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Design and Applications of Active Integrated Antennas Unabridged edition [Hardback]

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  • Formāts: Hardback, 280 pages
  • Izdošanas datums: 31-May-2018
  • Izdevniecība: Artech House Publishers
  • ISBN-10: 1630813583
  • ISBN-13: 9781630813581
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Design and Applications of Active Integrated Antennas Unabridged editionPalielināt
  • Formāts: Hardback, 280 pages
  • Izdošanas datums: 31-May-2018
  • Izdevniecība: Artech House Publishers
  • ISBN-10: 1630813583
  • ISBN-13: 9781630813581
Citas grāmatas par šo tēmu:
Permanent link: https://www.kriso.lv/db/9781630813581.html
Keywords:
Using Active Integrated Antenna (AIA) instead of the conventional sub-system designs of individual components will provide a system designer with more features and enhance performance. This book explains how active integration and co-design between the active components (amplifier, oscillator, mixer, diodes) and the antenna can provide better power transfer, higher gains, increased efficiencies, switched beam patterns and smaller design footprints.

As new antenna designs will require closer integration with other radio electronics, AIA are expected to be used in future wireless terminals. The book introduces the fundamental aspects of AIA and discusses in detail the various types of AIA, such as oscillator, amplifier, mixer, transceiver, frequency reconfigurable, on-chip and on package, as well as non-foster AIA covering various frequency bands and wireless standards. It presents co-design procedures for AIA applied to multiple-input-multiple-output (MIMO) front ends as well as examples of narrowband and wideband designs.

This is the first book to elaborate on AIA design with detailed step-by-step tutorials and the use of software packages (provided in an accompanying CD). It contains real world cases and illustrations, and is a must-have title for practicing and research engineers.

Recenzijas

An excellent new references is a recommended pick for college-level collections strong in electrical engineering and antenna design, offering engineers solid discussions of theory, applications, and different systems and their management. Mohammad S. Sharawi and Oualid Hammi's Design and Applications of Active Integrated Antennas offers professionals the latest methods in designing active integrated antennas for wireless devices, considering design protocol, interfaces between active components, increasing efficiency, and working between the active and passive parts of AIA. Design examples for such systems cover both narrowband and wideband applications and incorporate the latest design methods and applications. Both are solid references college-level electrical engineers will find essential. * Midwest Book Review *

Preface xi
Acknowledgments xv
Chapter 1 Introduction
1(20)
1.1 Review of Wireless Communication Technology Evolution
1(3)
1.2 Transmitter and Receiver Architectures
4(10)
1.2.1 RF Transmitter Architectures
5(4)
1.2.2 RF Receiver Architectures
9(1)
1.2.3 Digital IF RF Transceivers
9(5)
1.3 Technology Trends
14(5)
1.4 Conclusions
19(2)
References
19(2)
Chapter 2 Impedance Matching Methods
21(32)
2.1 Introduction to Impedance Matching
21(2)
2.2 Narrowband Matching
23(19)
2.2.1 Lumped Element Matching Using the L-Network
24(4)
2.2.2 Example of the Lumped Element L-Matching Method
28(2)
2.2.3 Quality Factor of a Matching Network
30(2)
2.2.4 Lumped Element Matching Using the T-Networks and π-Networks
32(2)
2.2.5 Example of T-Matching Using Lumped Elements
34(2)
2.2.6 Distributed Element Matching
36(4)
2.2.7 Example of Distributed Element Matching
40(2)
2.3 Wideband Matching
42(6)
2.3.1 Constant-Q Circles Technique
42(2)
2.3.2 Real Frequency Technique
44(3)
2.3.3 Non-Foster-Based Technique
47(1)
2.4 Use of CAD for Matching Network Design
48(2)
2.5 Conclusions
50(3)
References
51(2)
Chapter 3 Amplifier Design
53(36)
3.1 Generic Approach for Amplifiers Design
53(3)
3.2 LNA Design
56(11)
3.2.1 Noise Analysis in Cascaded Systems
56(6)
3.2.2 Noise Analysis in Amplifiers
62(1)
3.2.3 Design Procedure
63(2)
3.2.4 Design Example
65(2)
3.3 Maximum Gain Amplifier Design
67(3)
3.3.1 Matching Requirements
67(2)
3.3.2 Design Procedure
69(1)
3.3.3 Design Example
70(1)
3.4 Amplifier Design for Gain-Noise Trade-Off
70(14)
3.4.1 Gain Circles
71(7)
3.4.2 Design Procedure
78(1)
3.4.3 Design Examples
79(5)
3.5 PA Design
84(2)
3.5.1 Load-Pull Analysis
85(1)
3.5.2 Design Procedure
86(1)
3.6 Conclusions
86(3)
References
87(2)
Chapter 4 Antenna Fundamentals
89(44)
4.1 Antenna Features and Metrics
89(5)
4.1.1 Input Impedance, Resonance, and Bandwidth
89(1)
4.1.2 Radiation Pattern, Efficiency, Polarization, Gain, and MEG
90(4)
4.2 Antenna Types
94(12)
4.2.1 Dipole Antennas
94(3)
4.2.2 Monopole Antennas
97(2)
4.2.3 Patch Antennas
99(4)
4.2.4 Loop Antennas
103(1)
4.2.5 Slot Antennas
104(2)
4.3 Antenna Arrays
106(4)
4.3.1 Linear Antenna Arrays
107(1)
4.3.2 Planar Antenna Arrays
108(1)
4.3.3 Circular Antenna Arrays
109(1)
4.4 MIMO Antenna Systems
110(11)
4.4.1 Features of MIMO Antennas and Systems
110(1)
4.4.2 Performance Metrics of MIMO Antenna Systems
111(6)
4.4.3 MIMO Antenna System Examples
117(4)
4.5 Computer-Aided Antenna Design
121(6)
4.5.1 Printed Monopole Antenna Modeling Example Using HFSS
122(2)
4.5.2 Printed PIFA Antenna Modeling Example Using CST
124(3)
4.6 Conclusions
127(6)
References
127(6)
Chapter 5 Active Integrated Antennas
133(36)
5.1 Performance Metrics of AIAs
133(5)
5.1.1 Frequency Bandwidth
133(1)
5.1.2 Power Gain
134(1)
5.1.3 Total Efficiency
134(1)
5.1.4 Stability
134(1)
5.1.5 Noise Performance
135(1)
5.1.6 Example
135(3)
5.2 Oscillator-Based AIAs
138(5)
5.2.1 Design Outline
139(1)
5.2.2 Examples
140(3)
5.3 Amplifier-Based AIAs
143(4)
5.3.1 Design Outline
144(1)
5.3.2 Examples
145(2)
5.4 Mixer-Based AIAs
147(5)
5.4.1 Design Outline
147(3)
5.4.2 Examples
150(2)
5.5 Transceiver-Based AIAs
152(2)
5.5.1 Design Outline
152(1)
5.5.2 Examples
153(1)
5.6 Other Types of AIAs
154(8)
5.6.1 Frequency, Polarization, and Pattern Reconfigurable Antennas
154(4)
5.6.2 On-Chip/On-Package Antennas
158(3)
5.6.3 Non-Foster Antennas
161(1)
5.7 Conclusions
162(7)
References
163(6)
Chapter 6 A Codesign Approach for Designing AIAs
169(20)
6.1 Detailed AIA Codesign Procedure
169(3)
6.2 Narrowband AIA Codesign Examples
172(4)
6.3 Wideband AIA Codesign Examples
176(2)
6.4 UWB AIA Codesign Approach
178(9)
6.5 Conclusions
187(2)
References
187(2)
Appendix A Using ADS Tutorial
189(8)
Example A.1 RF Lumped Component-Based BPF
189(4)
Example A.2 RF Amplifier Characteristics Based on Its S-Parameters
193(4)
Appendix B Using MWO Tutorial
197(12)
Example B.1 Lowpass RF Filter
197(8)
Example B.2 RF Filter Design with PCB Trace Effects
205(4)
Appendix C Using HFSS Tutorial
209(12)
Appendix D Using CST Tutorial
221(12)
List of Acronyms 233(4)
About the Authors 237(2)
Index 239
Mohammad S. Sharawi is currently a Professor of Electrical Engineering at King Fahd University of Petroleum and Minerals (KFUPM), Dhahran, Saudi Arabia. He is the founder and director of the Antennas and Microwave Structure Design Laboratory (AMSDL). Prof. Sharawi is a Senior Member IEEE and Fellow IET. Oualid Hammi is an associate professor in the Electrical Engineering Department at the American University of Sharjah, Sharjah, United Arab Emirates. He is also an adjunct associate professor of electrical and computer engineering at the University of Calgary, AB, Canada. He received his M.Sc. in electrical engineering from the Ecole Polytechnique de Montreal, Universite de Montreal, Montreal, QC, Canada and his Ph.D. in electrical engineering from the University of Calgary, AB, Canada.