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The partial element equivalent circuit method for electro-magnetic and circuit problems : a paradigm for EM modeling / / Albert E. Ruehli, Giulio Antonini, Lijun Jiang
| The partial element equivalent circuit method for electro-magnetic and circuit problems : a paradigm for EM modeling / / Albert E. Ruehli, Giulio Antonini, Lijun Jiang |
| Autore | Ruehli A. E (Albert E.), <1937-> |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : John Wiley & Sons, , 2016 |
| Descrizione fisica | 1 online resource (436 pages) |
| Disciplina | 621.301/51 |
| Collana | Wiley - IEEE |
| Soggetto topico |
Electric circuits - Mathematical models
Electromagnetism - Mathematical models |
| ISBN |
1-119-07840-7
1-119-07839-3 1-119-07838-5 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
-- DEDICATION xv -- PREFACE xvii -- ACKNOWLEDGEMENTS xxi -- ACRONYMS xxv -- 1 Introduction 1 -- References, 6 -- 2 Circuit Analysis for PEEC Methods 9 -- 2.1 Circuit Analysis Techniques, 9 -- 2.2 Overall Electromagnetic and Circuit Solver Structure, 9 -- 2.3 Circuit Laws, 11 -- 2.4 Frequency and Time Domain Analyses, 13 -- 2.5 Frequency Domain Analysis Formulation, 14 -- 2.6 Time Domain Analysis Formulations, 17 -- 2.7 General Modified Nodal Analysis (MNA), 22 -- 2.8 Including Frequency Dependent Models in Time Domain Solution, 28 -- 2.9 Including Frequency Domain Models in Circuit Solution, 31 -- 2.10 Recursive Convolution Solution, 39 -- 2.11 Circuit Models with Delays or Retardation, 41 -- Problems, 43 -- References, 44 -- 3 Maxwell's Equations 47 -- 3.1 Maxwell's Equations for PEEC Solutions, 47 -- 3.2 Auxiliary Potentials, 52 -- 3.3 Wave Equations and Their Solutions, 54 -- 3.4 Green's Function, 58 -- 3.5 Equivalence Principles, 60 -- 3.6 Numerical Solution of Integral Equations, 63 -- Problems, 65 -- References, 66 -- 4 Capacitance Computations 67 -- 4.1 Multiconductor Capacitance Concepts, 68 -- 4.2 Capacitance Models, 69 -- 4.3 Solution Techniques for Capacitance Problems, 74 -- 4.4 Meshing Related Accuracy Problems for PEEC Model, 79 -- 4.5 Representation of Capacitive Currents for PEEC Models, 82 -- Problems, 85 -- References, 86 -- 5 Inductance Computations 89 -- 5.1 Loop Inductance Computations, 90 -- 5.2 Inductance Computation Using a Solution or a Circuit Solver, 95 -- 5.3 Flux Loops for Partial Inductance, 95 -- 5.4 Inductances of Incomplete Structures, 96 -- 5.5 Computation of Partial Inductances, 99 -- 5.6 General Inductance Computations Using Partial Inductances and Open Loop Inductance, 107 -- 5.7 Difference Cell Pair Inductance Models, 109 -- 5.8 Partial Inductances with Frequency Domain Retardation, 119 -- Retardation, 123 -- Problems, 125 -- References, 131 -- 6 Building PEEC Models 133 -- 6.1 Resistive Circuit Elements for Manhattan-Type Geometries, 134.
6.2 Inductance / Resistance (Lp,R)PEEC Models, 136 -- 6.3 General (Lp,p,R)PEEC Model Development, 138 -- 6.4 Complete PEEC Model with Input and Output Connections, 148 -- 6.5 Time Domain Representation, 154 -- Problems, 154 -- References, 155 -- 7 Nonorthogonal PEEC Models 157 -- 7.1 Representation of Nonorthogonal Shapes, 158 -- 7.2 Specification of Nonorthogonal Partial Elements, 163 -- 7.3 Evaluation of Partial Elements for Nonorthogonal PEEC Circuits, 169 -- Problems, 181 -- References, 182 -- 8 Geometrical Description and Meshing 185 -- 8.1 General Aspects of PEEC Model Meshing Requirements, 186 -- 8.2 Outline of Some Meshing Techniques Available Today, 187 -- 8.3 SPICE Type Geometry Description, 194 -- 8.4 Detailed Properties of Meshing Algorithms, 196 -- 8.5 Automatic Generation of Geometrical Objects, 202 -- 8.6 Meshing of Some Three Dimensional Pre-determined Shapes, 205 -- 8.7 Approximations with Simplified Meshes, 207 -- 8.8 Mesh Generation Codes, 208 -- Problems, 209 -- References, 210 -- 9 Skin Effect Modeling 213 -- 9.1 Transmission Line Based Models, 214 -- 9.2 One Dimensional Current Flow Techniques, 215 -- 9.3 3D Volume Filament (VFI) Skin-Effect Model, 227 -- 9.4 Comparisons of Different Skin-Effect Models, 238 -- Problems, 244 -- References, 246 -- 10 PEEC Models for Dielectrics 249 -- 10.1 Electrical Models for Dielectric Materials, 249 -- 10.2 Circuit Oriented Models for Dispersive Dielectrics, 254 -- 10.3 Multi-Pole Debye Model, 257 -- 10.4 Including Dielectric Models in PEEC Solutions, 260 -- 10.5 Example for Impact of Dielectric Properties in the Time Domain, 276 -- Problems, 281 -- References, 281 -- 11 PEEC Models for Magnetic Material 285 -- 11.1 Inclusion of Problems with Magnetic Materials, 285 -- 11.2 Model for Magnetic Bodies by Using a Magnetic Scalar Potential and Magnetic Charge Formulation, 292 -- 11.3 PEEC Formulation Including Magnetic Bodies, 295 -- 11.4 Surface Models for Magnetic and Dielectric Material Solutions in PEEC, 300. Problems, 307 -- References, 308 -- 12 Incident and Radiated Field Models 309 -- 12.1 External Incident Field Applied to PEEC Model, 310 -- 12.2 Far-Field Radiation Models by Using Sensors, 312 -- 12.3 Direct Far-Field Radiation Computation, 318 -- Problems, 322 -- References, 322 -- 13 Stability and Passivity of PEEC Models 325 -- 13.1 Fundamental Stability and Passivity Concepts, 327 -- 13.2 Analysis of Properties of PEEC Circuits, 332 -- 13.3 Observability and Controllability of PEEC Circuits, 334 -- 13.4 Passivity Assessment of Solution, 337 -- 13.5 Solver Based Stability and Passivity Enhancement Techniques, 342 -- 13.6 Time Domain Solver Issues for Stability and Passivity, 359 -- Acknowledgment, 364 -- Problems, 364 -- References, 365 -- A Table of Units 369 -- A.1 Collection of Variables and Constants for Different Applications, 369 -- B Modified Nodal Analysis Stamps 373 -- B.1 Modified Nodal Analysis Matrix Stamps, 373 -- B.2 Controlled Source Stamps, 380 -- References, 382 -- C Computation of Partial Inductances 383 -- C.1 Partial Inductance Formulas for Orthogonal Geometries, 385 -- C.2 Partial inductance formulas for nonorthogonal geometries, 398 -- References, 407 -- D Computation of Partial Coefficients of Potential 409 -- D.1 Partial Potential Coefficients for Orthogonal Geometries, 410 -- D.2 Partial Potential Coefficient Formulas for Nonorthogonal Geometries, 418 -- References, 421 -- E Auxiliary Techniques for Partial Element Computations 423 -- E.1 Multi-function Partial Element Integration, 423 -- Subdivisions for Nonself-Partial Elements, 428 -- References, 429 -- INDEX 431. |
| Record Nr. | UNINA-9910270885403321 |
Ruehli A. E (Albert E.), <1937->
|
||
| Hoboken, New Jersey : , : John Wiley & Sons, , 2016 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
The partial element equivalent circuit method for electro-magnetic and circuit problems : a paradigm for EM modeling / / Albert E. Ruehli, Giulio Antonini, Lijun Jiang
| The partial element equivalent circuit method for electro-magnetic and circuit problems : a paradigm for EM modeling / / Albert E. Ruehli, Giulio Antonini, Lijun Jiang |
| Autore | Ruehli A. E (Albert E.), <1937-> |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : John Wiley & Sons, , 2016 |
| Descrizione fisica | 1 online resource (436 pages) |
| Disciplina | 621.301/51 |
| Collana | Wiley - IEEE |
| Soggetto topico |
Electric circuits - Mathematical models
Electromagnetism - Mathematical models |
| ISBN |
1-119-07840-7
1-119-07839-3 1-119-07838-5 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
-- DEDICATION xv -- PREFACE xvii -- ACKNOWLEDGEMENTS xxi -- ACRONYMS xxv -- 1 Introduction 1 -- References, 6 -- 2 Circuit Analysis for PEEC Methods 9 -- 2.1 Circuit Analysis Techniques, 9 -- 2.2 Overall Electromagnetic and Circuit Solver Structure, 9 -- 2.3 Circuit Laws, 11 -- 2.4 Frequency and Time Domain Analyses, 13 -- 2.5 Frequency Domain Analysis Formulation, 14 -- 2.6 Time Domain Analysis Formulations, 17 -- 2.7 General Modified Nodal Analysis (MNA), 22 -- 2.8 Including Frequency Dependent Models in Time Domain Solution, 28 -- 2.9 Including Frequency Domain Models in Circuit Solution, 31 -- 2.10 Recursive Convolution Solution, 39 -- 2.11 Circuit Models with Delays or Retardation, 41 -- Problems, 43 -- References, 44 -- 3 Maxwell's Equations 47 -- 3.1 Maxwell's Equations for PEEC Solutions, 47 -- 3.2 Auxiliary Potentials, 52 -- 3.3 Wave Equations and Their Solutions, 54 -- 3.4 Green's Function, 58 -- 3.5 Equivalence Principles, 60 -- 3.6 Numerical Solution of Integral Equations, 63 -- Problems, 65 -- References, 66 -- 4 Capacitance Computations 67 -- 4.1 Multiconductor Capacitance Concepts, 68 -- 4.2 Capacitance Models, 69 -- 4.3 Solution Techniques for Capacitance Problems, 74 -- 4.4 Meshing Related Accuracy Problems for PEEC Model, 79 -- 4.5 Representation of Capacitive Currents for PEEC Models, 82 -- Problems, 85 -- References, 86 -- 5 Inductance Computations 89 -- 5.1 Loop Inductance Computations, 90 -- 5.2 Inductance Computation Using a Solution or a Circuit Solver, 95 -- 5.3 Flux Loops for Partial Inductance, 95 -- 5.4 Inductances of Incomplete Structures, 96 -- 5.5 Computation of Partial Inductances, 99 -- 5.6 General Inductance Computations Using Partial Inductances and Open Loop Inductance, 107 -- 5.7 Difference Cell Pair Inductance Models, 109 -- 5.8 Partial Inductances with Frequency Domain Retardation, 119 -- Retardation, 123 -- Problems, 125 -- References, 131 -- 6 Building PEEC Models 133 -- 6.1 Resistive Circuit Elements for Manhattan-Type Geometries, 134.
6.2 Inductance / Resistance (Lp,R)PEEC Models, 136 -- 6.3 General (Lp,p,R)PEEC Model Development, 138 -- 6.4 Complete PEEC Model with Input and Output Connections, 148 -- 6.5 Time Domain Representation, 154 -- Problems, 154 -- References, 155 -- 7 Nonorthogonal PEEC Models 157 -- 7.1 Representation of Nonorthogonal Shapes, 158 -- 7.2 Specification of Nonorthogonal Partial Elements, 163 -- 7.3 Evaluation of Partial Elements for Nonorthogonal PEEC Circuits, 169 -- Problems, 181 -- References, 182 -- 8 Geometrical Description and Meshing 185 -- 8.1 General Aspects of PEEC Model Meshing Requirements, 186 -- 8.2 Outline of Some Meshing Techniques Available Today, 187 -- 8.3 SPICE Type Geometry Description, 194 -- 8.4 Detailed Properties of Meshing Algorithms, 196 -- 8.5 Automatic Generation of Geometrical Objects, 202 -- 8.6 Meshing of Some Three Dimensional Pre-determined Shapes, 205 -- 8.7 Approximations with Simplified Meshes, 207 -- 8.8 Mesh Generation Codes, 208 -- Problems, 209 -- References, 210 -- 9 Skin Effect Modeling 213 -- 9.1 Transmission Line Based Models, 214 -- 9.2 One Dimensional Current Flow Techniques, 215 -- 9.3 3D Volume Filament (VFI) Skin-Effect Model, 227 -- 9.4 Comparisons of Different Skin-Effect Models, 238 -- Problems, 244 -- References, 246 -- 10 PEEC Models for Dielectrics 249 -- 10.1 Electrical Models for Dielectric Materials, 249 -- 10.2 Circuit Oriented Models for Dispersive Dielectrics, 254 -- 10.3 Multi-Pole Debye Model, 257 -- 10.4 Including Dielectric Models in PEEC Solutions, 260 -- 10.5 Example for Impact of Dielectric Properties in the Time Domain, 276 -- Problems, 281 -- References, 281 -- 11 PEEC Models for Magnetic Material 285 -- 11.1 Inclusion of Problems with Magnetic Materials, 285 -- 11.2 Model for Magnetic Bodies by Using a Magnetic Scalar Potential and Magnetic Charge Formulation, 292 -- 11.3 PEEC Formulation Including Magnetic Bodies, 295 -- 11.4 Surface Models for Magnetic and Dielectric Material Solutions in PEEC, 300. Problems, 307 -- References, 308 -- 12 Incident and Radiated Field Models 309 -- 12.1 External Incident Field Applied to PEEC Model, 310 -- 12.2 Far-Field Radiation Models by Using Sensors, 312 -- 12.3 Direct Far-Field Radiation Computation, 318 -- Problems, 322 -- References, 322 -- 13 Stability and Passivity of PEEC Models 325 -- 13.1 Fundamental Stability and Passivity Concepts, 327 -- 13.2 Analysis of Properties of PEEC Circuits, 332 -- 13.3 Observability and Controllability of PEEC Circuits, 334 -- 13.4 Passivity Assessment of Solution, 337 -- 13.5 Solver Based Stability and Passivity Enhancement Techniques, 342 -- 13.6 Time Domain Solver Issues for Stability and Passivity, 359 -- Acknowledgment, 364 -- Problems, 364 -- References, 365 -- A Table of Units 369 -- A.1 Collection of Variables and Constants for Different Applications, 369 -- B Modified Nodal Analysis Stamps 373 -- B.1 Modified Nodal Analysis Matrix Stamps, 373 -- B.2 Controlled Source Stamps, 380 -- References, 382 -- C Computation of Partial Inductances 383 -- C.1 Partial Inductance Formulas for Orthogonal Geometries, 385 -- C.2 Partial inductance formulas for nonorthogonal geometries, 398 -- References, 407 -- D Computation of Partial Coefficients of Potential 409 -- D.1 Partial Potential Coefficients for Orthogonal Geometries, 410 -- D.2 Partial Potential Coefficient Formulas for Nonorthogonal Geometries, 418 -- References, 421 -- E Auxiliary Techniques for Partial Element Computations 423 -- E.1 Multi-function Partial Element Integration, 423 -- Subdivisions for Nonself-Partial Elements, 428 -- References, 429 -- INDEX 431. |
| Record Nr. | UNINA-9910813795003321 |
|
Ruehli A. E (Albert E.), <1937->
|
||
| Hoboken, New Jersey : , : John Wiley & Sons, , 2016 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||