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BestsellerE-book
Author Yarman, Binboga Siddik.

Title Design of digital phase shifters for multipurpose communication systems / Binboga Siddik Yarman.

Publication Info. Denmark : River Publishers, [2019]
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Online ebook via EBSCO. Access restricted to current Rider University students, faculty, and staff.
Instructions for reading/downloading the EBSCO version of this ebook

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Description 1 online resource (558 pages).
text file
Series River Publishers series in communications
River Publishers series in communications.
Contents Preface xi Acknowledgments xv -- List of Figures xvii -- List of Tables xxv -- List of Abbreviations xxvii -- 1 Fundamentals of Digital Phase Shifters 1 -- 1.1 Introduction 1 -- 1.2 Concept of Digital Phase Shift 3 -- 1.3 Digital Phase Bits 4 -- 1.4 n-Bit Phase Shifter 5 -- 1.5 Phase Error 9 -- 1.6 Practical Issues 12 -- 1.7 Types of Digital Phase Shifters 12 -- References 17 -- 2 Scattering Parameters for Lossless Two-Ports 19 -- 2.1 Introduction 19 -- 2.2 Formal Definition of Scattering Parameters 20 -- 2.3 Generation of Scattering Parameters for Linear Two-Ports 34 -- 2.4 Transducer Power Gain in Forward and Backward Directions 37 -- 2.5 Properties of the Scattering Parameters of Lossless Two-Ports 38 -- 2.6 Blashke Products or All Pass Functions 45 -- 2.7 Possible Zeros of a Proper Polynomial f(p) 45 -- 2.8 Transmission Zeros 48 -- 2.9 Lossless Ladders 53 -- 2.10 Further Properties of the Scattering Parameters of the Lossless Two-Ports 55 -- 2.11 Transfer Scattering Parameters 56 -- 2.12 Cascaded (or Tandem) Connections of Two-ports 57 -- 2.13 Construction of an n-Bit Phase Shifter by Cascading Phase-Shifting Cells 59 -- 3 Transmission Lines as Phase Shifter 63 -- 3.1 Ideal Transmission Lines 63 -- 3.2 Time Domain Solutions of Voltage and Current Wave Equations 68 -- 3.3 Model for a Two-Pair Wire Transmission Line as an Ideal TEM Line 69 -- 3.4 Model for a Coaxial Cable as an Ideal TEM Line 69 -- 3.5 Field Solutions for TEM Lines 70 -- 3.6 Phasor Solutions for Ideal TEM Lines 70 -- 3.7 Steady-State Time Domain Solutions for Voltage and Current at any Point z on the TEM Line 72 -- 3.8 Definition of the Major Parameters of a Transmission Line 72 -- 3.9 Voltage and Current Expression in Terms of Incident and Reflected Waves 74 -- 3.10 Reflection Coefficient S 74 -- 3.11 TEM Lines as Circuit or "Distributed" Elements 74 -- 3.12 Voltage and Current Expressions at the Load End; Load Reflection Coefficient on the z = 0 Plane 75 -- 3.13 Voltage and Current Expressions at the Source-End; Input Reflection Coefficient on the z = ]]>?<![CDATA[L Plane 76.
9.10 Analysis of the Phase Shifting Performance of 3S-DPS 353 -- 9.11 Performance Measure of Digital Phase Shifters 356 -- 9.12 Investigation of Unequal Phase Distributions between the States 364 -- 9.13 Practical Lossy Design of a 3D-DPS 371 -- 9.14 Investigation of Unequal Phase Distribution between the States with Negative Phases: An Alternative Approach 393 -- 9.15 On-Chip Inductor Design 405 -- References 433 -- 10 -- 360À T-Section Digital Phase Shifter 435 -- 10.1 Derivation of Design Equations for a 360À T-Section Digital Phase Shifter 435 -- 10.2 Algorithm to Design 360À T-Section Digital Phase Shifter 439 -- 10.3 Unequal Distribution of Distribution of the Phase Shift between the States 445 -- 10.4 Analysis of the Phase Performance of the 360À T-Section DPS Topology with Lossy Components 446 -- 10.5 Algorithm: Design of a Lossy 360À T-Section DPS 449 -- 10.6 Physical Implementation of 360À T-DPS 454 -- References 461 -- 11 -- 360À PI-Section Digital Phase Shifter 463 -- 11.1 Algorithm to design 360À PI-Section Digital Phase Shifter 467 -- 11.2 Unequal Distribution of the Phase Shifts between the States 472 -- 11.3 Analysis of the Phase Performance of the 360À PI-Section DPS Topology with Lossy Components 473 -- 11.4 Algorithm: Design of a Lossy 360À PI-Section DPS 476 -- 11.5 Physical Implementation of 360À PI-DPS 484 -- References 492 -- 12 -- 180À High-pass-based PI-Section Digital Phase Shifter 493 -- 12.1 Derivation of Design Equations for a 180À PI-Section Digital Phase Shifter 493 -- 12.2 Algorithm to Design 180À PI-Section Digital Phase Shifter 496 -- 12.3 Analysis of the Phase Performance of the 360À PI-Section DPS Topology with lossy components 501 -- 12.4 Algorithm: Design of a Lossy 180À HPI Section DPS 503 -- 12.5 Physical Implementation of 180À HPI-DPS 509 -- References 514 -- Index 517 -- About the Author 525.
Summary Design of Digital Phase Shifters for Multipurpose Communication Systems aims to cover a new emerging need in designing digital phase shifters for modern communication systems. With the advancement of new generation mobile communication systems, directed beams save a substantial amount of RF-power, and improve the noise immunity. In this regard, beam-forming circuits, namely, digital phase shifters constitute essential parts the antenna arrays. Therefore, this book is devoted to design of digital phase shifters for various communications systems. In the good old days, phase shifter design requirements used to demand narrow bandwidth with no physical size constraints. Nowadays, they must be compact and suitable for Very Large Scale Integrated Circuits (VLSI) or Microwave Monolithic Integrated Circuit (MMIC) implementation with Wide Phase Range (WPR) and Wide Frequency Band (WFB). Since the 1980s, the author has been designing digital phase shifters for various applications. He started to work with loaded lines phase shifters, and then employed branch line couplers to achieve wider frequency bands. In order to reduce the physical size, he used a 3 element Symmetric LC ladder based T or PI configurations. In order to achieve broad frequency band with large phase range, usage of LC lattice structures is inevitable. Lately, the author designed phase shifters using both lowpass and highpass LC ladder and lattice based switched-structures, which are suitable for monolithic implementation. In the course of design, MOS transistors were employed as switching elements. This book includes several novel digital phase shifter topologies, which provides wide phase range and wideband operation. Technical topics discussed in the book include: * Basic Concept of Antenna Arrays * Concept of Digital Phase Bit * Scattering Parameters to analyze the electric performance of phase shifters * Transmission Lines as circuit elements to construct practical phase shifters * Loaded Line Digital Phase Shifters (DPS) * 180À - Lowpass Based T/PI Section DPS * 180À - Highpass Based T/PI Section DPS * 180À 3-Element LC T/PI Section DPS * 180À Wide Phase Range, Wide Frequency Band Symmetric Lattice Based DPS For each topology presented, explicit design equations are provided and programs to assess the electric performance of each topology is developed in a MatLab environment. It is expected that the reader will be self-sufficient to design and implement the digital phase shifters topologies presented in this book.
Local Note eBooks on EBSCOhost EBSCO eBook Subscription Academic Collection - North America
Subject Mobile communication systems.
Mobile communication systems.
Digital communications.
Digital communications.
Phase shifters -- Design and construction.
Phase shifters.
Genre/Form Electronic books.
Other Form: Print version: Yarman, Binboga Siddik. Design of Digital Phase Shifters for Multipurpose Communication Systems. Aalborg : River Publishers, ©2019 9788770220941
ISBN 877022093X (electronic book)
9788770220934 (electronic book)

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