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100   $a20081015d2009      uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aElectromagnetism and interconnections$b[electronic resource] $eadvanced mathematical tools for computer-aided simulation /$fSte?phane Charruau
210   $aLondon $cISTE ; Hoboken, NJ : Wiley$d2009
215   $a1 online resource (312 p.)
225 1 $aISTE ;$vv.124
300   $aDescription based upon print version of record.
311   $a1-84821-107-4 
320   $aIncludes bibliographical references and index.
327   $aElectromagnetism and Interconnections; Table of contents; Acknowledgements; Introduction; Chapter 1. Theoretical Foundations of Electromagnetism; 1.1. Elements of the theory of distributions applied to electromagnetism; 1.1.1. Choosing a presentation of the foundations of electromagnetism; 1.1.2. Linear modeling of physical laws and Green's kernels; 1.1.3. Accounting for the "natural symmetries" of physical laws; 1.1.4. Motivation for using the theory of distributions; 1.1.5. Quick review of the theory of distributions; 1.1.6. Application to electromagnetism
327   $a1.2. Vector analysis review according to the theory of distributions1.2.1. Derivation of discontinuous functions defined on R; 1.2.2. Derivative of linear mappings; 1.2.3. Derivation of discontinuous functions on a surface in R3; 1.2.4. Derivation of vector distributions in R3; 1.2.5. Algebra of the operator N?; 1.3. Maxwell's equations according to the theory of distributions; 1.3.1. Symmetries and duality in electromagnetism; 1.3.2. The symmetry laws of distributions in electromagnetism; 1.3.3. Application to the first couple of Maxwell's equations
327   $a1.3.4. Behavior law of materials by means of the theory of distributions1.3.5. Application to the second couple of Maxwell's equations; 1.3.6. Charge density, current density, continuity equations; 1.3.7. Integral form of Maxwell's equations; 1.4. Conclusion; Chapter 2. Full Wave Analysis; 2.1. Discontinuities in electromagnetism; 2.1.1. Initial and boundary conditions according to the theory of distributions; 2.1.2. Electromagnetic images, incident and reflected fields; 2.1.3. Method of moments for the numerical computation of electromagnetic fields; 2.2. Potentials in electromagnetism
327   $a2.2.1. Scalar and vector potentials, duality between electrical and magnetic potentials2.2.2. Lossy propagation equations, the Lorentz gauge; 2.2.3. Green's kernels for harmonic electromagnetic waves in heterogenous media; 2.3. Topology of electromagnetic interferences; 2.3.1. Introduction; 2.3.2. Topological modeling of electromagnetic interferences; 2.3.3. Partitioning the electrical network in respect of electromagnetic interferences; 2.3.4. The tree of electromagnetic interferences and the problem of loops; 2.4. Conclusion; Chapter 3. Electromagnetism in Stratified Media
327   $a3.1. Electrical and magnetic currents in stratified media3.1.1. Scope of the theory, defining stratified media; 3.1.2. Integral formulation of the current derivative versus time: general case; 3.1.3. Integral formula of the current derivative relative to space in the direction of the vector potentia; 3.1.4. Duality between electrical and magnetic currents in lossless media; 3.2. Straight stratified media; 3.2.1. Scope; 3.2.2. Lossy propagation equations and the variational approach; 3.2.3. Spectral analysis of the longitudinal field
327   $a3.2.4. From Maxwell's equations to transmission line equations
330   $aThis book covers the theoretical problems of modeling electrical behavior of the interconnections encountered in everyday electronic products. The coverage shows the theoretical tools of waveform prediction at work in the design of a complex and high-speed digital electronic system. Scientists, research engineers, and postgraduate students interested in electromagnetism, microwave theory, electrical engineering, or the development of simulation tools software for high speed electronic system design automation will find this book an illuminating resource.
410  0$aISTE
606   $aTelecommunication lines$xComputer simulation
606   $aElectromagnetic waves$xMathematical models
615  0$aTelecommunication lines$xComputer simulation.
615  0$aElectromagnetic waves$xMathematical models.
676   $a621.34
676   $a621.381
700   $aCharruau$b Stephane$01689093
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910830874403321
996   $aElectromagnetism and interconnections$94063847
997   $aUNINA