Coupled-oscillator based active-array antennas / / Ronald J. Pogorzelski Jet Propulsion labortary, California Institute of Technology, Apostolos Georgiadis, Centre Tecnoláogic de Telecomunicacions de Catalunya, Castelldefels, Barcelona, Spain |
Autore | Pogorzelski Ronald J. |
Edizione | [1st edition] |
Pubbl/distr/stampa | Hoboken, New Jersey : , : Wiley, John Wiley & Sons Inc. Publication, , [2012] |
Descrizione fisica | 1 online resource (382 p.) |
Disciplina | 621.382/4 |
Altri autori (Persone) | GeorgiadisApostolos |
Collana | JPL deep-space communications and navigation series |
Soggetto topico |
Antenna arrays
Electric networks, Active Nonlinear oscillators Coupled mode theory |
ISBN |
1-283-54293-5
9786613855381 1-118-30996-0 1-118-30997-9 1-118-31001-2 |
Classificazione | TEC008000 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
-- Foreword xi -- Preface xiii -- Acknowledgments xvii -- Authors xix -- PART I: THEORY AND ANALYSIS 1 -- Chapter 1 Introduction - Oscillators and Synchronization 3 -- 1.1 Early Work in Mathematical Biology and Electronic Circuits 3 -- 1.2 van der Pol's Model 5 -- 1.3 Injection Locking (Adier's Formalism) and Its Spectra (Locked and Unlocked) 7 -- 1.4 Mutual Injection Locking of Two Oscillators 21 -- 1.5 Conclusion 26 -- Chapter 2 Coupled-Oscillator Arrays-Basic Analytical Description and Operating Principles 27 -- 2.1 Fundamental Equations 28 -- 2.2 Discrete Model Solution (Linearization and Laplace Transformation) 31 -- 2.3 Steady-State Solution 37 -- 2.4 Stability of the Phase Solution in the Full Nonlinear Formulation 41 -- 2.5 External Injection Locking 46 -- 2.6 Generalization to Planar Arrays 50 -- 2.7 Coupling Networks 54 -- 2.8 Conclusion 66 -- Chapter 3 The Continuum Model for Linear Arrays 67 -- 3.1 The Linear Array without External Injection 68 -- 3.2 The Linear Array with External Injection 81 -- 3.3 Beam-Steering via End Detuning 93 -- 3.4 Beam-Steering via End Injection 95 -- 3.5 Conclusion 102 -- Chapter 4 The Continuum Model for Planar Arrays 103 -- 4.1 Cartesian Coupling in the Continuum Model without External Injection 103 -- 4.2 Cartesian Coupling in the Continuum Model with External Injection 109 -- 4.3 Non-Cartesian Coupling Topologies 118 -- 4.4 Conclusion 137 -- Chapter 5 Causality and Coupling Delay 139 -- 5.1 Coupling Delay 139 -- 5.2 The Discrete Model with Coupling Delay 141 -- 5.3 The Continuum Model with Coupling Delay 146 -- 5.4 Beam Steering in the Continuum Model with Coupling Delay 159 -- 5.5 Conclusion 173 -- PART II: EXPERIMENTAL WORK AND APPLICATIONS 175 -- Chapter 6 Experimental Validation of the Theory 177 -- 6.1 Linear-Array Experiments 177 -- 6.2 Planar-Array Experiments 188 -- 6.3 Receive-Array Experiments 201 -- 6.4 Phase Noise 210 -- 6.5 The Unlocked State 213 -- 6.6 Conclusion 215 -- PART III: NONLINEAR BEHAVIOR 217 -- Chapter 7 Perturbation Models for Stability, Phase Noise, and Modulation 219.
7.1 Preliminaries of Dynamical Systems 220 -- 7.2 Bifurcations of Nonlinear Dynamical Systems 226 -- 7.3 The Averaging Method and Multiple Time Scales 230 -- 7.4 Averaging Theory in Coupled Oscillator Systems 231 -- 7.5 Obtaining the Parameters of the van der Pol Oscillator Model 235 -- 7.6 An Alternative Perturbation Model for Coupled-Oscillator Systems 238 -- 7.7 Matrix Equations for the Steady State and Stability Analysis 242 -- 7.8 A Comparison between the Two Perturbation Models for Coupled Oscillator Systems 246 -- 7.9 Externally Injection-Locked COAs 247 -- 7.10 Phase Noise 250 -- 7.11 Modulation 256 -- 7.12 Coupled Phase-Locked Loops 258 -- 7.13 Conclusion 261 -- Chapter 8 Numerical Methods for Simulating Coupled-Oscillator Arrays 263 -- 8.1 Introduction to Numerical Methods 264 -- 8.2 Obtaining Periodic Steady-State Solutions of Autonomous Circuits in Harmonic-Balance Simulators 270 -- 8.3 Numerical Analysis of a Voltage-Controlled Oscillator 272 -- 8.4 Numerical Analysis of a Five-Element Linear Coupled-Oscillator Array 278 -- 8.5 Numerical Analysis of an Externally Injection-Locked Five-Element Linear Coupled-Oscillator Array 286 -- 8.6 Harmonic Radiation for Extended Scanning Range 288 -- 8.7 Numerical Analysis of a Self-Oscillating Mixer 291 -- 8.8 Conclusion 296 -- Chapter 9 Beamforming in Coupled-Oscillator Arrays 297 -- 9.1 Preliminary Concepts of Convex Optimization 297 -- 9.2 Beamforming in COAs 301 -- 9.3 Stability Optimization of the Coupled-Oscillator Steady-State Solution 308 -- 9.4 Multi-Beam Pattern Generation Using Coupled-Oscillator Arrays 311 -- 9.5 Control of the Amplitude Dynamics 315 -- 9.6 Adaptive Coupled-Oscillator Array Beamformer 317 -- 9.7 Conclusion 320 -- Chapter 10 Overall Conclusions and Possible Future Directions 321 -- REFERENCES 325 -- ACRONYMS AND ABBREVIATIONS 341 -- INDEX 345. |
Record Nr. | UNINA-9910138869403321 |
Pogorzelski Ronald J.
![]() |
||
Hoboken, New Jersey : , : Wiley, John Wiley & Sons Inc. Publication, , [2012] | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
|
Coupled-oscillator based active-array antennas / / Ronald J. Pogorzelski Jet Propulsion labortary, California Institute of Technology, Apostolos Georgiadis, Centre Tecnoláogic de Telecomunicacions de Catalunya, Castelldefels, Barcelona, Spain |
Autore | Pogorzelski Ronald J. |
Edizione | [1st edition] |
Pubbl/distr/stampa | Hoboken, New Jersey : , : Wiley, John Wiley & Sons Inc. Publication, , [2012] |
Descrizione fisica | 1 online resource (382 p.) |
Disciplina | 621.382/4 |
Altri autori (Persone) | GeorgiadisApostolos |
Collana | JPL deep-space communications and navigation series |
Soggetto topico |
Antenna arrays
Electric networks, Active Nonlinear oscillators Coupled mode theory |
ISBN |
1-283-54293-5
9786613855381 1-118-30996-0 1-118-30997-9 1-118-31001-2 |
Classificazione | TEC008000 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
-- Foreword xi -- Preface xiii -- Acknowledgments xvii -- Authors xix -- PART I: THEORY AND ANALYSIS 1 -- Chapter 1 Introduction - Oscillators and Synchronization 3 -- 1.1 Early Work in Mathematical Biology and Electronic Circuits 3 -- 1.2 van der Pol's Model 5 -- 1.3 Injection Locking (Adier's Formalism) and Its Spectra (Locked and Unlocked) 7 -- 1.4 Mutual Injection Locking of Two Oscillators 21 -- 1.5 Conclusion 26 -- Chapter 2 Coupled-Oscillator Arrays-Basic Analytical Description and Operating Principles 27 -- 2.1 Fundamental Equations 28 -- 2.2 Discrete Model Solution (Linearization and Laplace Transformation) 31 -- 2.3 Steady-State Solution 37 -- 2.4 Stability of the Phase Solution in the Full Nonlinear Formulation 41 -- 2.5 External Injection Locking 46 -- 2.6 Generalization to Planar Arrays 50 -- 2.7 Coupling Networks 54 -- 2.8 Conclusion 66 -- Chapter 3 The Continuum Model for Linear Arrays 67 -- 3.1 The Linear Array without External Injection 68 -- 3.2 The Linear Array with External Injection 81 -- 3.3 Beam-Steering via End Detuning 93 -- 3.4 Beam-Steering via End Injection 95 -- 3.5 Conclusion 102 -- Chapter 4 The Continuum Model for Planar Arrays 103 -- 4.1 Cartesian Coupling in the Continuum Model without External Injection 103 -- 4.2 Cartesian Coupling in the Continuum Model with External Injection 109 -- 4.3 Non-Cartesian Coupling Topologies 118 -- 4.4 Conclusion 137 -- Chapter 5 Causality and Coupling Delay 139 -- 5.1 Coupling Delay 139 -- 5.2 The Discrete Model with Coupling Delay 141 -- 5.3 The Continuum Model with Coupling Delay 146 -- 5.4 Beam Steering in the Continuum Model with Coupling Delay 159 -- 5.5 Conclusion 173 -- PART II: EXPERIMENTAL WORK AND APPLICATIONS 175 -- Chapter 6 Experimental Validation of the Theory 177 -- 6.1 Linear-Array Experiments 177 -- 6.2 Planar-Array Experiments 188 -- 6.3 Receive-Array Experiments 201 -- 6.4 Phase Noise 210 -- 6.5 The Unlocked State 213 -- 6.6 Conclusion 215 -- PART III: NONLINEAR BEHAVIOR 217 -- Chapter 7 Perturbation Models for Stability, Phase Noise, and Modulation 219.
7.1 Preliminaries of Dynamical Systems 220 -- 7.2 Bifurcations of Nonlinear Dynamical Systems 226 -- 7.3 The Averaging Method and Multiple Time Scales 230 -- 7.4 Averaging Theory in Coupled Oscillator Systems 231 -- 7.5 Obtaining the Parameters of the van der Pol Oscillator Model 235 -- 7.6 An Alternative Perturbation Model for Coupled-Oscillator Systems 238 -- 7.7 Matrix Equations for the Steady State and Stability Analysis 242 -- 7.8 A Comparison between the Two Perturbation Models for Coupled Oscillator Systems 246 -- 7.9 Externally Injection-Locked COAs 247 -- 7.10 Phase Noise 250 -- 7.11 Modulation 256 -- 7.12 Coupled Phase-Locked Loops 258 -- 7.13 Conclusion 261 -- Chapter 8 Numerical Methods for Simulating Coupled-Oscillator Arrays 263 -- 8.1 Introduction to Numerical Methods 264 -- 8.2 Obtaining Periodic Steady-State Solutions of Autonomous Circuits in Harmonic-Balance Simulators 270 -- 8.3 Numerical Analysis of a Voltage-Controlled Oscillator 272 -- 8.4 Numerical Analysis of a Five-Element Linear Coupled-Oscillator Array 278 -- 8.5 Numerical Analysis of an Externally Injection-Locked Five-Element Linear Coupled-Oscillator Array 286 -- 8.6 Harmonic Radiation for Extended Scanning Range 288 -- 8.7 Numerical Analysis of a Self-Oscillating Mixer 291 -- 8.8 Conclusion 296 -- Chapter 9 Beamforming in Coupled-Oscillator Arrays 297 -- 9.1 Preliminary Concepts of Convex Optimization 297 -- 9.2 Beamforming in COAs 301 -- 9.3 Stability Optimization of the Coupled-Oscillator Steady-State Solution 308 -- 9.4 Multi-Beam Pattern Generation Using Coupled-Oscillator Arrays 311 -- 9.5 Control of the Amplitude Dynamics 315 -- 9.6 Adaptive Coupled-Oscillator Array Beamformer 317 -- 9.7 Conclusion 320 -- Chapter 10 Overall Conclusions and Possible Future Directions 321 -- REFERENCES 325 -- ACRONYMS AND ABBREVIATIONS 341 -- INDEX 345. |
Record Nr. | UNINA-9910807179403321 |
Pogorzelski Ronald J.
![]() |
||
Hoboken, New Jersey : , : Wiley, John Wiley & Sons Inc. Publication, , [2012] | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
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Mathematical control theory of coupled PDEs / Irena Lasiecka |
Autore | Lasiecka, Irena |
Pubbl/distr/stampa | Philadelphia : Society for Industrial and Applied Mathematics, c2002 |
Descrizione fisica | xii, 242 p. : ill. ; 25 cm |
Disciplina | 629.8312 |
Collana | CBMS-NSF regional conference series in applied mathematics ; 75 |
Soggetto topico |
Control theory
Hyperbolic differential equations Parabolic differential equations Coupled mode theory |
ISBN | 0898714869 |
Classificazione |
AMS 93-02
AMS 35B37 AMS 49J20 AMS 74H45 AMS 74M05 AMS 93C20 LC QA402.3.L333 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Record Nr. | UNISALENTO-991001585699707536 |
Lasiecka, Irena
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Philadelphia : Society for Industrial and Applied Mathematics, c2002 | ||
![]() | ||
Lo trovi qui: Univ. del Salento | ||
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Mutual coupling between antennas / / editor, Trevor S. Bird |
Pubbl/distr/stampa | Hoboken, NJ : , : John Wiley & Sons, , [2021] |
Descrizione fisica | 1 online resource (483 pages) |
Disciplina | 621.3824 |
Soggetto topico |
Antenna arrays
Coupled mode theory Electromagnetic interference |
Soggetto genere / forma | Electronic books. |
ISBN |
1-119-56497-2
1-119-56488-3 1-119-56504-9 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Cover -- Title Page -- Copyright -- Contents -- Preface -- Acknowledgments -- List of Contributors -- Notation -- Chapter 1 Introduction -- 1.1 Aims and Scope -- 1.2 Historical Perspective -- 1.3 Overview of Text -- References -- Chapter 2 Basics of Antenna Mutual Coupling -- 2.1 Introduction -- 2.2 Electromagnetic Field Quantities -- 2.2.1 Definitions -- 2.2.2 Field Representations in Source‐Free Regions -- 2.3 Mutual Coupling Between Elementary Sources -- 2.3.1 Radiation -- 2.3.2 Generalized Infinitesimal Current Elements -- 2.3.3 Mutual Coupling Between Infinitesimal Current Elements -- 2.4 Network Representation of Mutual Coupling -- 2.4.1 Extension to Combination of Elements -- 2.4.2 Mutual Impedance and Admittance Matrix Formulation -- 2.4.3 Scattering Matrix Representation -- 2.5 Radiation from Antennas in the Presence of Mutual Coupling -- 2.5.1 Far‐Field Radiation -- 2.5.2 Magnetic Current Only -- 2.5.3 Electric Current Only -- 2.6 Conclusion -- References -- Chapter 3 Methods in the Analysis of Mutual Coupling in Antennas -- 3.1 Introduction -- 3.2 Mutual Coupling in Antennas with Continuous Sources -- 3.2.1 Impedance and Admittance with Continuous Sources -- 3.2.2 Reaction -- 3.2.3 Definition of Circuit Quantities -- 3.3 On Finite and Infinite Arrays -- 3.3.1 Finite Array Analysis by Element‐by‐Element Method -- 3.3.2 Infinite Periodic Array Analysis -- 3.4 Integral Equation Methods Used in Coupling Analysis -- 3.4.1 Introduction -- 3.4.2 Green's Function Methods -- 3.4.2.1 Free‐Space Green's Function for Harmonic Sources -- 3.4.2.2 Free‐Space Green's Function for Transient Sources -- 3.4.2.3 Fields with Sources -- 3.4.3 Solution by Weighted Residuals -- 3.5 Some Other Methods Used in Coupling Analysis -- 3.5.1 Unit Cell Analysis in Periodic Structure Method -- 3.5.2 Mode Matching Methods -- 3.5.3 Moment Methods.
3.5.4 Method of Characteristic Modes -- 3.5.5 Minimum Scattering Element Method -- 3.6 Practical Aspects of Numerical Methods in Mutual Coupling Analysis -- 3.6.1 Introduction -- 3.6.2 Numerical Quadrature -- 3.6.3 Matrix Inversion -- 3.7 Conclusion -- References -- Chapter 4 Mutual Coupling in Arrays of Wire Antennas -- 4.1 Introduction -- 4.2 Formulation of the Problem -- 4.2.1 Moment Method -- 4.2.2 Moment Method Solution for the Dipole -- 4.3 Mutual Impedance -- 4.3.1 Closed Form Expressions for Mutual Impedance -- 4.3.2 Asymptotic Approximations to Mutual Impedance -- 4.4 Arrays of Wire Antennas -- 4.4.1 Full‐Wave Dipole Above a Perfect Ground -- 4.4.2 The Yagi-Uda Array -- 4.4.3 7 x 7 array of closely packed elements -- 4.5 Concluding Remarks -- References -- Chapter 5 Arrays of Planar Aperture Antennas -- 5.1 Introduction -- 5.2 Mutual Coupling in Waveguide and Horn Arrays -- 5.2.1 Integral Equation Formulation -- 5.2.2 Modal Representation -- 5.2.3 Modeling of Profiled Horns and Mode Matching -- 5.2.4 Asymptotic Approximation of Mutual Admittance -- 5.3 Coupling in Rectangular Waveguides and Horns -- 5.3.1 Self‐Admittance of TE10 Mode -- 5.3.2 Example of Mutual Coupling Between Different‐Sized Waveguides -- 5.3.3 Application to Horns -- 5.3.4 Waveguide‐Fed Slot Arrays -- 5.3.5 Asymptotic Approximation of Coupling in Rectangular Apertures -- 5.3.6 Coupling in Horns Approximated with Quadratic Phase -- 5.4 Coupling in Arrays of Coaxial Waveguides and Horns -- 5.4.1 Self‐Admittance of TE11 Mode in Coaxial Waveguide -- 5.4.2 TEM Mode Coupling in Coaxial Waveguide -- 5.4.3 Asymptotic Approximation of Coupling in Coaxial Waveguide Apertures -- 5.4.4 Coaxial and Circular Aperture Array Examples -- 5.5 Mutual Coupling Between Apertures of General Cross‐Section -- 5.5.1 Elliptical Apertures -- 5.5.2 General Apertures. 5.6 Coupling in Apertures Loaded with Dielectrics and Metamaterials -- 5.6.1 Dielectric‐Loaded Apertures -- 5.6.2 Metamaterial‐Loaded Apertures -- 5.7 Concluding Remarks -- References -- Chapter 6 Arrays of Microstrip Patch Antennas -- 6.1 Introduction -- 6.2 Representation of Mutual Coupling Between Patch Antennas -- 6.2.1 E‐Current Model of Coupling -- 6.2.2 Cavity Model (H‐Model) of Coupling -- 6.2.3 Full‐Wave Solution -- 6.3 Applications of Microstrip Arrays -- 6.3.1 Mutual Coupling Between Microstrip Patches -- 6.3.2 Steering by Switching Parasitic Elements -- 6.3.3 A Metasurface from Microstrip Patches -- 6.4 Concluding Remarks -- References -- Chapter 7 Mutual Coupling Between Antennas on Conformal Surfaces -- 7.1 Introduction -- 7.2 Mutual Admittance of Apertures on Slowly Curving Surfaces -- 7.2.1 Green's Function Formulation for Curved Surfaces -- 7.2.2 The Cylinder -- 7.2.3 The Sphere -- 7.3 Asymptotic Solution for Fields Near Convex Surfaces -- 7.3.1 Review of Literature for Convex Surfaces -- 7.3.2 Asymptotic Solution for the Surface Fields -- 7.4 Mutual Coupling of Apertures in Quadric Surfaces -- 7.4.1 Closed‐Form Expressions for Mutual Coupling Between Rectangular Waveguides in a Cylinder -- 7.4.2 Expressions for Mutual Coupling Between Circular Waveguides in a Sphere -- 7.4.3 Mutual Coupling Between Microstrip Patches on a Cylinder -- 7.5 Extension of Canonical Solution to Large Convex Surfaces with Slowly Varying Curvature -- 7.6 Applications of Coupling on Curved Surfaces -- 7.6.1 Mutual Coupling in a Waveguide Array on a Cylinder -- 7.6.2 Mutual Coupling Between Monopoles on a Cylinder -- 7.6.3 Mutual Coupling Between Waveguides on an Ellipsoid -- 7.7 Conclusion -- References -- Chapter 8 Mutual Coupling Between Co‐Sited Antennas and Antennas on Large Structures -- 8.1 Preliminaries and Assumptions -- 8.1.1 The Problem at Hand. 8.1.2 Course Adopted -- 8.2 Full‐Wave CEM Modeling View of a Single Antenna -- 8.3 Full‐Wave CEM Modeling View of Coupled Antennas in the Presence of a Host Platform -- 8.3.1 Field Point of View -- 8.3.2 Two‐Port Network Parameter Point of View -- 8.4 Useful Expressions for Coupling in the Presence of a Host Platform -- 8.4.1 Motivation -- 8.4.2 Reciprocity and Reaction Theorems Revisited -- 8.4.3 Generalized Reaction Theorem -- 8.4.4 Expressions for Mutual Impedance and Open Circuit Voltage -- 8.4.5 Power Coupling -- 8.5 Supplementary Comments on CEM Modeling Methods -- 8.6 Full‐Wave CEM Modeling of Coupled Antennas on a Platform - The Ideal -- 8.7 Reduced Complexity Antenna Electromagnetic Models -- 8.7.1 Necessity for Simplified Antenna Models -- 8.7.2 Huygens' Box Model -- 8.7.3 Spherical Wave Expansion Models -- 8.7.4 Infinitesimal Dipole Models -- 8.7.5 Planar Aperture Models -- 8.7.6 Point Source Models -- 8.8 CEM Modeling of Coupled Antennas on a Platform - Pragmatic Approaches -- 8.9 Co‐Sited Antenna Coupling Computation Examples -- 8.10 Concluding Remarks -- References -- Chapter 9 Mutual Coupling and Multiple‐Input Multiple‐Output (MIMO) Communications -- 9.1 Introduction -- 9.2 Previous Work on Mutual Coupling and MIMO -- 9.3 Basics of MIMO Communications -- 9.3.1 MIMO Channel Capacity -- 9.3.2 Eigenchannels and the Water‐Filling Solution -- 9.3.3 Eigenchannels in MIMO Systems and Beamforming Arrays -- 9.3.4 Reference Planes and the Intrinsic Channel Matrix -- 9.4 Mutual Coupling and MIMO Transmitting Arrays -- 9.4.1 Radiated Electric Field and Embedded Element Patterns -- 9.4.2 Pattern Overlap Matrix, Conservation of Energy, and Mutual Coupling -- 9.4.3 Gain and Directivity in the Overlap Matrix Formulation -- 9.4.4 Overlap Matrix for Isotropic Radiators. 9.4.5 Mutual Coupling for Closely Spaced Elements, Superdirectivity, and Q‐Factor Bounds -- 9.4.6 EEPs, Mutual Coupling, and Minimum Scattering Antennas -- 9.4.7 Mutual Coupling and Interactions Between Elements -- 9.4.8 Transmitter Power Constraint -- 9.4.9 Impedance Matching at the Transmitter -- 9.5 Mutual Coupling and MIMO Receiving Arrays -- 9.5.1 Receive Array Signal and Noise Model -- 9.5.2 Receive Array Thévenin Equivalent Network -- 9.5.3 Loaded Receive Array Output Voltages -- 9.5.4 External Noise and Loss Noise -- 9.5.5 Signal Correlation Matrix -- 9.5.6 Signal Correlation in a Rich Multipath Environment -- 9.5.7 Mutual Coupling, Noise Matching, and Equivalent Receiver Noise -- 9.5.7.1 Active Impedances for Receiving Arrays -- 9.5.7.2 Equivalent Receiver Noise Temperature and Active Impedance Matching -- 9.5.7.3 Noise Matching Efficiency -- 9.6 Conclusion -- References -- Chapter 10 Mutual Coupling in Beamforming and Interferometric Antennas -- 10.1 Introduction -- 10.2 The Array Manifold -- 10.3 Direction‐of‐Arrival Algorithms -- 10.3.1 Matrix Pencil Method for Direction of Arrival Estimation -- 10.4 Maximum Gain Design for Single and Multiple Beams -- 10.4.1 Penalty Function Optimization of Array Parameters -- 10.4.2 Method of Successive Projections -- 10.4.3 Comparison of Penalty Functions and Successive Projections -- 10.5 Direction‐of‐Arrival Estimation -- 10.5.1 No Coupling Situation -- 10.5.1.1 Cramer‐Rao Lower Bound -- 10.5.1.2 Four‐Element Linear Arrays with Different Apertures (Two Incoming Signals) -- 10.5.1.3 Fixed Aperture Uniform Linear Arrays with Different Numbers of Elements (Two Incoming Signals) -- 10.5.1.4 Fixed Aperture Uniform Linear Arrays with Different Number of Elements (Three Incoming Signals) -- 10.5.2 Perturbation Due to Mutual Coupling. 10.5.2.1 Eight‐Element Linear Arrays with Different Apertures (Three Incoming Signals). |
Record Nr. | UNINA-9910554854103321 |
Hoboken, NJ : , : John Wiley & Sons, , [2021] | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
|
Mutual coupling between antennas / / editor, Trevor S. Bird |
Pubbl/distr/stampa | Hoboken, NJ : , : John Wiley & Sons, , [2021] |
Descrizione fisica | 1 online resource (483 pages) |
Disciplina | 621.3824 |
Soggetto topico |
Antenna arrays
Coupled mode theory Electromagnetic interference |
ISBN |
1-119-56497-2
1-119-56488-3 1-119-56504-9 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Cover -- Title Page -- Copyright -- Contents -- Preface -- Acknowledgments -- List of Contributors -- Notation -- Chapter 1 Introduction -- 1.1 Aims and Scope -- 1.2 Historical Perspective -- 1.3 Overview of Text -- References -- Chapter 2 Basics of Antenna Mutual Coupling -- 2.1 Introduction -- 2.2 Electromagnetic Field Quantities -- 2.2.1 Definitions -- 2.2.2 Field Representations in Source‐Free Regions -- 2.3 Mutual Coupling Between Elementary Sources -- 2.3.1 Radiation -- 2.3.2 Generalized Infinitesimal Current Elements -- 2.3.3 Mutual Coupling Between Infinitesimal Current Elements -- 2.4 Network Representation of Mutual Coupling -- 2.4.1 Extension to Combination of Elements -- 2.4.2 Mutual Impedance and Admittance Matrix Formulation -- 2.4.3 Scattering Matrix Representation -- 2.5 Radiation from Antennas in the Presence of Mutual Coupling -- 2.5.1 Far‐Field Radiation -- 2.5.2 Magnetic Current Only -- 2.5.3 Electric Current Only -- 2.6 Conclusion -- References -- Chapter 3 Methods in the Analysis of Mutual Coupling in Antennas -- 3.1 Introduction -- 3.2 Mutual Coupling in Antennas with Continuous Sources -- 3.2.1 Impedance and Admittance with Continuous Sources -- 3.2.2 Reaction -- 3.2.3 Definition of Circuit Quantities -- 3.3 On Finite and Infinite Arrays -- 3.3.1 Finite Array Analysis by Element‐by‐Element Method -- 3.3.2 Infinite Periodic Array Analysis -- 3.4 Integral Equation Methods Used in Coupling Analysis -- 3.4.1 Introduction -- 3.4.2 Green's Function Methods -- 3.4.2.1 Free‐Space Green's Function for Harmonic Sources -- 3.4.2.2 Free‐Space Green's Function for Transient Sources -- 3.4.2.3 Fields with Sources -- 3.4.3 Solution by Weighted Residuals -- 3.5 Some Other Methods Used in Coupling Analysis -- 3.5.1 Unit Cell Analysis in Periodic Structure Method -- 3.5.2 Mode Matching Methods -- 3.5.3 Moment Methods.
3.5.4 Method of Characteristic Modes -- 3.5.5 Minimum Scattering Element Method -- 3.6 Practical Aspects of Numerical Methods in Mutual Coupling Analysis -- 3.6.1 Introduction -- 3.6.2 Numerical Quadrature -- 3.6.3 Matrix Inversion -- 3.7 Conclusion -- References -- Chapter 4 Mutual Coupling in Arrays of Wire Antennas -- 4.1 Introduction -- 4.2 Formulation of the Problem -- 4.2.1 Moment Method -- 4.2.2 Moment Method Solution for the Dipole -- 4.3 Mutual Impedance -- 4.3.1 Closed Form Expressions for Mutual Impedance -- 4.3.2 Asymptotic Approximations to Mutual Impedance -- 4.4 Arrays of Wire Antennas -- 4.4.1 Full‐Wave Dipole Above a Perfect Ground -- 4.4.2 The Yagi-Uda Array -- 4.4.3 7 x 7 array of closely packed elements -- 4.5 Concluding Remarks -- References -- Chapter 5 Arrays of Planar Aperture Antennas -- 5.1 Introduction -- 5.2 Mutual Coupling in Waveguide and Horn Arrays -- 5.2.1 Integral Equation Formulation -- 5.2.2 Modal Representation -- 5.2.3 Modeling of Profiled Horns and Mode Matching -- 5.2.4 Asymptotic Approximation of Mutual Admittance -- 5.3 Coupling in Rectangular Waveguides and Horns -- 5.3.1 Self‐Admittance of TE10 Mode -- 5.3.2 Example of Mutual Coupling Between Different‐Sized Waveguides -- 5.3.3 Application to Horns -- 5.3.4 Waveguide‐Fed Slot Arrays -- 5.3.5 Asymptotic Approximation of Coupling in Rectangular Apertures -- 5.3.6 Coupling in Horns Approximated with Quadratic Phase -- 5.4 Coupling in Arrays of Coaxial Waveguides and Horns -- 5.4.1 Self‐Admittance of TE11 Mode in Coaxial Waveguide -- 5.4.2 TEM Mode Coupling in Coaxial Waveguide -- 5.4.3 Asymptotic Approximation of Coupling in Coaxial Waveguide Apertures -- 5.4.4 Coaxial and Circular Aperture Array Examples -- 5.5 Mutual Coupling Between Apertures of General Cross‐Section -- 5.5.1 Elliptical Apertures -- 5.5.2 General Apertures. 5.6 Coupling in Apertures Loaded with Dielectrics and Metamaterials -- 5.6.1 Dielectric‐Loaded Apertures -- 5.6.2 Metamaterial‐Loaded Apertures -- 5.7 Concluding Remarks -- References -- Chapter 6 Arrays of Microstrip Patch Antennas -- 6.1 Introduction -- 6.2 Representation of Mutual Coupling Between Patch Antennas -- 6.2.1 E‐Current Model of Coupling -- 6.2.2 Cavity Model (H‐Model) of Coupling -- 6.2.3 Full‐Wave Solution -- 6.3 Applications of Microstrip Arrays -- 6.3.1 Mutual Coupling Between Microstrip Patches -- 6.3.2 Steering by Switching Parasitic Elements -- 6.3.3 A Metasurface from Microstrip Patches -- 6.4 Concluding Remarks -- References -- Chapter 7 Mutual Coupling Between Antennas on Conformal Surfaces -- 7.1 Introduction -- 7.2 Mutual Admittance of Apertures on Slowly Curving Surfaces -- 7.2.1 Green's Function Formulation for Curved Surfaces -- 7.2.2 The Cylinder -- 7.2.3 The Sphere -- 7.3 Asymptotic Solution for Fields Near Convex Surfaces -- 7.3.1 Review of Literature for Convex Surfaces -- 7.3.2 Asymptotic Solution for the Surface Fields -- 7.4 Mutual Coupling of Apertures in Quadric Surfaces -- 7.4.1 Closed‐Form Expressions for Mutual Coupling Between Rectangular Waveguides in a Cylinder -- 7.4.2 Expressions for Mutual Coupling Between Circular Waveguides in a Sphere -- 7.4.3 Mutual Coupling Between Microstrip Patches on a Cylinder -- 7.5 Extension of Canonical Solution to Large Convex Surfaces with Slowly Varying Curvature -- 7.6 Applications of Coupling on Curved Surfaces -- 7.6.1 Mutual Coupling in a Waveguide Array on a Cylinder -- 7.6.2 Mutual Coupling Between Monopoles on a Cylinder -- 7.6.3 Mutual Coupling Between Waveguides on an Ellipsoid -- 7.7 Conclusion -- References -- Chapter 8 Mutual Coupling Between Co‐Sited Antennas and Antennas on Large Structures -- 8.1 Preliminaries and Assumptions -- 8.1.1 The Problem at Hand. 8.1.2 Course Adopted -- 8.2 Full‐Wave CEM Modeling View of a Single Antenna -- 8.3 Full‐Wave CEM Modeling View of Coupled Antennas in the Presence of a Host Platform -- 8.3.1 Field Point of View -- 8.3.2 Two‐Port Network Parameter Point of View -- 8.4 Useful Expressions for Coupling in the Presence of a Host Platform -- 8.4.1 Motivation -- 8.4.2 Reciprocity and Reaction Theorems Revisited -- 8.4.3 Generalized Reaction Theorem -- 8.4.4 Expressions for Mutual Impedance and Open Circuit Voltage -- 8.4.5 Power Coupling -- 8.5 Supplementary Comments on CEM Modeling Methods -- 8.6 Full‐Wave CEM Modeling of Coupled Antennas on a Platform - The Ideal -- 8.7 Reduced Complexity Antenna Electromagnetic Models -- 8.7.1 Necessity for Simplified Antenna Models -- 8.7.2 Huygens' Box Model -- 8.7.3 Spherical Wave Expansion Models -- 8.7.4 Infinitesimal Dipole Models -- 8.7.5 Planar Aperture Models -- 8.7.6 Point Source Models -- 8.8 CEM Modeling of Coupled Antennas on a Platform - Pragmatic Approaches -- 8.9 Co‐Sited Antenna Coupling Computation Examples -- 8.10 Concluding Remarks -- References -- Chapter 9 Mutual Coupling and Multiple‐Input Multiple‐Output (MIMO) Communications -- 9.1 Introduction -- 9.2 Previous Work on Mutual Coupling and MIMO -- 9.3 Basics of MIMO Communications -- 9.3.1 MIMO Channel Capacity -- 9.3.2 Eigenchannels and the Water‐Filling Solution -- 9.3.3 Eigenchannels in MIMO Systems and Beamforming Arrays -- 9.3.4 Reference Planes and the Intrinsic Channel Matrix -- 9.4 Mutual Coupling and MIMO Transmitting Arrays -- 9.4.1 Radiated Electric Field and Embedded Element Patterns -- 9.4.2 Pattern Overlap Matrix, Conservation of Energy, and Mutual Coupling -- 9.4.3 Gain and Directivity in the Overlap Matrix Formulation -- 9.4.4 Overlap Matrix for Isotropic Radiators. 9.4.5 Mutual Coupling for Closely Spaced Elements, Superdirectivity, and Q‐Factor Bounds -- 9.4.6 EEPs, Mutual Coupling, and Minimum Scattering Antennas -- 9.4.7 Mutual Coupling and Interactions Between Elements -- 9.4.8 Transmitter Power Constraint -- 9.4.9 Impedance Matching at the Transmitter -- 9.5 Mutual Coupling and MIMO Receiving Arrays -- 9.5.1 Receive Array Signal and Noise Model -- 9.5.2 Receive Array Thévenin Equivalent Network -- 9.5.3 Loaded Receive Array Output Voltages -- 9.5.4 External Noise and Loss Noise -- 9.5.5 Signal Correlation Matrix -- 9.5.6 Signal Correlation in a Rich Multipath Environment -- 9.5.7 Mutual Coupling, Noise Matching, and Equivalent Receiver Noise -- 9.5.7.1 Active Impedances for Receiving Arrays -- 9.5.7.2 Equivalent Receiver Noise Temperature and Active Impedance Matching -- 9.5.7.3 Noise Matching Efficiency -- 9.6 Conclusion -- References -- Chapter 10 Mutual Coupling in Beamforming and Interferometric Antennas -- 10.1 Introduction -- 10.2 The Array Manifold -- 10.3 Direction‐of‐Arrival Algorithms -- 10.3.1 Matrix Pencil Method for Direction of Arrival Estimation -- 10.4 Maximum Gain Design for Single and Multiple Beams -- 10.4.1 Penalty Function Optimization of Array Parameters -- 10.4.2 Method of Successive Projections -- 10.4.3 Comparison of Penalty Functions and Successive Projections -- 10.5 Direction‐of‐Arrival Estimation -- 10.5.1 No Coupling Situation -- 10.5.1.1 Cramer‐Rao Lower Bound -- 10.5.1.2 Four‐Element Linear Arrays with Different Apertures (Two Incoming Signals) -- 10.5.1.3 Fixed Aperture Uniform Linear Arrays with Different Numbers of Elements (Two Incoming Signals) -- 10.5.1.4 Fixed Aperture Uniform Linear Arrays with Different Number of Elements (Three Incoming Signals) -- 10.5.2 Perturbation Due to Mutual Coupling. 10.5.2.1 Eight‐Element Linear Arrays with Different Apertures (Three Incoming Signals). |
Record Nr. | UNINA-9910830936003321 |
Hoboken, NJ : , : John Wiley & Sons, , [2021] | ||
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Lo trovi qui: Univ. Federico II | ||
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On the steady motion of a coupled system solid-liquid / / Josef Bemelmans, Giovanni P. Galdi, Mads Kyed |
Autore | Bemelmans Josef |
Pubbl/distr/stampa | Providence, Rhode Island : , : American Mathematical Society, , 2013 |
Descrizione fisica | 1 online resource (102 p.) |
Disciplina | 530.4/17 |
Collana | Memoirs of the American Mathematical Society |
Soggetto topico |
Solid-liquid interfaces
Coupled mode theory Elastic solids Navier-Stokes equations |
Soggetto genere / forma | Electronic books. |
ISBN | 1-4704-1060-5 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
""Contents""; ""Chapter 1. Introduction""; ""Chapter 2. Notation and Preliminaries""; ""2.1. Notation""; ""2.2. Preliminaries""; ""Chapter 3. Steady Free Motion: Definition and Formulation of the Problem""; ""3.1. Equations of Motion for the Elastic Body""; ""3.2. Equations of Motion for the Liquid""; ""3.3. Definition of a Steady Free Motion""; ""3.4. Non-dimensionlization""; ""Chapter 4. Main Result""; ""4.1. Strategy of Proof""; ""4.2. Isolated Orientation""; ""4.3. Statement of the Main Theorem""; ""4.4. Perturbation Parameter""; ""4.5. The Stokes Problem""
""4.6. Perturbing Around an Isolated Orientation""""4.7. Compatibility Conditions""; ""Chapter 5. Approximating Problem in Bounded Domains""; ""5.1. Fixed-Point Approach""; ""5.2. Validity of the Compatibility Conditions""; ""5.3. Solvability of the Fluid Equations""; ""5.4. Solvability of the Elasticity Equations""; ""5.5. Existence in a Bounded Domain""; ""Chapter 6. Proof of Main Theorem""; ""Chapter 7. Bodies with Symmetry""; ""7.1. Symmetry Function Spaces""; ""7.2. Main Theorem for Symmetric Bodies""; ""7.3. Stokes Problem for a Symmetric Body"" ""7.4. Reformulation of the Equations of Motion""""7.5. Compatibility Conditions""; ""7.6. Approximating Problem in Bounded Domains""; ""7.7. Fixed-Point Approach""; ""7.8. Validity of the Compatibility Conditions""; ""7.9. Solvability of the Fluid Equations""; ""7.10. Solvability of the Elasticity Equations""; ""7.11. Existence in a Bounded Domain""; ""7.12. Proof of Main Theorem for Symmetric Bodies""; ""7.13. Examples""; ""Appendix A. Isolated Orientation""; ""Bibliography"" |
Record Nr. | UNINA-9910480646603321 |
Bemelmans Josef
![]() |
||
Providence, Rhode Island : , : American Mathematical Society, , 2013 | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
|
On the steady motion of a coupled system solid-liquid / / Josef Bemelmans, Giovanni P. Galdi, Mads Kyed |
Autore | Bemelmans Josef |
Pubbl/distr/stampa | Providence, Rhode Island : , : American Mathematical Society, , 2013 |
Descrizione fisica | 1 online resource (102 p.) |
Disciplina | 530.4/17 |
Collana | Memoirs of the American Mathematical Society |
Soggetto topico |
Solid-liquid interfaces
Coupled mode theory Elastic solids Navier-Stokes equations |
ISBN | 1-4704-1060-5 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
""Contents""; ""Chapter 1. Introduction""; ""Chapter 2. Notation and Preliminaries""; ""2.1. Notation""; ""2.2. Preliminaries""; ""Chapter 3. Steady Free Motion: Definition and Formulation of the Problem""; ""3.1. Equations of Motion for the Elastic Body""; ""3.2. Equations of Motion for the Liquid""; ""3.3. Definition of a Steady Free Motion""; ""3.4. Non-dimensionlization""; ""Chapter 4. Main Result""; ""4.1. Strategy of Proof""; ""4.2. Isolated Orientation""; ""4.3. Statement of the Main Theorem""; ""4.4. Perturbation Parameter""; ""4.5. The Stokes Problem""
""4.6. Perturbing Around an Isolated Orientation""""4.7. Compatibility Conditions""; ""Chapter 5. Approximating Problem in Bounded Domains""; ""5.1. Fixed-Point Approach""; ""5.2. Validity of the Compatibility Conditions""; ""5.3. Solvability of the Fluid Equations""; ""5.4. Solvability of the Elasticity Equations""; ""5.5. Existence in a Bounded Domain""; ""Chapter 6. Proof of Main Theorem""; ""Chapter 7. Bodies with Symmetry""; ""7.1. Symmetry Function Spaces""; ""7.2. Main Theorem for Symmetric Bodies""; ""7.3. Stokes Problem for a Symmetric Body"" ""7.4. Reformulation of the Equations of Motion""""7.5. Compatibility Conditions""; ""7.6. Approximating Problem in Bounded Domains""; ""7.7. Fixed-Point Approach""; ""7.8. Validity of the Compatibility Conditions""; ""7.9. Solvability of the Fluid Equations""; ""7.10. Solvability of the Elasticity Equations""; ""7.11. Existence in a Bounded Domain""; ""7.12. Proof of Main Theorem for Symmetric Bodies""; ""7.13. Examples""; ""Appendix A. Isolated Orientation""; ""Bibliography"" |
Record Nr. | UNINA-9910796033003321 |
Bemelmans Josef
![]() |
||
Providence, Rhode Island : , : American Mathematical Society, , 2013 | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
|
On the steady motion of a coupled system solid-liquid / / Josef Bemelmans, Giovanni P. Galdi, Mads Kyed |
Autore | Bemelmans Josef |
Pubbl/distr/stampa | Providence, Rhode Island : , : American Mathematical Society, , 2013 |
Descrizione fisica | 1 online resource (102 p.) |
Disciplina | 530.4/17 |
Collana | Memoirs of the American Mathematical Society |
Soggetto topico |
Solid-liquid interfaces
Coupled mode theory Elastic solids Navier-Stokes equations |
ISBN | 1-4704-1060-5 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
""Contents""; ""Chapter 1. Introduction""; ""Chapter 2. Notation and Preliminaries""; ""2.1. Notation""; ""2.2. Preliminaries""; ""Chapter 3. Steady Free Motion: Definition and Formulation of the Problem""; ""3.1. Equations of Motion for the Elastic Body""; ""3.2. Equations of Motion for the Liquid""; ""3.3. Definition of a Steady Free Motion""; ""3.4. Non-dimensionlization""; ""Chapter 4. Main Result""; ""4.1. Strategy of Proof""; ""4.2. Isolated Orientation""; ""4.3. Statement of the Main Theorem""; ""4.4. Perturbation Parameter""; ""4.5. The Stokes Problem""
""4.6. Perturbing Around an Isolated Orientation""""4.7. Compatibility Conditions""; ""Chapter 5. Approximating Problem in Bounded Domains""; ""5.1. Fixed-Point Approach""; ""5.2. Validity of the Compatibility Conditions""; ""5.3. Solvability of the Fluid Equations""; ""5.4. Solvability of the Elasticity Equations""; ""5.5. Existence in a Bounded Domain""; ""Chapter 6. Proof of Main Theorem""; ""Chapter 7. Bodies with Symmetry""; ""7.1. Symmetry Function Spaces""; ""7.2. Main Theorem for Symmetric Bodies""; ""7.3. Stokes Problem for a Symmetric Body"" ""7.4. Reformulation of the Equations of Motion""""7.5. Compatibility Conditions""; ""7.6. Approximating Problem in Bounded Domains""; ""7.7. Fixed-Point Approach""; ""7.8. Validity of the Compatibility Conditions""; ""7.9. Solvability of the Fluid Equations""; ""7.10. Solvability of the Elasticity Equations""; ""7.11. Existence in a Bounded Domain""; ""7.12. Proof of Main Theorem for Symmetric Bodies""; ""7.13. Examples""; ""Appendix A. Isolated Orientation""; ""Bibliography"" |
Record Nr. | UNINA-9910827608103321 |
Bemelmans Josef
![]() |
||
Providence, Rhode Island : , : American Mathematical Society, , 2013 | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
|
Synchronization in coupled chaotic circuits and systems [[electronic resource] /] / Chai Wah Wu |
Autore | Wu Chai Wah |
Pubbl/distr/stampa | River Edge, N.J., : World Scientific, c2002 |
Descrizione fisica | 1 online resource (187 p.) |
Disciplina | 621.3815 |
Collana | World Scientific series on nonlinear science. Series A, Monographs and treatises |
Soggetto topico |
Electronic circuits
Chaotic behavior in systems Coupled mode theory |
Soggetto genere / forma | Electronic books. |
ISBN | 981-277-842-X |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Contents ; Preface ; Chapter 1 Introduction ; Chapter 2 Synchronization in Two Coupled Chaotic Systems ; 2.1 Pecora-Carroll subsystem decomposition ; 2.2 Separable additive coupling ; 2.3 Synchronization and stability ; 2.3.1 Absolute stability ; 2.3.2 Lipschitz nonlinear systems
2.3.3 Circuit theoretical criteria for asymptotical stability 2.4 Communication and signal processing via synchronization of chaotic systems ; 2.5 Synchronization of nonautonomous systems ; 2.5.1 Unidirectional synchronization scheme for nonautonomous systems 2.5.2 Mutual coupling synchronization scheme for nonautonomous systems 2.5.3 Synchronization between different systems ; 2.5.4 Synchronizing nonautonomous systems as communication systems ; 2.6 Synchronization via a scalar signal 2.6.1 Applications of scalar synchronization to chaotic communication system 2.7 Adaptive synchronization ; 2.7.1 A general adaptive scheme ; 2.7.2 Two coupled nonlinear systems with linear parameters ; 2.7.3 Two coupled nonlinear systems with multiplicative parameters ; 2.7.4 Examples 2.7.5 A generalization of the scheme in Eq. (2.35) 2.7.6 Adaptive observers ; 2.8 Discrete-time systems ; 2.9 Further reading ; Chapter 3 Synchronization in Coupled Arrays of Chaotic Systems ; 3.1 Uniform linear static coupling ; 3.1.1 G is normal ; 3.1.2 G is symmetric 3.1.3 General G |
Record Nr. | UNINA-9910450896003321 |
Wu Chai Wah
![]() |
||
River Edge, N.J., : World Scientific, c2002 | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
|
Synchronization in coupled chaotic circuits and systems [[electronic resource] /] / Chai Wah Wu |
Autore | Wu Chai Wah |
Pubbl/distr/stampa | River Edge, N.J., : World Scientific, c2002 |
Descrizione fisica | 1 online resource (187 p.) |
Disciplina | 621.3815 |
Collana | World Scientific series on nonlinear science. Series A, Monographs and treatises |
Soggetto topico |
Electronic circuits
Chaotic behavior in systems Coupled mode theory |
ISBN | 981-277-842-X |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Contents ; Preface ; Chapter 1 Introduction ; Chapter 2 Synchronization in Two Coupled Chaotic Systems ; 2.1 Pecora-Carroll subsystem decomposition ; 2.2 Separable additive coupling ; 2.3 Synchronization and stability ; 2.3.1 Absolute stability ; 2.3.2 Lipschitz nonlinear systems
2.3.3 Circuit theoretical criteria for asymptotical stability 2.4 Communication and signal processing via synchronization of chaotic systems ; 2.5 Synchronization of nonautonomous systems ; 2.5.1 Unidirectional synchronization scheme for nonautonomous systems 2.5.2 Mutual coupling synchronization scheme for nonautonomous systems 2.5.3 Synchronization between different systems ; 2.5.4 Synchronizing nonautonomous systems as communication systems ; 2.6 Synchronization via a scalar signal 2.6.1 Applications of scalar synchronization to chaotic communication system 2.7 Adaptive synchronization ; 2.7.1 A general adaptive scheme ; 2.7.2 Two coupled nonlinear systems with linear parameters ; 2.7.3 Two coupled nonlinear systems with multiplicative parameters ; 2.7.4 Examples 2.7.5 A generalization of the scheme in Eq. (2.35) 2.7.6 Adaptive observers ; 2.8 Discrete-time systems ; 2.9 Further reading ; Chapter 3 Synchronization in Coupled Arrays of Chaotic Systems ; 3.1 Uniform linear static coupling ; 3.1.1 G is normal ; 3.1.2 G is symmetric 3.1.3 General G |
Record Nr. | UNINA-9910784722803321 |
Wu Chai Wah
![]() |
||
River Edge, N.J., : World Scientific, c2002 | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
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