glass strand is able to be made into a signal-transmitting medium. Since then, tens of thousands of miles of optical fibers have been laid to carry information on land and across the oceans. The rapid advancement of optical technologies makes possible the transmission of signals in bulk using light, and it has led to a surge of internet technologies since the last century. However, the major drawback of wired communications is that it does not allow user mobility. Geographical features and human-made constructions can also pose a hindrance for laying out long wires or cables. As early as 1900, it was shown by Guglielmo Marconi that an electromagnetic wave is able to carry signals through air and free space. Since then, numerous analog and digital wireless communication systems have been developed. shows a typical analog wireless system, which has many functional blocks performing complex operations such as reception, transmission, modulation, and demodulation. As can be seen from the figure, the transmitting path consists basically of a modulator and a radio-frequency (RF) transmitter, while the receiving path has a demodulator and an RF receiver. In an analog wireless system all the signals are continuous. As shown in , the system can easily be made digital by incorporating analog-to-digital and digital-to-analog converters. In modern digital wireless systems, the modulation, demodulation, coding, and decoding processes can be performed easily by superfast microprocessors and digital signal processors. An advantage of digital signal is that many powerful coding schemes, such as the Viterbi, Trellis, and Turbo codes, can easily be imposed on the signal sequence (in “0” or “1”) to enhance its robustness against noise (3). The coding process is usually accomplished by connecting an encoder to the transmitting path and a decoder to the receiving path simultaneously. The encoder can be a circuit, a software program, or firmware (an algorithm burned into programmable hardware) that the source bits to channel bits. On the other end, a decoder is employed to retrieve the original message from the channel bits received. Various security features can also be added during the encoding–decoding process. As the encoder and decoder do not change the fundamental frequencies of a message signal, they are usually called baseband modules.

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Lesen Sie weiter in der vollständigen Ausgabe!

Lesen Sie weiter in der vollständigen Ausgabe!

Lesen Sie weiter in der vollständigen Ausgabe!

Lesen Sie weiter in der vollständigen Ausgabe!