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Handbook of smart antennas for RFID systems / / Nemai Chandra Karmakar
| Handbook of smart antennas for RFID systems / / Nemai Chandra Karmakar |
| Autore | Karmakar Nemai Chandra <1963-> |
| Edizione | [1st edition] |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : Wiley, , c2010 |
| Descrizione fisica | 1 online resource (646 p.) |
| Disciplina |
621.384135
681/.2 |
| Altri autori (Persone) | KarmakarNemai Chandra |
| Soggetto topico |
Radio frequency identification systems - Design and construction
Adaptive antennas - Design and construction Phased array antennas - Design and construction |
| ISBN |
1-282-84904-2
9786612849046 1-118-07439-4 0-470-87217-9 0-470-87216-0 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Forward -- Preface -- Acknowledgement -- Section I: Introduction to RFID -- Chapter 1: The Evolution of RFID (B. Jamali, The University of Adelaide) -- Chapter 2: Introduction to RFID systems (S.M. Roy and N.C. Karmakar, Monash University) -- Chapter 3: Recent Paradigm Shift in RFID and Smart Antennas (N.C. Karmakar, Monash University) -- Section II: RFID Reader Systems -- Chapter 4: Modern RFID Readers (S. Parardovic and N.C. Karmakar, Monash University) -- Chapter 5: A Development Platform for SDR based RFID Reader (B. Jamali, The University of Adelaide) -- Section III: Physical Layer Developments of Smart Antennas for RFID Systems -- Chapter 6: RFID Reader Antenna -- A Smart Design Approach (S.M. Roy and N.C. Karmakar, Monash University) -- Chapter 7: Handheld Reader Antenna at 5.8 GHz (S.M. Roy and N.C. Karmakar, Monash University) -- Chapter 8: FPGA Controlled Phased Array Antenna Development for UHF RFID Reader (N.C. Karmakar, P. Zakavi and M. Kumbukage, Monash University) -- Chapter 9: Optically Controlled Phased Array Antennas for UWB RFID Reader (A. Arokiaswami, P. Q. Thai, Nanyang Technological University and N.C. Karmakar, Monash University) -- Chapter 10: Adaptive Antenna Arrays for RFID (M. Trinkle and B. Jamali, The University of Adelaide) -- Chapter 11: Design of Portable RFID Smart Antenna System?A Practical Approach (J.S. Fu, Chang Gung University, W. Liu, Nanyang Technological University and N.C. Karmakar, Monash University) -- Section IV: DOA and Localization of RFID Tags using Smart Antennas -- Chapter 12: Direction of Arrival Estimation based on A Single Port Smart Antenna for RFID Applications (Chen Sun, National Institute of Information and Communication Technology (NICT) and N.C. Karmakar, Monash University) -- Chapter 13: DOA Geo-location in Real-Time Indoor WiFi System Utilizing Smart Antennas (C.H. Lim, B.P. Ng, M.H. Er, J.P. Lie and W. Wang, Nanyang Technological University) -- Chapter 14: Direction of Arrival (DoA) Estimation of Impulse Radio UWB RFID Tags (J.P. Lie, B.P. Ng, C.H. Lim and C.M. S. See, Nanyang Technological University).
Chapter 15: Localization techniques in single and multihop wireless networks (V. Lakafosis, Rushi Vyas and M.M. Tentzeris, Georgia Institute of Technology) -- Section V: Multi-Antenna RFID Tags -- Chapter 16: Multi-antenna Chipless RFID Tags (I. Balbin and N. C. Karmakar, Monash University) -- Chapter 17: Link Budgets for Backscatter Radio Systems (J.D. Griffin and G.D. Durgin, Georgia Institute of Technology) -- Chapter 18: Fading Statistics for Multi-Antenna RF Tags (J.D. Griffin and G.D. Durgin, Georgia Institute of Technology) -- Section VI: MIMO Antennas for RFID Systems -- Chapter 19: Optimum Power Allocation in Multiple-Input-Multiple-Output (MIMO) Systems under Independent Rayleigh Fading (J.S. Fu, Chang Gung University, W. Liu, Nanyang Technological University and N. C. Karmakar, Monash University) -- Chapter 20: Low-cost and Compact RF-MIMO Transceivers (I. Santamaria, J. Via, V. Elvira, J. Ibanez, J. Perez, University of Cantabria -- R. Eickhoff, and U. Mayer, Dresden University of Technology) -- Chapter 21: Blind Channel Estimation in MIMO using Multi-carrier CDMA (A. Rahim, Monash University, K. M. Ahmed, Asian Institute of Technology and N. C. Karmakar, Monash University) -- Section VII: Anti-Collision Algorithm and Smart Antennas for RFID Systems -- Chapter 22: Anti-collision Algorithm and Smart Antennas for RFID Systems (Q. J. Teoh and N. C. Karmakar, Monash University) -- Chapter 23: RFID Anti-Collision Algorithms with Multi-Packet Reception (J. Lee, Hewlett-Packard Laboratories, T. Kwon, Seoul National University) -- Chapter 24: Anti-Collision of RFID tags using Capturing Effect (Q. J. Teoh and N. C. Karmakar, Monash University). |
| Record Nr. | UNINA-9910141043603321 |
Karmakar Nemai Chandra <1963->
|
||
| Hoboken, New Jersey : , : Wiley, , c2010 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Handbook of smart antennas for RFID systems / / Nemai Chandra Karmakar
| Handbook of smart antennas for RFID systems / / Nemai Chandra Karmakar |
| Autore | Karmakar Nemai Chandra <1963-> |
| Edizione | [1st edition] |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : Wiley, , c2010 |
| Descrizione fisica | 1 online resource (646 p.) |
| Disciplina |
621.384135
681/.2 |
| Altri autori (Persone) | KarmakarNemai Chandra |
| Soggetto topico |
Radio frequency identification systems - Design and construction
Adaptive antennas - Design and construction Phased array antennas - Design and construction |
| ISBN |
1-282-84904-2
9786612849046 1-118-07439-4 0-470-87217-9 0-470-87216-0 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Forward -- Preface -- Acknowledgement -- Section I: Introduction to RFID -- Chapter 1: The Evolution of RFID (B. Jamali, The University of Adelaide) -- Chapter 2: Introduction to RFID systems (S.M. Roy and N.C. Karmakar, Monash University) -- Chapter 3: Recent Paradigm Shift in RFID and Smart Antennas (N.C. Karmakar, Monash University) -- Section II: RFID Reader Systems -- Chapter 4: Modern RFID Readers (S. Parardovic and N.C. Karmakar, Monash University) -- Chapter 5: A Development Platform for SDR based RFID Reader (B. Jamali, The University of Adelaide) -- Section III: Physical Layer Developments of Smart Antennas for RFID Systems -- Chapter 6: RFID Reader Antenna -- A Smart Design Approach (S.M. Roy and N.C. Karmakar, Monash University) -- Chapter 7: Handheld Reader Antenna at 5.8 GHz (S.M. Roy and N.C. Karmakar, Monash University) -- Chapter 8: FPGA Controlled Phased Array Antenna Development for UHF RFID Reader (N.C. Karmakar, P. Zakavi and M. Kumbukage, Monash University) -- Chapter 9: Optically Controlled Phased Array Antennas for UWB RFID Reader (A. Arokiaswami, P. Q. Thai, Nanyang Technological University and N.C. Karmakar, Monash University) -- Chapter 10: Adaptive Antenna Arrays for RFID (M. Trinkle and B. Jamali, The University of Adelaide) -- Chapter 11: Design of Portable RFID Smart Antenna System?A Practical Approach (J.S. Fu, Chang Gung University, W. Liu, Nanyang Technological University and N.C. Karmakar, Monash University) -- Section IV: DOA and Localization of RFID Tags using Smart Antennas -- Chapter 12: Direction of Arrival Estimation based on A Single Port Smart Antenna for RFID Applications (Chen Sun, National Institute of Information and Communication Technology (NICT) and N.C. Karmakar, Monash University) -- Chapter 13: DOA Geo-location in Real-Time Indoor WiFi System Utilizing Smart Antennas (C.H. Lim, B.P. Ng, M.H. Er, J.P. Lie and W. Wang, Nanyang Technological University) -- Chapter 14: Direction of Arrival (DoA) Estimation of Impulse Radio UWB RFID Tags (J.P. Lie, B.P. Ng, C.H. Lim and C.M. S. See, Nanyang Technological University).
Chapter 15: Localization techniques in single and multihop wireless networks (V. Lakafosis, Rushi Vyas and M.M. Tentzeris, Georgia Institute of Technology) -- Section V: Multi-Antenna RFID Tags -- Chapter 16: Multi-antenna Chipless RFID Tags (I. Balbin and N. C. Karmakar, Monash University) -- Chapter 17: Link Budgets for Backscatter Radio Systems (J.D. Griffin and G.D. Durgin, Georgia Institute of Technology) -- Chapter 18: Fading Statistics for Multi-Antenna RF Tags (J.D. Griffin and G.D. Durgin, Georgia Institute of Technology) -- Section VI: MIMO Antennas for RFID Systems -- Chapter 19: Optimum Power Allocation in Multiple-Input-Multiple-Output (MIMO) Systems under Independent Rayleigh Fading (J.S. Fu, Chang Gung University, W. Liu, Nanyang Technological University and N. C. Karmakar, Monash University) -- Chapter 20: Low-cost and Compact RF-MIMO Transceivers (I. Santamaria, J. Via, V. Elvira, J. Ibanez, J. Perez, University of Cantabria -- R. Eickhoff, and U. Mayer, Dresden University of Technology) -- Chapter 21: Blind Channel Estimation in MIMO using Multi-carrier CDMA (A. Rahim, Monash University, K. M. Ahmed, Asian Institute of Technology and N. C. Karmakar, Monash University) -- Section VII: Anti-Collision Algorithm and Smart Antennas for RFID Systems -- Chapter 22: Anti-collision Algorithm and Smart Antennas for RFID Systems (Q. J. Teoh and N. C. Karmakar, Monash University) -- Chapter 23: RFID Anti-Collision Algorithms with Multi-Packet Reception (J. Lee, Hewlett-Packard Laboratories, T. Kwon, Seoul National University) -- Chapter 24: Anti-Collision of RFID tags using Capturing Effect (Q. J. Teoh and N. C. Karmakar, Monash University). |
| Record Nr. | UNINA-9910830282903321 |
|
Karmakar Nemai Chandra <1963->
|
||
| Hoboken, New Jersey : , : Wiley, , c2010 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Handbook of smart antennas for RFID systems / / edited by Nemai Chandra Karmakar
| Handbook of smart antennas for RFID systems / / edited by Nemai Chandra Karmakar |
| Edizione | [1st edition] |
| Pubbl/distr/stampa | Hoboken, N.J., : Wiley, c2010 |
| Descrizione fisica | 1 online resource (646 p.) |
| Disciplina | 681/.2 |
| Altri autori (Persone) | KarmakarNemai Chandra <1963-> |
| Soggetto topico |
Radio frequency identification systems - Design and construction
Adaptive antennas - Design and construction Phased array antennas - Design and construction |
| ISBN |
9786612849046
9781282849044 1282849042 9781118074398 1118074394 9780470872178 0470872179 9780470872161 0470872160 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Forward -- Preface -- Acknowledgement -- Section I: Introduction to RFID -- Chapter 1: The Evolution of RFID (B. Jamali, The University of Adelaide) -- Chapter 2: Introduction to RFID systems (S.M. Roy and N.C. Karmakar, Monash University) -- Chapter 3: Recent Paradigm Shift in RFID and Smart Antennas (N.C. Karmakar, Monash University) -- Section II: RFID Reader Systems -- Chapter 4: Modern RFID Readers (S. Parardovic and N.C. Karmakar, Monash University) -- Chapter 5: A Development Platform for SDR based RFID Reader (B. Jamali, The University of Adelaide) -- Section III: Physical Layer Developments of Smart Antennas for RFID Systems -- Chapter 6: RFID Reader Antenna -- A Smart Design Approach (S.M. Roy and N.C. Karmakar, Monash University) -- Chapter 7: Handheld Reader Antenna at 5.8 GHz (S.M. Roy and N.C. Karmakar, Monash University) -- Chapter 8: FPGA Controlled Phased Array Antenna Development for UHF RFID Reader (N.C. Karmakar, P. Zakavi and M. Kumbukage, Monash University) -- Chapter 9: Optically Controlled Phased Array Antennas for UWB RFID Reader (A. Arokiaswami, P. Q. Thai, Nanyang Technological University and N.C. Karmakar, Monash University) -- Chapter 10: Adaptive Antenna Arrays for RFID (M. Trinkle and B. Jamali, The University of Adelaide) -- Chapter 11: Design of Portable RFID Smart Antenna System?A Practical Approach (J.S. Fu, Chang Gung University, W. Liu, Nanyang Technological University and N.C. Karmakar, Monash University) -- Section IV: DOA and Localization of RFID Tags using Smart Antennas -- Chapter 12: Direction of Arrival Estimation based on A Single Port Smart Antenna for RFID Applications (Chen Sun, National Institute of Information and Communication Technology (NICT) and N.C. Karmakar, Monash University) -- Chapter 13: DOA Geo-location in Real-Time Indoor WiFi System Utilizing Smart Antennas (C.H. Lim, B.P. Ng, M.H. Er, J.P. Lie and W. Wang, Nanyang Technological University) -- Chapter 14: Direction of Arrival (DoA) Estimation of Impulse Radio UWB RFID Tags (J.P. Lie, B.P. Ng, C.H. Lim and C.M. S. See, Nanyang Technological University).
Chapter 15: Localization techniques in single and multihop wireless networks (V. Lakafosis, Rushi Vyas and M.M. Tentzeris, Georgia Institute of Technology) -- Section V: Multi-Antenna RFID Tags -- Chapter 16: Multi-antenna Chipless RFID Tags (I. Balbin and N. C. Karmakar, Monash University) -- Chapter 17: Link Budgets for Backscatter Radio Systems (J.D. Griffin and G.D. Durgin, Georgia Institute of Technology) -- Chapter 18: Fading Statistics for Multi-Antenna RF Tags (J.D. Griffin and G.D. Durgin, Georgia Institute of Technology) -- Section VI: MIMO Antennas for RFID Systems -- Chapter 19: Optimum Power Allocation in Multiple-Input-Multiple-Output (MIMO) Systems under Independent Rayleigh Fading (J.S. Fu, Chang Gung University, W. Liu, Nanyang Technological University and N. C. Karmakar, Monash University) -- Chapter 20: Low-cost and Compact RF-MIMO Transceivers (I. Santamaria, J. Via, V. Elvira, J. Ibanez, J. Perez, University of Cantabria -- R. Eickhoff, and U. Mayer, Dresden University of Technology) -- Chapter 21: Blind Channel Estimation in MIMO using Multi-carrier CDMA (A. Rahim, Monash University, K. M. Ahmed, Asian Institute of Technology and N. C. Karmakar, Monash University) -- Section VII: Anti-Collision Algorithm and Smart Antennas for RFID Systems -- Chapter 22: Anti-collision Algorithm and Smart Antennas for RFID Systems (Q. J. Teoh and N. C. Karmakar, Monash University) -- Chapter 23: RFID Anti-Collision Algorithms with Multi-Packet Reception (J. Lee, Hewlett-Packard Laboratories, T. Kwon, Seoul National University) -- Chapter 24: Anti-Collision of RFID tags using Capturing Effect (Q. J. Teoh and N. C. Karmakar, Monash University). |
| Altri titoli varianti | Smart antennas for RFID systems |
| Record Nr. | UNINA-9910876745003321 |
| Hoboken, N.J., : Wiley, c2010 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Synthesized transmission lines : design, circuit implementation, and phased array applications / / Tzyh-Ghuang Ma, Chao-Wei Wang, Chi-Hui Lai, Ying-Cheng Tseng
| Synthesized transmission lines : design, circuit implementation, and phased array applications / / Tzyh-Ghuang Ma, Chao-Wei Wang, Chi-Hui Lai, Ying-Cheng Tseng |
| Pubbl/distr/stampa | Singapore ; ; Hoboken, NJ : , : John Wiley & Sons, , 2017 |
| Descrizione fisica | 1 online resource (217 pages) |
| Disciplina | 621.3841/35 |
| Soggetto topico |
Microwave transmission lines - Design and construction
Phased array antennas - Design and construction |
| ISBN |
1-118-97573-1
1-118-97574-X |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
-- Preface xi -- 1 Introduction to Synthesized Transmission Lines 1 /C. W. Wang and T. G. Ma -- 1.1 Introduction 1 -- 1.2 Propagation Characteristics of a TEM Transmission Line 2 -- 1.2.1 Wave Equations 2 -- 1.2.2 Keys to Miniaturization 5 -- 1.3 Analysis of Synthesized Transmission Lines 7 -- 1.3.1 Bloch Theorem and Characterization of a Periodic Synthesized Transmission Line 7 -- 1.3.2 Characterization of a Non?-Periodic Synthesized Transmission Line 9 -- 1.3.3 Extraction of Line Parameters from S?-Parameters 10 -- 1.4 Lumped and Quasi?-Lumped Approaches 11 -- 1.4.1 Lumped Networks 11 -- 1.4.2 Shunt?-Stub Loaded Lines 14 -- 1.5 One?-Dimensional Periodic Structures 16 -- 1.5.1 Complementary?-Conducting?-Strip Lines 19 -- 1.6 Photonic Bandgap Structures 20 -- 1.7 Left?-Handed Structures 21 -- References 24 -- 2 Non?-Periodic Synthesized Transmission Lines for Circuit Miniaturization 26 /C. W. Wang and T. G. Ma -- 2.1 Introduction 26 -- 2.2 Non?-Periodic Synthesized Microstrip Lines and Their Applications 27 -- 2.2.1 Design Details and Propagation Characteristics 27 -- 2.2.2 90À and 180À Hybrid Couplers 30 -- 2.2.3 Application to Butler Matrix as Array Feeding Network 32 -- 2.3 Non?-Periodic Synthesized Coplanar Waveguides and Their Applications 34 -- 2.3.1 Synthesis and Design 34 -- 2.3.2 180À Hybrid Using Synthesized CPWs 37 -- 2.3.3 Dual?-Mode Ring Bandpass Filters 38 -- 2.4 Non?-Periodic Quasi?-Lumped Synthesized Coupled Lines 42 -- 2.4.1 Basics of Coupled Transmission Lines 42 -- 2.4.2 Miniaturization of Coupled Lines and the Directional Couplers 44 -- 2.4.3 Marchand Baluns Using Synthesized Coupled Lines 49 -- 2.4.4 Lumped Directional Coupler and the Phase Shifter 53 -- 2.5 Non?-Periodic Synthesized Lines Using Vertical Inductors 55 -- References 60 -- 3 Dual/Tri?-Operational Mode Synthesized Transmission Lines: Design and Analysis 62 /C. H. Lai and T. G. Ma -- 3.1 Introduction 62 -- 3.2 Equivalent Circuit Models and Analysis 63 -- 3.2.1 Ladder?-Type Approximation in the Passband 63.
3.2.2 Half?-Circuit Model at Resonance 64 -- 3.3 Dual?-Operational Mode Synthesized Transmission Lines 65 -- 3.3.1 Design Concept 65 -- 3.3.2 Dual?-Mode Synthesized Line Using a Series Resonator 66 -- 3.3.3 Dual?-Mode Synthesized Line Using Open-Circuited Stubs 70 -- 3.3.4 Dual?-Mode Synthesized Line Using Parallel Resonators 72 -- 3.4 Tri?-Operational Mode Synthesized Lines Using Series Resonators 74 -- 3.4.1 Design Concept 74 -- 3.4.2 Tri?-Mode Synthesized Line as Category?-1 Design 75 -- 3.4.3 Tri?-Mode Synthesized Line as Category?-2 Design 79 -- 3.4.4 Tri?-Mode Synthesized Line as Category?-3 Design 83 -- 3.5 Multi?-Operational Mode Synthesized Lines as Diplexer and Triplexer 87 -- 3.5.1 Diplexer 87 -- 3.5.2 Triplexer 89 -- References 94 -- 4 Applications to Heterogeneous Integrated Phased Arrays 95 /C. H. Lai and T. G. Ma -- 4.1 Introduction 95 -- 4.2 Dual?-Mode Retrodirective Array 96 -- 4.2.1 Design Goal 96 -- 4.2.2 System Architecture 97 -- 4.2.3 Circuit Realization 98 -- 4.2.4 Bistatic Radiation Patterns 102 -- 4.2.5 Alternative Architecture 103 -- 4.3 Dual?-Mode Integrated Beam?-Switching/Retrodirective Array 106 -- 4.3.1 Design Goal 106 -- 4.3.2 System Architecture 106 -- 4.3.3 Circuit Realization 109 -- 4.3.4 Radiation Characteristics 111 -- 4.3.5 Complementary Design 111 -- 4.4 Tri?-Mode Heterogeneous Integrated Phased Array 115 -- 4.4.1 Design Goal 115 -- 4.4.2 System Architecture 116 -- 4.4.3 Operation and System Implementation 117 -- 4.4.4 Circuit Responses and Radiation Patterns 119 -- 4.4.4.1 Beam?-Switching Mode 120 -- 4.4.4.2 Van Atta Mode 122 -- 4.4.4.3 PCA Mode 122 -- 4.5 Simplified Dual?-Mode Integrated Array Using Two Elements 122 -- References 124 -- 5 On?-Chip Realization of Synthesized Transmission Lines Using IPD Processes 126 /Y. C. Tseng and T. G. Ma -- 5.1 Introduction 126 -- 5.2 Integrated Passive Device (IPD) Process 127 -- 5.3 Tight Couplers Using Synthesized CPWs 128 -- 5.3.1 Quadrature Hybrid 128 -- 5.3.2 Wideband Rat?-Race Coupler 129. 5.3.3 Dual?-Band Rat?-Race Coupler 132 -- 5.3.4 Coupled?-Line Coupler 137 -- 5.3.5 Butler Matrix 139 -- 5.4 Bandpass/Bandstop Filters Using Synthesized CPWs 142 -- 5.4.1 Bandpass Filter Using Synthesized Stepped?-Impedance Resonators 143 -- 5.4.2 Transformer?-Coupled Bandpass Filter 146 -- 5.4.3 Bridged T?-Coils as Common?-Mode Filter 147 -- 5.5 Chip Designs Using Multi?-Mode Synthesized CPWs 151 -- 5.5.1 Diplexer 151 -- 5.5.2 Dual?-Mode Rat?-Race Coupler 154 -- 5.5.3 Triplexer 157 -- 5.5.4 On?-Chip Liquid Detector 161 -- References 166 -- 6 Periodic Synthesized Transmission Lines with Two?-Dimensional Routing 168 /T. G. Ma -- 6.1 Introduction 168 -- 6.2 Design of the Unit Cells 169 -- 6.2.1 Formulation 169 -- 6.2.2 Quarter?-Wavelength Lines 172 -- 6.3 Power Divider and Couplers 174 -- 6.4 Broadside Directional Coupler 178 -- 6.4.1 Design Principle 178 -- 6.4.2 Circuit Realization 180 -- 6.5 Common?-Mode Rejection Filter 184 -- 6.5.1 Design Principle 184 -- 6.5.2 Circuit Realization 187 -- 6.6 On?-Chip Implementation 189 -- 6.6.1 Unit Cells and Quarter?-Wavelength Lines 189 -- 6.6.2 Circuit Implementations and Compensation 192 -- References 194 -- Index 196. |
| Record Nr. | UNINA-9910153205603321 |
| Singapore ; ; Hoboken, NJ : , : John Wiley & Sons, , 2017 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Synthesized transmission lines : design, circuit implementation, and phased array applications / / Tzyh-Ghuang Ma, Chao-Wei Wang, Chi-Hui Lai, Ying-Cheng Tseng
| Synthesized transmission lines : design, circuit implementation, and phased array applications / / Tzyh-Ghuang Ma, Chao-Wei Wang, Chi-Hui Lai, Ying-Cheng Tseng |
| Pubbl/distr/stampa | Singapore ; ; Hoboken, NJ : , : John Wiley & Sons, , 2017 |
| Descrizione fisica | 1 online resource (217 pages) |
| Disciplina | 621.3841/35 |
| Soggetto topico |
Microwave transmission lines - Design and construction
Phased array antennas - Design and construction |
| ISBN |
1-118-97573-1
1-118-97574-X |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
-- Preface xi -- 1 Introduction to Synthesized Transmission Lines 1 /C. W. Wang and T. G. Ma -- 1.1 Introduction 1 -- 1.2 Propagation Characteristics of a TEM Transmission Line 2 -- 1.2.1 Wave Equations 2 -- 1.2.2 Keys to Miniaturization 5 -- 1.3 Analysis of Synthesized Transmission Lines 7 -- 1.3.1 Bloch Theorem and Characterization of a Periodic Synthesized Transmission Line 7 -- 1.3.2 Characterization of a Non?-Periodic Synthesized Transmission Line 9 -- 1.3.3 Extraction of Line Parameters from S?-Parameters 10 -- 1.4 Lumped and Quasi?-Lumped Approaches 11 -- 1.4.1 Lumped Networks 11 -- 1.4.2 Shunt?-Stub Loaded Lines 14 -- 1.5 One?-Dimensional Periodic Structures 16 -- 1.5.1 Complementary?-Conducting?-Strip Lines 19 -- 1.6 Photonic Bandgap Structures 20 -- 1.7 Left?-Handed Structures 21 -- References 24 -- 2 Non?-Periodic Synthesized Transmission Lines for Circuit Miniaturization 26 /C. W. Wang and T. G. Ma -- 2.1 Introduction 26 -- 2.2 Non?-Periodic Synthesized Microstrip Lines and Their Applications 27 -- 2.2.1 Design Details and Propagation Characteristics 27 -- 2.2.2 90À and 180À Hybrid Couplers 30 -- 2.2.3 Application to Butler Matrix as Array Feeding Network 32 -- 2.3 Non?-Periodic Synthesized Coplanar Waveguides and Their Applications 34 -- 2.3.1 Synthesis and Design 34 -- 2.3.2 180À Hybrid Using Synthesized CPWs 37 -- 2.3.3 Dual?-Mode Ring Bandpass Filters 38 -- 2.4 Non?-Periodic Quasi?-Lumped Synthesized Coupled Lines 42 -- 2.4.1 Basics of Coupled Transmission Lines 42 -- 2.4.2 Miniaturization of Coupled Lines and the Directional Couplers 44 -- 2.4.3 Marchand Baluns Using Synthesized Coupled Lines 49 -- 2.4.4 Lumped Directional Coupler and the Phase Shifter 53 -- 2.5 Non?-Periodic Synthesized Lines Using Vertical Inductors 55 -- References 60 -- 3 Dual/Tri?-Operational Mode Synthesized Transmission Lines: Design and Analysis 62 /C. H. Lai and T. G. Ma -- 3.1 Introduction 62 -- 3.2 Equivalent Circuit Models and Analysis 63 -- 3.2.1 Ladder?-Type Approximation in the Passband 63.
3.2.2 Half?-Circuit Model at Resonance 64 -- 3.3 Dual?-Operational Mode Synthesized Transmission Lines 65 -- 3.3.1 Design Concept 65 -- 3.3.2 Dual?-Mode Synthesized Line Using a Series Resonator 66 -- 3.3.3 Dual?-Mode Synthesized Line Using Open-Circuited Stubs 70 -- 3.3.4 Dual?-Mode Synthesized Line Using Parallel Resonators 72 -- 3.4 Tri?-Operational Mode Synthesized Lines Using Series Resonators 74 -- 3.4.1 Design Concept 74 -- 3.4.2 Tri?-Mode Synthesized Line as Category?-1 Design 75 -- 3.4.3 Tri?-Mode Synthesized Line as Category?-2 Design 79 -- 3.4.4 Tri?-Mode Synthesized Line as Category?-3 Design 83 -- 3.5 Multi?-Operational Mode Synthesized Lines as Diplexer and Triplexer 87 -- 3.5.1 Diplexer 87 -- 3.5.2 Triplexer 89 -- References 94 -- 4 Applications to Heterogeneous Integrated Phased Arrays 95 /C. H. Lai and T. G. Ma -- 4.1 Introduction 95 -- 4.2 Dual?-Mode Retrodirective Array 96 -- 4.2.1 Design Goal 96 -- 4.2.2 System Architecture 97 -- 4.2.3 Circuit Realization 98 -- 4.2.4 Bistatic Radiation Patterns 102 -- 4.2.5 Alternative Architecture 103 -- 4.3 Dual?-Mode Integrated Beam?-Switching/Retrodirective Array 106 -- 4.3.1 Design Goal 106 -- 4.3.2 System Architecture 106 -- 4.3.3 Circuit Realization 109 -- 4.3.4 Radiation Characteristics 111 -- 4.3.5 Complementary Design 111 -- 4.4 Tri?-Mode Heterogeneous Integrated Phased Array 115 -- 4.4.1 Design Goal 115 -- 4.4.2 System Architecture 116 -- 4.4.3 Operation and System Implementation 117 -- 4.4.4 Circuit Responses and Radiation Patterns 119 -- 4.4.4.1 Beam?-Switching Mode 120 -- 4.4.4.2 Van Atta Mode 122 -- 4.4.4.3 PCA Mode 122 -- 4.5 Simplified Dual?-Mode Integrated Array Using Two Elements 122 -- References 124 -- 5 On?-Chip Realization of Synthesized Transmission Lines Using IPD Processes 126 /Y. C. Tseng and T. G. Ma -- 5.1 Introduction 126 -- 5.2 Integrated Passive Device (IPD) Process 127 -- 5.3 Tight Couplers Using Synthesized CPWs 128 -- 5.3.1 Quadrature Hybrid 128 -- 5.3.2 Wideband Rat?-Race Coupler 129. 5.3.3 Dual?-Band Rat?-Race Coupler 132 -- 5.3.4 Coupled?-Line Coupler 137 -- 5.3.5 Butler Matrix 139 -- 5.4 Bandpass/Bandstop Filters Using Synthesized CPWs 142 -- 5.4.1 Bandpass Filter Using Synthesized Stepped?-Impedance Resonators 143 -- 5.4.2 Transformer?-Coupled Bandpass Filter 146 -- 5.4.3 Bridged T?-Coils as Common?-Mode Filter 147 -- 5.5 Chip Designs Using Multi?-Mode Synthesized CPWs 151 -- 5.5.1 Diplexer 151 -- 5.5.2 Dual?-Mode Rat?-Race Coupler 154 -- 5.5.3 Triplexer 157 -- 5.5.4 On?-Chip Liquid Detector 161 -- References 166 -- 6 Periodic Synthesized Transmission Lines with Two?-Dimensional Routing 168 /T. G. Ma -- 6.1 Introduction 168 -- 6.2 Design of the Unit Cells 169 -- 6.2.1 Formulation 169 -- 6.2.2 Quarter?-Wavelength Lines 172 -- 6.3 Power Divider and Couplers 174 -- 6.4 Broadside Directional Coupler 178 -- 6.4.1 Design Principle 178 -- 6.4.2 Circuit Realization 180 -- 6.5 Common?-Mode Rejection Filter 184 -- 6.5.1 Design Principle 184 -- 6.5.2 Circuit Realization 187 -- 6.6 On?-Chip Implementation 189 -- 6.6.1 Unit Cells and Quarter?-Wavelength Lines 189 -- 6.6.2 Circuit Implementations and Compensation 192 -- References 194 -- Index 196. |
| Record Nr. | UNINA-9910826963703321 |
| Singapore ; ; Hoboken, NJ : , : John Wiley & Sons, , 2017 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Systems engineering of phased arrays / / Rick Sturdivant, Clifton Quan, Enson Chang
| Systems engineering of phased arrays / / Rick Sturdivant, Clifton Quan, Enson Chang |
| Autore | Sturdivant Rick |
| Edizione | [1st ed.] |
| Pubbl/distr/stampa | Boston : , : Artech House, , [2019] |
| Descrizione fisica | 1 PDF (xxi, 291 pages) : illustrations |
| Disciplina | 621.382/4 |
| Collana | Artech House radar series |
| Soggetto topico | Phased array antennas - Design and construction |
| ISBN |
1-63081-489-X
9781630814098 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Intro -- Systems Engineering of Phased Arrays -- Contents -- Preface -- Acknowledgments -- Part I System Engineering Activities -- 1 The Systems Engineering Process and Its Application to Phased Arrays -- 1.1 Introduction -- 1.2 Methodological Reductionism -- 1.3 The Systems Engineering Approach -- 1.4 The Three-Phase Process -- 1.5 Phase 1: Concept Development -- 1.5.1 Needs Analysis -- 1.5.2 Alternatives Exploration -- 1.5.3 Trade Studies and Baseline Selection -- 1.5.4 New Technology Validation -- 1.5.5 Risk Management Plan -- 1.5.6 Other Concept Development Activities -- 1.6 Phase II: Engineering Development -- 1.6.1 Typical Engineering Activities for Phased Arrays -- 1.6.2 Antenna Development -- 1.6.3 Integrated Circuit Development -- 1.6.4 T/R Module Development -- 1.6.5 Thermal Design and Heat Transfer Development -- 1.6.6 Beamformer Development -- 1.6.7 Digital Receiver/Exciter Development -- 1.6.8 Mechanical Structure Development -- 1.6.9 Production Plan Development -- 1.6.10 Acceptance Testing -- 1.6.11 Other Functions -- 1.6.12 Outputs from Engineering Development -- 1.7 Phase III: Post-Development -- 1.7.1 Production -- 1.7.2 Deployment -- 1.7.3 Operation and System Maintenance -- 1.7.4 Eventual Decommissioning -- 1.8 Conclusions -- 1.9 Problems -- References -- 2 Phased Array System Architectures -- 2.1 Introduction to Phased Array System Architectures -- 2.2 Phased Array System Basics -- 2.3 Phased Array Architectures -- 2.3.1 Passive Phased Arrays -- 2.3.2 AESA -- 2.3.3 AESA with Phase Shifters at Each Element and at Each Subarray -- 2.3.4 Element-Level Digital Beamforming -- 2.3.5 Other Methods -- 2.4 Array Architectures for T/R Module Integration -- 2.5 Array Beamforming Options -- 2.6 Polarization Diverse and Wideband Arrays -- 2.7 Conclusions -- 2.8 Problems -- References -- 3 Use Cases for Phased Arrays.
3.1 Introduction to Use Cases -- 3.2 High-Altitude Platform Station -- 3.2.1 Introduction to HAPS -- 3.2.2 HAPS System Description with Key Challenges and Benefits -- 3.2.3 HAPS Examples and Summary -- 3.3 Medical Applications of Phased Arrays -- 3.3.1 Introduction to Medical Phased Arrays -- 3.3.2 Medical Arrays System Description with Key Challenges and Benefits -- 3.3.3 Medical Phased Array Examples and Summary -- 3.4 Phased Array for 5G MIMO Broadband -- 3.4.1 Introduction 5G Broadband Phased Arrays -- 3.4.2 5G Phased Array System Description with Key Challenges and Benefits -- 3.4.3 5G Phased Array Examples and Summary -- 3.5 Airborne Radar for Fighter Aircraft -- 3.5.1 Introduction to Military Phased Arrays -- 3.5.2 Airborne Phased Array System Description with Key Challenges and Benefits -- 3.5.3 Airborne Phased Array Examples and Summary -- 3.6 Conclusions -- 3.7 Problems -- References -- 4 Phased Array Concept Development Example -- 4.1 Introduction -- 4.2 Needs Assessment-A Common Starting Point -- 4.3 Technology Opportunities -- 4.4 System Architecting -- 4.5 The SAI Method for New System Concept Development -- 4.6 Application of the Modified SAI Method to Broadband Access for Small to Medium-Size Public Venues -- 4.6.1 Step 1: Determine Value Proposition and Constraints -- 4.6.2 Step 2: Identification of Potential Perturbations -- 4.6.3 Step 3: Identify Desired Ilities -- 4.6.4 Step 4: Generate Function Alternatives -- 4.6.5 Step 5: Generate Architecture Options -- 4.6.6 Step 6: Select the "Best" Architecture Option -- 4.7 Conclusions -- 4.8 Problems -- References -- Part II Detailed Development Activities -- 5 Antenna Element Technology Options -- 5.1 Introduction -- 5.2 Based Concepts of Antennas -- 5.3 Antenna Development Process -- 5.4 Conventional Dipole -- 5.5 Planar Inverted-F Antenna -- 5.6 Meander Line Antenna. 5.7 Microstrip Patch Antennas -- 5.8 Bowtie Dipole Antenna -- 5.9 Waveguide Radiators -- 5.10 Reflector Antenna -- 5.11 Vivaldi Tapered Slotline Antenna -- 5.12 Low-Profile Vivaldi Tapered Slot Antennas -- 5.13 Tightly Coupled Dipole Array -- 5.14 Conclusions -- 5.15 Problems -- References -- 6 Transmit/Receive Modules -- 6.1 Introduction -- 6.2 Technical Challenges Often Faced in T/R Module Development -- 6.2.1 Heat Transfer -- 6.2.2 Signal Integrity -- 6.2.3 Integration with Other Functions -- 6.2.4 Materials Compatibility -- 6.2.5 Electromagnetic Coupling -- 6.3 General Description of the T/R Module -- 6.3.1 System Location of the T/R Module -- 6.3.2 T/R Block Diagram -- 6.4 T/R Module Detailed Description -- 6.4.1 Low Noise Amplifier -- 6.4.2 Low Noise Amplifier Protection -- 6.4.3 High-Power Amplifier and Driver Amplifier -- 6.4.4 Phase Shifter -- 6.4.5 Duplexer -- 6.5 T/R Module Manufacturing and Test -- 6.5.1 Integrated Circuit Manufacturing -- 6.5.2 Package Manufacturing -- 6.5.3 Interconnects Types -- 6.5.4 T/R Module Test -- 6.6 Examples of T/R Modules -- 6.6.1 A 3-D Ceramic T/R Module for Space-Based Applications -- 6.6.2 T/R Module Using Laminate Circuit Board Technology -- 6.6.3 60-GHz CMOS T/R Module Integrated with Antennas -- 6.7 Conclusions -- 6.8 Problems -- References -- 7 Thermal Design, Heat Transfer Trade Studies, and Reliability -- 7.1 Introduction -- 7.2 Heat Transfer Fundamentals at the Integrated Circuit Level -- 7.3 Reliability and MTTF -- 7.4 Example: Millimeter-Wave SATCOM Front End -- 7.5 Array Cooling Methods -- 7.5.1 The Challenge of Phased Array Cooling -- 7.5.2 Brick Array Cooling -- 7.5.3 Tile Array Cooling -- 7.6 Other Reliability Drivers for Phased Arrays -- 7.7 Materials Used for Thermal Management -- 7.8 Conclusions -- 7.9 Problems -- References -- 8 Analog versus Digital Beamforming -- 8.1 Introduction. 8.2 Benefits and Challenges in Analog Beamforming -- 8.3 Benefits and Challenges in Digital Beamforming -- 8.4 Basic Digital Beamforming -- 8.5 Adaptive Beamforming -- 8.6 Errors in Beamforming and Their Effects -- 8.7 Multiple Access Methods for 5G Phased Arrays -- 8.7.1 Orthogonal Frequency Division Multiple Access -- 8.7.2 Code Division Multiple Access -- 8.7.3 Other Access Technologies -- 8.8 Conclusions -- 8.9 Problems -- References -- 9 Digital Receiver Exciters -- 9.1 Introduction -- 9.2 Digital Receiver Architecture Options -- 9.3 Example Trade Study on Digital Receiver Architecture -- 9.4 Digital Exciter Architecture Options -- 9.5 Main Components of a Digital Receiver Exciter -- 9.5.1 Low Noise Amplifier -- 9.5.2 Digital Attenuator -- 9.5.3 Frequency Mixer -- 9.5.4 Preselection, Image Rejection, and Antialiasing Filters -- 9.5.5 Frequency Multipliers -- 9.5.6 ADC -- 9.6 Analysis of DRXs -- 9.7 Conclusions -- 9.8 Problems -- References -- Part III System Modeling and Advanced Development Activities -- 10 Phased Array System Modeling -- 10.1 Introduction -- 10.2 LFOV Receiver Array -- 10.3 Multichannel Communication System Design -- 10.4 Stripmap Synthetic Aperture Radar -- 10.5 Radar Detection Performance -- 10.6 Conclusions -- 10.7 Problems -- References -- Appendix 10A Excel Spreadsheet for the LFOV Array -- Appendix 10B Scilab Code for the Communication System Receiver Array -- Appendix 10C Scilab Code for the Stripmap SAR Simulation -- Appendix 10D Gaussian ROC Curve Derivation -- 11 Advanced Development Activities for Phased Arrays -- 11.1 Introduction -- 11.2 System Risk Management -- 11.3 Advanced Development Activities -- 11.4 Types of Advanced Development Risk Reduction Activities -- 11.5 Typical Risks in Phased Array Development -- 11.6 Advanced Development Impacts All Levels of the System -- 11.7 Other Risk Analysis Topics. 11.8 Conclusions -- 11.9 Problems -- References -- 12 Conclusions -- About the Authors -- Index. |
| Record Nr. | UNINA-9910793302103321 |
|
Sturdivant Rick
|
||
| Boston : , : Artech House, , [2019] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Systems engineering of phased arrays / / Rick Sturdivant, Clifton Quan, Enson Chang
| Systems engineering of phased arrays / / Rick Sturdivant, Clifton Quan, Enson Chang |
| Autore | Sturdivant Rick |
| Edizione | [1st ed.] |
| Pubbl/distr/stampa | Boston : , : Artech House, , [2019] |
| Descrizione fisica | 1 PDF (xxi, 291 pages) : illustrations |
| Disciplina | 621.382/4 |
| Collana | Artech House radar series |
| Soggetto topico | Phased array antennas - Design and construction |
| ISBN |
1-63081-489-X
9781630814098 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Intro -- Systems Engineering of Phased Arrays -- Contents -- Preface -- Acknowledgments -- Part I System Engineering Activities -- 1 The Systems Engineering Process and Its Application to Phased Arrays -- 1.1 Introduction -- 1.2 Methodological Reductionism -- 1.3 The Systems Engineering Approach -- 1.4 The Three-Phase Process -- 1.5 Phase 1: Concept Development -- 1.5.1 Needs Analysis -- 1.5.2 Alternatives Exploration -- 1.5.3 Trade Studies and Baseline Selection -- 1.5.4 New Technology Validation -- 1.5.5 Risk Management Plan -- 1.5.6 Other Concept Development Activities -- 1.6 Phase II: Engineering Development -- 1.6.1 Typical Engineering Activities for Phased Arrays -- 1.6.2 Antenna Development -- 1.6.3 Integrated Circuit Development -- 1.6.4 T/R Module Development -- 1.6.5 Thermal Design and Heat Transfer Development -- 1.6.6 Beamformer Development -- 1.6.7 Digital Receiver/Exciter Development -- 1.6.8 Mechanical Structure Development -- 1.6.9 Production Plan Development -- 1.6.10 Acceptance Testing -- 1.6.11 Other Functions -- 1.6.12 Outputs from Engineering Development -- 1.7 Phase III: Post-Development -- 1.7.1 Production -- 1.7.2 Deployment -- 1.7.3 Operation and System Maintenance -- 1.7.4 Eventual Decommissioning -- 1.8 Conclusions -- 1.9 Problems -- References -- 2 Phased Array System Architectures -- 2.1 Introduction to Phased Array System Architectures -- 2.2 Phased Array System Basics -- 2.3 Phased Array Architectures -- 2.3.1 Passive Phased Arrays -- 2.3.2 AESA -- 2.3.3 AESA with Phase Shifters at Each Element and at Each Subarray -- 2.3.4 Element-Level Digital Beamforming -- 2.3.5 Other Methods -- 2.4 Array Architectures for T/R Module Integration -- 2.5 Array Beamforming Options -- 2.6 Polarization Diverse and Wideband Arrays -- 2.7 Conclusions -- 2.8 Problems -- References -- 3 Use Cases for Phased Arrays.
3.1 Introduction to Use Cases -- 3.2 High-Altitude Platform Station -- 3.2.1 Introduction to HAPS -- 3.2.2 HAPS System Description with Key Challenges and Benefits -- 3.2.3 HAPS Examples and Summary -- 3.3 Medical Applications of Phased Arrays -- 3.3.1 Introduction to Medical Phased Arrays -- 3.3.2 Medical Arrays System Description with Key Challenges and Benefits -- 3.3.3 Medical Phased Array Examples and Summary -- 3.4 Phased Array for 5G MIMO Broadband -- 3.4.1 Introduction 5G Broadband Phased Arrays -- 3.4.2 5G Phased Array System Description with Key Challenges and Benefits -- 3.4.3 5G Phased Array Examples and Summary -- 3.5 Airborne Radar for Fighter Aircraft -- 3.5.1 Introduction to Military Phased Arrays -- 3.5.2 Airborne Phased Array System Description with Key Challenges and Benefits -- 3.5.3 Airborne Phased Array Examples and Summary -- 3.6 Conclusions -- 3.7 Problems -- References -- 4 Phased Array Concept Development Example -- 4.1 Introduction -- 4.2 Needs Assessment-A Common Starting Point -- 4.3 Technology Opportunities -- 4.4 System Architecting -- 4.5 The SAI Method for New System Concept Development -- 4.6 Application of the Modified SAI Method to Broadband Access for Small to Medium-Size Public Venues -- 4.6.1 Step 1: Determine Value Proposition and Constraints -- 4.6.2 Step 2: Identification of Potential Perturbations -- 4.6.3 Step 3: Identify Desired Ilities -- 4.6.4 Step 4: Generate Function Alternatives -- 4.6.5 Step 5: Generate Architecture Options -- 4.6.6 Step 6: Select the "Best" Architecture Option -- 4.7 Conclusions -- 4.8 Problems -- References -- Part II Detailed Development Activities -- 5 Antenna Element Technology Options -- 5.1 Introduction -- 5.2 Based Concepts of Antennas -- 5.3 Antenna Development Process -- 5.4 Conventional Dipole -- 5.5 Planar Inverted-F Antenna -- 5.6 Meander Line Antenna. 5.7 Microstrip Patch Antennas -- 5.8 Bowtie Dipole Antenna -- 5.9 Waveguide Radiators -- 5.10 Reflector Antenna -- 5.11 Vivaldi Tapered Slotline Antenna -- 5.12 Low-Profile Vivaldi Tapered Slot Antennas -- 5.13 Tightly Coupled Dipole Array -- 5.14 Conclusions -- 5.15 Problems -- References -- 6 Transmit/Receive Modules -- 6.1 Introduction -- 6.2 Technical Challenges Often Faced in T/R Module Development -- 6.2.1 Heat Transfer -- 6.2.2 Signal Integrity -- 6.2.3 Integration with Other Functions -- 6.2.4 Materials Compatibility -- 6.2.5 Electromagnetic Coupling -- 6.3 General Description of the T/R Module -- 6.3.1 System Location of the T/R Module -- 6.3.2 T/R Block Diagram -- 6.4 T/R Module Detailed Description -- 6.4.1 Low Noise Amplifier -- 6.4.2 Low Noise Amplifier Protection -- 6.4.3 High-Power Amplifier and Driver Amplifier -- 6.4.4 Phase Shifter -- 6.4.5 Duplexer -- 6.5 T/R Module Manufacturing and Test -- 6.5.1 Integrated Circuit Manufacturing -- 6.5.2 Package Manufacturing -- 6.5.3 Interconnects Types -- 6.5.4 T/R Module Test -- 6.6 Examples of T/R Modules -- 6.6.1 A 3-D Ceramic T/R Module for Space-Based Applications -- 6.6.2 T/R Module Using Laminate Circuit Board Technology -- 6.6.3 60-GHz CMOS T/R Module Integrated with Antennas -- 6.7 Conclusions -- 6.8 Problems -- References -- 7 Thermal Design, Heat Transfer Trade Studies, and Reliability -- 7.1 Introduction -- 7.2 Heat Transfer Fundamentals at the Integrated Circuit Level -- 7.3 Reliability and MTTF -- 7.4 Example: Millimeter-Wave SATCOM Front End -- 7.5 Array Cooling Methods -- 7.5.1 The Challenge of Phased Array Cooling -- 7.5.2 Brick Array Cooling -- 7.5.3 Tile Array Cooling -- 7.6 Other Reliability Drivers for Phased Arrays -- 7.7 Materials Used for Thermal Management -- 7.8 Conclusions -- 7.9 Problems -- References -- 8 Analog versus Digital Beamforming -- 8.1 Introduction. 8.2 Benefits and Challenges in Analog Beamforming -- 8.3 Benefits and Challenges in Digital Beamforming -- 8.4 Basic Digital Beamforming -- 8.5 Adaptive Beamforming -- 8.6 Errors in Beamforming and Their Effects -- 8.7 Multiple Access Methods for 5G Phased Arrays -- 8.7.1 Orthogonal Frequency Division Multiple Access -- 8.7.2 Code Division Multiple Access -- 8.7.3 Other Access Technologies -- 8.8 Conclusions -- 8.9 Problems -- References -- 9 Digital Receiver Exciters -- 9.1 Introduction -- 9.2 Digital Receiver Architecture Options -- 9.3 Example Trade Study on Digital Receiver Architecture -- 9.4 Digital Exciter Architecture Options -- 9.5 Main Components of a Digital Receiver Exciter -- 9.5.1 Low Noise Amplifier -- 9.5.2 Digital Attenuator -- 9.5.3 Frequency Mixer -- 9.5.4 Preselection, Image Rejection, and Antialiasing Filters -- 9.5.5 Frequency Multipliers -- 9.5.6 ADC -- 9.6 Analysis of DRXs -- 9.7 Conclusions -- 9.8 Problems -- References -- Part III System Modeling and Advanced Development Activities -- 10 Phased Array System Modeling -- 10.1 Introduction -- 10.2 LFOV Receiver Array -- 10.3 Multichannel Communication System Design -- 10.4 Stripmap Synthetic Aperture Radar -- 10.5 Radar Detection Performance -- 10.6 Conclusions -- 10.7 Problems -- References -- Appendix 10A Excel Spreadsheet for the LFOV Array -- Appendix 10B Scilab Code for the Communication System Receiver Array -- Appendix 10C Scilab Code for the Stripmap SAR Simulation -- Appendix 10D Gaussian ROC Curve Derivation -- 11 Advanced Development Activities for Phased Arrays -- 11.1 Introduction -- 11.2 System Risk Management -- 11.3 Advanced Development Activities -- 11.4 Types of Advanced Development Risk Reduction Activities -- 11.5 Typical Risks in Phased Array Development -- 11.6 Advanced Development Impacts All Levels of the System -- 11.7 Other Risk Analysis Topics. 11.8 Conclusions -- 11.9 Problems -- References -- 12 Conclusions -- About the Authors -- Index. |
| Record Nr. | UNINA-9910809047303321 |
|
Sturdivant Rick
|
||
| Boston : , : Artech House, , [2019] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
