Electricity, electromagnetism and magnetism Books

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Book SynopsisCombining theoretical methods from quantum optics and solid-state physics, this book gives researchers and graduate students a new level of understanding of semiconductor quantum optics. Nearly 300 exercises help readers learn the techniques involved. Online resources include further discussions on topical issues, latest trends and publications on the field.Trade Review'… an excellent reference text and their model will surely serve as a solid platform for future work.' Chemistry World (rsc.org/chemistryworld)'The text is very clearly written. Many of the formulas are explained step by step [and] there are numerous exercises and recommendations for further reading at the end of most chapters. It is a useful tool for all those working in the quantum optics area of research.' Daniela Dragoman, Optics and Photonics News (osa-opn.org)Table of Contents1. Central concepts in classical mechanics; 2. Central concepts of classical electrodynamics; 3. Central concepts in quantum mechanics; 4. Central concepts in stationary quantum theory; 5. Central concepts in measurement theory; 6. Wigner's phase-space representation; 7. Hamiltonian formulation of classical electrodynamics; 8. System Hamiltonian of classical electrodynamics; 9. System Hamiltonian in the generalized Coulomb gauge; 10. Quantization of light and matter; 11. Quasiparticles in semiconductors; 12. Band structure of solids; 13. Interactions in semiconductors; 14. Generic quantum dynamics; 15. Cluster-expansion representation of the quantum dynamics; 16. Simple many-body systems; 17. Hierarchy problem for dipole systems; 18. Two-level approximation for optical transition; 19. Self-consistent extension of the two-level approach; 20. Dissipative extension of the two-level approach; 21. Quantum-optical extension of the two-level approach; 22. Quantum dynamics of two-level system; 23. Spectroscopy and quantum-optical correlations; 24. General aspects of semiconductor optics; 25. Introductory semiconductor optics; 26. Maxwell-semiconductor Bloch equations; 27. Coherent vs. incoherent excitons; 28. Semiconductor luminescence equations; 29. Many-body aspects of the semiconductor luminescence; 30. Advanced semiconductor quantum optics; Appendix; Index.

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Book SynopsisJames Clerk Maxwell's influential contribution to nineteenth-century physics brought together the experimental and theoretical advances in the field of electricity and magnetism known at the time. Published in 1873, it contains Maxwell's famous equations on electromagnetic theory. Volume 2 covers magnetism and electromagnetism, including the electromagnetic theory of light.Table of ContentsPart III. Magnetism: 1. Elementary theory of magnetism; 2. Magnetic force and magnetic induction; 3. Particular forms of magnets; 4. Induced magnetization; 5. Magnetic problems; 6. Weber's theory of magnetic induction; 7. Magnetic measurements; 8. Terrestrial magnetism; Part IV. Electromagnetism: 1. Electromagnetic force; 2. Mutual action of electric currents; 3. Induction of electric currents; 4. Induction of a current on itself; 5. General equations of dynamics; 6. Application of dynamics to electromagnetism; 7. Electrokinetics; 8. Exploration of the field by means of the secondary circuit; 9. General equations; 10. Dimensions of electric units; 11. Energy and stress; 12. Current-sheets; 13. Parallel currents; 14. Circular currents; 15. Electromagnetic instruments; 16. Electromagnetic observations; 17. Electrical measurement of coefficients of induction; 18. Determination of resistance in electromagnetic measure; 19. Comparison of electrostatic with electromagnetic units; 20. Electromagnetic theory of light; 21. Magnetic action on light; 22. Electric theory of magnetism; 23. Theories of action at a distance; Index.

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Book SynopsisOliver Heaviside FRS (18501925) was a brilliant self-taught electrical engineer, physicist and mathematician. Published in 1893, this is the last of three volumes that summarise his work in electromagnetic theory. It reviews his work on waves from moving sources, and compares vector analysis with quaternions.Table of Contents9. Waves from moving sources; 10. Waves in the ether.

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Book SynopsisIn order to make the most important works in the field accessible to practising engineers, Sir Francis Ronalds (17881873) donated a vast collection of books, essays and pamphlets to the Society of Telegraph Engineers. This book, first published in 1880, is a catalogue of more than 13,000 titles.Table of ContentsPreface; Biographical memoir of Sir Francis Ronalds, FRS; The Ronalds catalogue.

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Book SynopsisThis 1769 work brings together published and unpublished letters both from and to Benjamin Franklin, which demonstrate the range of his interests. The letters show a lively transatlantic group of scientific friends and colleagues describing their experiments, interpreting each others' results, and theorizing on all aspects of the natural world.Table of ContentsAdvertisement concerning this fourth edition; Preface to the first edition; Letters I-V; Additional papers, 1749; Letters VI-XIII; Remarks on the Abbe Nollet's letters on electricity, by Mr David Colden of New-York; Electrical experiments together with some observations on thunder-clouds, in further confirmation of Mr Franklin's observations on the positive and negative electrical state of the clouds, by John Canton, M.A. and F.R.S.; Electrical and other philosophical papers and letters; Letters XIV-XXIII; Accounts of water-spouts; An account of the new-invented Pensylvanian fire-places; Letters XXIV-LXI; Index.

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Book SynopsisA modern presentation of integral methods in low-frequency electromagnetics This book provides state-of-the-art knowledge on integral methods in low-frequency electromagnetics. Blending theory with numerous examples, it introduces key aspects of the integral methods used in engineering as a powerful alternative to PDE-based models. Readers will get complete coverage of: The electromagnetic field and its basic characteristics An overview of solution methods Solutions of electromagnetic fields by integral expressions Integral and integrodifferential methods Indirect solutions of electromagnetic fields by the boundary element method Integral equations in the solution of selected coupled problems Numerical methods for integral equations All computations presented in the book are done by means of the authors'' own codes, and a significantTable of ContentsList of Figures. List of Tables. Preface. Acknowledgments. 1 Electromagnetic Field and their Basic Characteristics. 1.1 Fundamentals. 1.2 Potentials. 1.3 Mathematical models of electromagnetic fields. 1.4 Energy and forces in electromagnetic fields. 1.5 Power balance in electromagnetic fields. 2 Overview of Solution Methods. 2.1 Continuous models in electromagnetism. 2.2 Methods of solution of the continuous models. 2.3 Classification of the analytical methods. 2.4 Numerical methods and their classification. 2.5 Differential methods. 2.6 Finite element method. 2.7 Integral and integrodifferential methods. 2.8 Important mathematical aspects of numerical methods. 2.9 Numerical schemes for parabolic equations. 3 Solution of Electromagnetic Fields by Integral Expressions. 3.1 Introduction. 3.2 1D integration area. 3.3 2D integration area. 3.4 Forces acting in the system of long massive conductors. 3.5 3D integration area. 4 Integral and Integrodifferential Methods. 4.1 Integral versus differential models. 4.2 Theoretical foundations. 4.3 Static and harmonic problems in one dimension. 4.4 Static and harmonic problems in two dimensions. 4.5 Static problems in three dimensions. 4.6 Time-dependent eddy current problems in one dimension and two dimensions. 4.7 Static and 2D eddy current problems with motion. 5 Indirect Solution of Electromagnetic Fields by the Boundary Element Method. 5.1 Introduction. 5.2 BEM-based solution of differential equations. 5.3 Problems with 1D integration area. 6 Integral Equations in Solution of Selected Coupled Problems. 6.1 Continual induction heating of nonferrous cylindrical bodies. 6.2 Induction heating of a long nonmagnetic cylindrical billet rotating in uniform magnetic field. 6.3 Pulsed Induction Accelerator. 7 Numerical Methods for Integral Equations. 7.1 Introduction. 7.2 Collocation methods. 7.3 Galerkin methods. 7.4 Numerical example. Appendix A: Basic Mathematical Tools. A.1 Vectors, matrices, systems of linear equations. A.2 Vector analysis. Appendix B: Special Functions. B.1 Bessel functions. B.2 Elliptic integrals. B.3 Special polynomials. Appendix C: Integration Techniques. C.1 Analytical calculations of some integrals over typical elements. C.2 Techniques of numerical integration. References. Topic Index.

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Book Synopsis

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Book Synopsis

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Book Synopsis

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Book SynopsisWritten by specialists of modeling in electromagnetism, this book provides a comprehensive review of the finite element method for low frequency applications. Fundamentals of the method as well as new advances in the field are described in detail. Chapters 1 to 4 present general 2D and 3D static and dynamic formulations by the use of scalar and vector unknowns and adapted interpolations for the fields (nodal, edge, face or volume). Chapter 5 is dedicated to the presentation of different macroscopic behavior laws of materials and their implementation in a finite element context: anisotropy and hysteretic properties for magnetic sheets, iron losses, non-linear permanent magnets and superconductors. More specific formulations are then proposed: the modeling of thin regions when finite elements become misfit (Chapter 6), infinite domains by using geometrical transformations (Chapter 7), the coupling of 2D and 3D formulations with circuit equations (Chapter 8), taking into account the movement, particularly in the presence of Eddy currents (Chapter 9) and an original approach for the treatment of geometrical symmetries when the sources are not symmetric (Chapter 10). Chapters 11 to 13 are devoted to coupled problems: magneto-thermal coupling for induction heating, magneto-mechanical coupling by introducing the notion of strong and weak coupling and magneto-hydrodynamical coupling focusing on electromagnetic instabilities in fluid conductors. Chapter 14 presents different meshing methods in the context of electromagnetism (presence of air) and introduces self-adaptive mesh refinement procedures. Optimization techniques are then covered in Chapter 15, with the adaptation of deterministic and probabilistic methods to the numerical finite element environment. Chapter 16 presents a variational approach of electromagnetism, showing how Maxwell equations are derived from thermodynamic principles.Table of ContentsChapter 1. Introduction to Nodal Finite Elements. 1 Jean-Louis COULOMB 1.1. Introduction 1 1.1.1. The finite element method 1 1.2. The 1D finite element method 2 1.2.1. A simple electrostatics problem 2 1.2.2. Differential approach 3 1.2.3. Variational approach 4 1.2.4. First-order finite elements 6 1.2.5. Second-order finite elements 9 1.3. The finite element method in two dimensions 10 1.3.1. The problem of the condenser with square section 10 1.3.2. Differential approach 12 1.3.3. Variational approach 14 1.3.4. Meshing in first-order triangular finite elements 15 1.3.5. Finite element interpolation 17 1.3.6. Construction of the system of equations by the Ritz method 19 1.3.7. Calculation of the matrix coefficients 21 1.3.8. Analysis of the results 25 1.3.9. Dual formations, framing and convergence 42 1.3.10. Resolution of the nonlinear problems 44 1.3.11. Alternative to the variational method: the weighted residues method 45 1.4. The reference elements 47 1.4.1. Linear reference elements 48 1.4.2. Surface reference elements 49 1.4.3. Volume reference elements 52 1.4.4. Properties of the shape functions 53 1.4.5. Transformation from reference coordinates to domain coordinates 54 1.4.6. Approximation of the physical variable 56 1.4.7. Numerical integrations on the reference elements 60 1.4.8. Local Jacobian derivative method 63 1.5. Conclusion 66 1.6. References 66 Chapter 2. Static Formulations: Electrostatic, Electrokinetic, Magnetostatics 69 Patrick DULAR and Francis PIRIOU 2.1. Problems to solve 70 2.1.1. Maxwell’s equations 70 2.1.2. Behavior laws of materials 71 2.1.3. Boundary conditions 71 2.1.4. Complete static models 74 2.1.5. The formulations in potentials 75 2.2. Function spaces in the fields and weak formulations 82 2.2.1. Integral expressions: introduction 82 2.2.2. Definitions of function spaces 82 2.2.3. Tonti diagram: synthesis scheme of a problem 84 2.2.4. Weak formulations 86 2.3. Discretization of function spaces and weak formulations 91 2.3.1. Finite elements 91 2.3.2. Sequence of discrete spaces 93 2.3.3. Gauge conditions and source terms in discrete spaces 106 2.3.4. Weak discrete formulations 109 2.3.5. Expression of global variables 114 2.4. References 115 Chapter 3. Magnetodynamic Formulations 117 Zhuoxiang REN and Frédéric BOUILLAULT 3.1. Introduction 117 3.2. Electric formulations 119 3.2.1. Formulation in electric field 119 3.2.2. Formulation in combined potentials a - 120 3.2.3. Comparison of the formulations in field and in combined potentials 121 3.3. Magnetic formulations 123 3.3.1. Formulation in magnetic field 123 3.3.2. Formulation in combined potentials t - ɸ 124 3.3.3. Numerical example 125 3.4. Hybrid formulation 127 3.5. Electric and magnetic formulation complementarities 128 3.5.1. Complementary features 128 3.5.2. Concerning the energy bounds 129 3.5.3. Numerical example 129 3.6. Conclusion 133 3.7. References 134 Chapter 4. Mixed Finite Element Methods in Electromagnetism 139 Bernard BANDELIER and Françoise RIOUX-DAMIDAU 4.1. Introduction 139 4.2. Mixed formulations in magnetostatics 140 4.2.1. Magnetic induction oriented formulation 141 4.2.2. Formulation oriented magnetic field 144 4.2.3. Formulation in induction and field 146 4.2.4. Alternate case 147 4.3. Energy approach: minimization problems, searching for a saddle-point 147 4.3.1. Minimization of a functional calculus related to energy 147 4.3.2. Variational principle of magnetic energy 149 4.3.3. Searching for a saddle-point 151 4.3.4. Functional calculus related to the constitutive relationship 154 4.4. Hybrid formulations 154 4.4.1. Magnetic induction oriented hybrid formulation 154 4.4.2. Hybrid formulation oriented magnetic field 156 4.4.3. Mixed hybrid method 157 4.5. Compatibility of approximation spaces – inf-sup condition 157 4.5.1. Mixed magnetic induction oriented formulation 158 4.5.2. Mixed formulation oriented magnetic field 160 4.5.3. General case 160 4.6. Mixed finite elements, Whitney elements 161 4.6.1. Magnetic induction oriented formulation 162 4.6.2. Magnetic field oriented formulation 163 4.7. Mixed formulations in magnetodynamics 164 4.7.1. Magnetic field oriented formulation 164 4.7.2. Formulation oriented electric field 167 4.8. Solving techniques 167 4.8.1. Penalization methods 168 4.8.2. Algorithm using the Schur complement 171 4.9. References 174 Chapter 5. Behavior Laws of Materials 177 Frédéric BOUILLAULT, Afef KEDOUS-LEBOUC, Gérard MEUNIER, Florence OSSART and Francis PIRIOU 5.1. Introduction 177 5.2. Behavior law of ferromagnetic materials 178 5.2.1. Definitions 178 5.2.2. Hysteresis and anisotropy 179 5.2.3. Classificiation of models dealing with the behavior law 180 5.3. Implementation of nonlinear behavior models 183 5.3.1. Newton method 183 5.3.2. Fixed point method 187 5.3.3. Particular case of a behavior with hysteresis 191 5.4. Modeling of magnetic sheets 192 5.4.1. Some words about magnetic sheets 192 5.4.2. Example of stress in the electric machines 192 5.4.3. Anisotropy of sheets with oriented grains 194 5.4.4. Hysteresis and dynamic behavior under uniaxial stress 200 5.4.5. Determination of iron losses in electric machines: nonlinear isotropic finite element modeling and calculation of the losses a posteriori 209 5.4.6. Conclusion 215 5.5. Modeling of permanent magnets 216 5.5.1. Introduction. 216 5.5.2. Magnets obtained by powder metallurgy 216 5.5.3. Study of linear anisotropic behavior 218 5.5.4. Study of nonlinear behavior 220 5.5.5. Implementation of the model in finite element software 223 5.5.6. Validation: the experiment by Joel Chavanne 224 5.5.7. Conductive magnet subjected to an AC field 225 5.6. Modeling of superconductors 226 5.6.1. Introduction 226 5.6.2. Behavior of superconductors 227 5.6.3. Modeling of electric behavior of superconductors 230 5.6.4. Particular case of the Bean model 232 5.6.5. Examples of modeling 237 5.7. Conclusion 240 5.8. References 241 Chapter 6. Modeling on Thin and Line Regions 245 Christophe GUÉRIN 6.1. Introduction 245 6.2. Different special elements and their interest 245 6.3. Method for taking into account thin regions without potential jump 249 6.4. Method for taking into account thin regions with potential jump 250 6.4.1. Analytical integration method 251 6.4.2. Numerical integration method 252 6.5. Method for taking thin regions into account 255 6.6. Thin and line regions in magnetostatics 256 6.6.1. Thin and line regions in magnetic scalar potential formulations 256 6.6.2. Thin and line regions in magnetic vector potential formulations 257 6.7. Thin and line regions in magnetoharmonics 257 6.7.1. Solid conducting regions presenting a strong skin effect 258 6.7.2. Thin conducting regions 265 6.8. Thin regions in electrostatic problems: “electric harmonic problems” and electric conduction problems 272 6.9. Thin thermal regions 272 6.10. References 273 Chapter 7. Coupling with Circuit Equations 277 Gérard MEUNIER, Yvan LEFEVRE, Patrick LOMBARD and Yann LE FLOCH 7.1. Introduction 277 7.2. Review of the various methods of setting up electric circuit equations 278 7.2.1. Circuit equations with nodal potentials 278 7.2.2. Circuit equations with mesh currents 279 7.2.3. Circuit equations with time integrated nodal potentials 280 7.2.4. Formulation of circuit equations in the form of state equations 281 7.2.5. Conclusion on the methods of setting up electric equations 283 7.3. Different types of coupling 284 7.3.1. Indirect coupling 285 7.3.2. Integro-differential formulation 285 7.3.3. Simultaneous resolution 285 7.3.4. Conclusion 285 7.4. Establishment of the “current-voltage” relations 286 7.4.1. Insulated massive conductor with two ends: basic assumptions and preliminary relations 286 7.4.2. Current-voltage relations using the magnetic vector potential 287 7.4.3. Current-voltage relations using magnetic induction 288 7.4.4. Wound conductors 290 7.4.5. Losses in the wound conductors 291 7.5. Establishment of the coupled field and circuit equations 292 7.5.1. Coupling with a vector potential formulation in 2D 292 7.5.2. Coupling with a vector potential formulation in 3D 303 7.5.3. Coupling with a scalar potential formulation in 3D 310 7.6. General conclusion 317 7.7. References 318 Chapter 8. Modeling of Motion: Accounting for Movement in the Modeling of Magnetic Phenomena 321 Vincent LECONTE 8.1. Introduction 321 8.2. Formulation of an electromagnetic problem with motion 322 8.2.1. Definition of motion 322 8.2.2. Maxwell equations and motion 325 8.2.3. Formulations in potentials 329 8.2.4. Eulerian approach 335 8.2.5. Lagrangian approach 338 8.2.6. Example application 342 8.3. Methods for taking the movement into account 346 8.3.1. Introduction. 346 8.3.2. Methods for rotating machines 346 8.3.3. Coupling methods without meshing and with the finite element method 348 8.3.4. Coupling of boundary integrals with the finite element method 350 8.3.5. Automatic remeshing methods for large distortions 355 8.4. Conclusion 362 8.5. References 363 Chapter 9. Symmetric Components and Numerical Modeling 369 Jacques LOBRY, Eric NENS and Christian BROCHE 9.1. Introduction 369 9.2. Representation of group theory 371 9.2.1. Finite groups 371 9.2.2. Symmetric functions and irreducible representations 374 9.2.3. Orthogonal decomposition of a function 378 9.2.4. Symmetries and vector fields 379 9.3. Poisson’s problem and geometric symmetries 384 9.3.1. Differential and integral formulations 384 9.3.2. Numerical processing 387 9.4. Applications 388 9.4.1. 2D magnetostatics 388 9.4.2. 3D magnetodynamics 394 9.5. Conclusions and future work 403 9.6. References 404 Chapter 10. Magneto-thermal Coupling 405 Mouloud FÉLIACHI and Javad FOULADGAR 10.1. Introduction 405 10.2. Magneto-thermal phenomena and fundamental equations 406 10.2.1. Electromagentism 406 10.2.2. Thermal 408 10.2.3. Flow 408 10.3. Behavior laws and couplings 409 10.3.1. Electrmagnetic phenomena 409 10.3.2. Thermal phenomena 409 10.3.3. Flow phenomena 409 10.4. Resolution methods 409 10.4.1. Numerical methods 409 10.4.2. Semi-analytical methods 410 10.4.3. Analytical-numerical methods 411 10.4.4. Magneto-thermal coupling models 411 10.5. Heating of a moving work piece 413 10.6. Induction plasma 417 10.6.1. Introduction 417 10.6.2. Inductive plasma installation 418 10.6.3. Mathematical models 418 10.6.4. Results 426 10.6.5. Conclusion 427 10.7. References 428 Chapter 11. Magneto-mechanical Modeling 431 Yvan LEFEVRE and Gilbert REYNE 11.1. Introduction 431 11.2. Modeling of coupled magneto-mechancial phenomena 432 11.2.1. Modeling of mechanical structure 433 11.2.2. Coupled magneto-mechanical modeling 437 11.2.3. Conclusion 442 11.3. Numerical modeling of electromechancial conversion in conventional actuators 442 11.3.1. General simulation procedure 443 11.3.2. Global magnetic force calculation method 444 11.3.3. Conclusion 447 11.4. Numerical modeling of electromagnetic vibrations 447 11.4.1. Magnetostriction vs. magnetic forces 447 11.4.2. Procedure for simulating vibrations of magnetic origin 449 11.4.3. Magnetic forces density 449 11.4.4. Case of rotating machine teeth 452 11.4.5. Magnetic response modeling 453 11.4.6. Model superposition method 455 11.4.7. Conclusion 458 11.5. Modeling strongly coupled phenomena 459 11.5.1. Weak coupling and strong coupling from a physical viewpoint 459 11.5.2. Weak coupling or strong coupling problem from a numerical modeling analysis 460 11.5.3. Weak coupling and intelligent use of software tools 461 11.5.4. Displacement and deformation of a magnetic system 463 11.5.5. Structural modeling based on magnetostrictive materials 465 11.5.6. Electromagnetic induction launchers 469 11.6. Conclusion 470 11.7. References 471 Chapter 12. Magnetohydrodynamics: Modeling of a Kinematic Dynamo 477 Franck PLUNIAN and Philippe MASSÉ 12.1. Introduction 477 12.1.1. Generalities 477 12.1.2. Maxwell’s equations and Ohm’s law 481 12.1.3. The induction equation 482 12.1.4. The dimensionless equation 483 12.2. Modeling the induction equation using finite elements 485 12.2.1. Potential (A,ɸ) quadric-vector formulation 485 12.2.2. 2D1/2 quadri-vector potential formulation 488 12.3. Some simulation examples 491 12.3.1. Screw dynamo (Ponomarenko dynamo) 491 12.3.2. Two-scale dynamo without walls (Roberts dynamo) 495 12.3.3. Two-scale dynamo with walls 498 12.3.4. A dynamo at the industrial scale 502 12.4. Modeling of the dynamic problem 503 12.5. References 504 Chapter 13. Mesh Generation 509 Yves DU TERRAIL COUVAT, François-Xavier ZGAINSKI and Yves MARÉCHAL 13.1. Introduction 509 13.2. General definition 510 13.3. A short history 512 13.4. Mesh algorithms 512 13.4.1. The basic algorithms 512 13.4.2. General mesh algorithms 518 13.5. Mesh regularization 526 13.5.1. Regularization by displacement of nodes 526 13.5.2. Regularization by bubbles 528 13.5.3. Adaptation of nodes population 530 13.5.4. Insertion in meshing algorithms 530 13.5.5. Value of bubble regularization 531 13.6. Mesh processer and modeling environment 533 13.6.1. Some typical criteria 533 13.6.2. Electromagnetism and meshing constraints 534 13.7. Conclusion 541 13.8. References 541 Chapter 14. Optimization 547 Jean-Louis COULOMB 14.1. Introduction 547 14.1.1. Optimization: who, why, how? 547 14.1.2. Optimization by numerical simulation: is this reasonable? 548 14.1.3. Optimization by numerical simulation: difficulties 549 14.1.4. Numerical design of experiments (DOE) method: an elegant solution 549 14.1.5. Sensitivity analysis: an “added value” accessible by simulation 550 14.1.6. Organization of this chapter 551 14.2. Optimization methods 551 14.2.1. Optimization problems: some definitions 551 14.2.2. Optimization problems without constraints 553 14.2.3. Constrained optimization problems 559 14.2.4. Multi-objective optimization 560 14.3. Design of experiments (DOE) method 562 14.3.1. The direct control of the simulation tool by an optimization algorithm: principle and disadvantages 562 14.3.2. The response surface: an approximation enabling indirect optimization 563 14.3.3. DOE method: a short history 565 14.3.4. DOE method: a simple example 565 14.4. Response surfaces 572 14.4.1. Basic principles 572 14.4.2. Polynomial surfaces of degree 1 without interaction: simple but sometimes useful 573 14.4.3. Polynomial surfaces of degree 1 with interactions: quite useful for screening 573 14.4.4. Polynomial surfaces of degree 2: a first approach for nonlinearities 574 14.4.5. Response surfaces of degrees 1 and 2: interests and limits 576 14.4.6. Response surfaces by combination of radial functions 576 14.4.7. Response surfaces using diffuse elements 577 14.4.8. Adaptive response surfaces 579 14.5. Sensitivity analysis 579 14.5.1. Finite difference method 579 14.5.2. Method for local derivation of the Jacobian matrix 580 14.5.3. Steadiness of state variables: steadiness of state equations 581 14.5.4. Sensitivity of the objective function: the adjoint state method 583 14.5.5. Higher order derivative 583 14.6. A complete example of optimization 584 14.6.1. The problem of optimization 584 14.6.2. Determination of the influential parameters by the DOE method 585 14.6.3. Approximation of the objective function by a response surface 587 14.6.4. Search for the optimum on the response surface 587 14.6.5. Verification of the solution by simulation 587 14.7. Conclusion 588 14.8. References 588 List of Authors 595 Index 599

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Book SynopsisThis book concerns the analysis and design of induction heating of poor electrical conduction materials. Some innovating applications such as inductive plasma installation or transformers, thermo inductive non-destructive testing and carbon-reinforced composite materials heating are studied. Analytical, semi-analytical and numerical models are combined to obtain the best modeling technique for each case. Each model has been tested with experimental results and validated. The principal aspects of a computational package to solve these kinds of coupled problems are described. In the first chapter, the mathematical tools for coupled electromagnetic and thermal phenomena are introduced. In Chapter 2, these tools are used to analyze a radio frequency inductive plasma installation. The third chapter describes the methodology of designing a low frequency plasma transformer. Chapter 4 studies the feasibility of the thermo inductive technique for non-destructive testing and the final chapter is dedicated to the use of induction heating in the lifecycle of carbon-reinforced composite materials. Contents 1. Thermal and Electromagnetic Coupling, Javad Fouladgar, Didier Trichet and Brahim Ramdane.2. Simplified Model of a Radiofrequency Inductive Thermal Plasma Installation, Javad Fouladgar and Jean-Pierre Ploteau.3. Design Methodology of A Very Low-Frequency Plasma Transformer, Javad Fouladgar and Souri Mohamed Mimoune.4. Non Destructive Testing by Thermo-Inductive Method, Javad Fouladgar, Brahim Ramdane, Didier Trichet and Tayeb Saidi.5. Induction Heating of Composite Materials, Javad Fouladgar, Didier Trichet, Samir Bensaid and Guillaume WasselynckTable of ContentsIntroduction xiii Javad FOULADGAR Chapter 1. Thermal and Electromagnetic Coupling 1 Javad FOULADGAR, Didier TRICHET and Brahim RAMDANE 1.1. Introduction 1 1.2. Electromagnetic problem 2 1.3. Thermal problem 15 1.4. Magnetothermal coupling 16 1.5. Solving the electromagnetic and thermal equations 18 1.6. Conclusion 35 1.7. Bibliography 36 Chapter 2. Simplified Model of a Radiofrequency Inductive Thermal Plasma Installation 39 Javad FOULADGAR and Jean-Pierre PLOTEAU 2.1. Introduction 39 2.2. Plasma and its characteristics 40 2.3. Modeling a plasma installation 49 2.4. Calculating charge impedance 57 2.5. Generator model 64 2.6. Conclusion 80 2.7. Bibliography 81 Chapter 3. Design Methodology of A Very Low-Frequency Plasma Transformer 85 Javad FOULADGAR and Souri Mohamed MIMOUNE 3.1. Introduction 85 3.2. Different types of very low-frequency applicators 87 3.3. Simplified analytical model for analysis and preliminary design 88 3.4. Nonlinear model 97 3.5. Plasma stability in the transitory and sinusoidal states 100 3.6. Advanced inductive plasma transformer model 103 3.7. Plasma initialization 111 3.8. Conclusion 114 3.9. Bibliography 114 Chapter 4. Non Destructive Testing by Thermo-Inductive Method 117 Javad FOULADGAR, Brahim RAMDANE, Didier TRICHET and Tayeb SAIDI 4.1. Introduction 117 4.2. Principles of the thermo-inductive method 119 4.3. Basic thermo-inductive technique theory 126 4.4. Application of the thermo-inductive method to inspect massive magnetic steel components 145 4.5. Comparison with infrared thermography 164 4.6. Applications on composite materials 168 4.7. Conclusion and general instructions 185 4.8. Bibliography 190 Chapter 5. Induction Heating of Composite Materials 195 Javad FOULADGAR, Didier TRICHET, Samir BENSAID and Guillaume WASSELYNCK 5.1. Introduction 195 5.2. Composite materials 197 5.3. Lifecycle of composite materials 202 5.4. Induction and the lifecycle of composite materials 203 5.5. Identifying the physical properties of composite materials by experimental methods 207 5.6. Homogenization techniques 224 5.7. Heating composite materials by induction 251 5.8. Setup model 253 5.9. Influence of the folds’ orientation 260 5.10. Difficulty of the electrothermal coupling 262 5.11. Validating the electrothermal model 262 5.12. Conclusion 267 5.13. Bibliography 268 List of Authors 273 Index 275

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Book SynopsisDedicated to a complete presentation on all aspects of reverberation chambers, this book provides the physical principles behind these test systems in a very progressive manner. The detailed panorama of parameters governing the operation of electromagnetic reverberation chambers details various applications such as radiated immunity, emissivity, and shielding efficiency experiments. In addition, the reader is provided with the elements of electromagnetic theory and statistics required to take full advantage of the basic operational rules of reverberation chambers, including calibration procedures. Comparisons with other testing systems (TEM cells, anechoic chambers) are also discussed.Trade Review"The book is recommended both as a reference for researchers and professionals working with reverberation chambers, and as a textbook for a course on reverberation chambers." (Radio Science Bulletin, 1 December 2011) Table of ContentsPreface xiii Foreword xv Paolo CORONA Introduction xix Chapter 1. Position of the Reverberation Chambers in Common Electromagnetic Tests 1 1.1. Introduction 1 1.2. Electromagnetic fields and plane waves 2 1.3. Electromagnetic tests in confined areas 13 1.4. Discussion 26 1.5. Bibliography 28 Chapter 2. Main Physical Features of Electromagnetic Cavities 29 2.1. Introduction 29 2.2. Reduction of the modes in a 1D cavity 30 2.3. Physical features of an empty rectangular cavity 44 2.4. The 3D cavity operating in stirred modes 69 2.5. Discussion 77 2.6. Bibliography 80 Chapter 3. Statistical Behavior of Stirred Waves in an Oversized Cavity 83 3.1. Introduction 83 3.2. Descriptions of the ideal random electromagnetic field 84 3.3. Simulation of the properties of an ideal random field 93 3.4. Contribution of the statistical tests 104 3.5. Balance of power in a reverberation chamber 121 3.6. Discussion 130 3.7. Bibliography 132 Chapter 4. Impact of the Physical and Technological Parameters of a Reverberation Chamber 135 4.1. Introduction 135 4.2. Main parameters for reverberation chamber design 136 4.3. The usual techniques of mode stirring 153 4.4. The characterization of reverberation chambers 164 4.5. Discussion 188 4.6. Bibliography 190 Chapter 5. Radiated Immunity Tests in a Reverberation Chamber 193 5.1. Introduction 193 5.2. The calibration process 194 5.3. Examples of calibration results 206 5.4. Implementing of the immunity test for a piece of equipment 210 5.5. Immunity test in reverberation and anechoic chambers 220 5.6. Rectangular components of the electric field and the total electric field 226 5.7. Discussion 228 5.8. Bibliography 230 Chapter 6. Emissivity Tests in Reverberation Chambers 233 6.1. Introduction 233 6.2. A few notions on electromagnetic radiation and antennas 234 6.3. Measurement of the total radiated power in free space 249 6.4. Measurement of the unintentional emission of a device under test 252 6.5. Measurement examples of the total radiated power 262 6.6. Total radiated power and radiated emissivity 269 6.7. Measurement of the efficiency and of the diversity gain of the antennas 272 6.8. Discussion 275 6.9. Bibliography 276 Chapter 7. Measurement of the Shielding Effectiveness 279 7.1. Introduction 279 7.2. Definitions of the shielding effectiveness 280 7.3. Measurement of the effectiveness of shielded cables and connectors in reverberation chambers 287 7.4. Measurement of the attenuation of the shielded enclosures 302 7.5. Measurement of the shielding effectiveness of the materials 307 7.6. Discussion 316 7.7. Bibliography 318 Chapter 8. Mode Stirring Reverberation Chamber: A Research Tool 321 8.1. Introduction 321 8.2. A non-ideal random electromagnetic field 324 8.3. Studying the correlation of a set of measurements 336 8.4. Quantization of the scattered and coherent fields in a reverberation chamber 349 8.5. Discussion 356 8.6. Bibliography 358 APPENDICES 361 Appendix 1. Notion of Probability 363 A1.1. The random variable concept 363 A1.2. Probability concept from intuition 363 A1.3. Probability density function (pdf) 364 A1.4. Computation of moments 365 A1.5. Centered and normalized variables 366 A1.6. Computation of the variance and standard deviation 367 A1.7. Probability distributions 367 A1.8. The cumulative distribution function (cdf) 369 A1.9. The ergodism notion 369 A1.10. Features of the random stationary variables 372 A1.11. The characteristic function 373 A1.12. Summary of the main probability distributions 375 A1.13. Tables of numerical values of the normal distribution integrals 378 A1.14. Bibliography 379 Appendix 2. Formulas of the Quality Factor of a Rectangular Cavity 381 A2.1. Quality factor of the TMm n p mode 381 A2.2. Calculation of the average Q quality factor 382 A2.3. Bibliography 384 Appendix 3. Total Field and Total Power Variables 385 A3.1. Total field variables 385 A3.2. χ2 variable attached to the total field 386 A3.3. Total field probability density function 386 A3.4. Calculation of the mean of the total field 387 A3.5. The pdf of the total power 388 A3.6. Calculation of the mean total powers 389 Appendix 4. Calculation of the Variances of υφ, υη, υθ 391 A4.1. Variance of the υφ and υη variables 391 A4.2. Variance of the υθ variable 392 Appendix 5. Electric Dipole Formulas 395 A5.1. Complete formulas of the electric dipole 395 A5.2. Near-field formulas of the electric dipole 397 A5.3. Far-field formulas of the electric dipole 397 A5.4. Bibliography 398 Index 399

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