LEADER 06067nam 2200649 450 001 996216181703316 005 20221206181725.0 010 $a1-282-34836-1 010 $a9786612348365 010 $a0-470-54348-5 010 $a0-470-54346-9 024 7 $a10.1002/9780470543481 035 $a(CKB)1000000000806930 035 $a(EBL)469528 035 $a(SSID)ssj0000296770 035 $a(PQKBManifestationID)11246215 035 $a(PQKBTitleCode)TC0000296770 035 $a(PQKBWorkID)10327250 035 $a(PQKB)11339055 035 $a(MiAaPQ)EBC469528 035 $a(CaBNVSL)mat05361045 035 $a(IDAMS)0b0000648117886d 035 $a(IEEE)5361045 035 $a(OCoLC)476315039 035 $a(EXLCZ)991000000000806930 100 $a20151221d2009 uy 101 0 $aeng 135 $aur|n|---||||| 181 $ctxt 182 $cc 183 $acr 200 14$aThe foundations of signal integrity /$fPaul G. Huray 210 1$aHoboken, New Jersey :$cIEEE Press,$dc2010. 210 2$a[Piscataqay, New Jersey] :$cIEEE Xplore,$d[2009] 215 $a1 online resource (363 p.) 300 $aDescription based upon print version of record. 311 $a0-470-34360-5 320 $aIncludes bibliographical references and index. 327 $aPreface -- Intent of the Book -- 1. Plane Electromagnetic Waves -- Introduction -- 1.1 Propagating Plane Waves -- 1.2 Polarized Plane Waves -- 1.3 Doppler Shift -- 1.4 Plane Waves in a Lossy Medium -- 1.5 Dispersion and Group Velocity -- 1.6 Power and Energy Propagation -- 1.7 Momentum Propagation -- Endnotes -- 2. Plane Waves in Compound Media -- Introduction -- 2.1 Plane Wave Propagating in a Material as It Orthogonally Interacts with a Second Material -- 2.2 Electromagnetic Boundary Conditions -- 2.3 Plane Wave Propagating in a Material as It Orthogonally Interacts with Two Boundaries -- 2.4 Plane Wave Propagating in a Material as It Orthogonally Interacts with Multiple Boundaries -- 2.5 Polarized Plane Waves Propagating in a Material as They Interact Obliquely with a Boundary -- 2.6 Brewster's Law -- 2.7 Applications of Snell's Law and Brewster's Law -- Endnote -- 3. Transmission Lines and Waveguides -- 3.1 Infi nitely Long Transmission Lines -- 3.2 Governing Equations -- 3.3 Special Cases -- 3.4 Power Transmission -- 3.5 Finite Transmission Lines -- 3.6 Harmonic Waves in Finite Transmission Lines -- 3.7 Using AC Spice Models -- 3.8 Transient Waves in Finite Transmission Lines -- 4. Ideal Models vs Real-World Systems -- Introduction -- 4.1 Ideal Transmission Lines -- 4.2 Ideal Model Transmission Line Input and Output -- 4.3 Real-World Transmission Lines -- 4.4 Effects of Surface Roughness -- 4.5 Effects of the Propagating Material -- 4.6 Effects of Grain Boundaries -- 4.7 Effects of Permeability -- 4.8 Effects of Board Complexity -- 4.9 Final Conclusions for an Ideal versus a Real-World Transmission Line -- Endnotes -- 5. Complex Permittivity of Propagating Media -- Introduction -- 5.1 Basic Mechanisms of the Propagating Material -- 5.2 Permittivity of Permanent Polar Molecules -- 5.3 Induced Dipole Moments -- 5.4 Induced Dipole Response Function, G(?) -- 5.5 Frequency Character of the Permittivity -- 5.6 Kramers-Kronig Relations for Induced Moments -- 5.7 Arbitrary Time Stimulus. 327 $a5.8 Conduction Electron Permittivity -- 5.9 Conductivity Response Function -- 5.10 Permittivity of Plasma Oscillations -- 5.11 Permittivity Summary -- 5.12 Empirical Permittivity -- 5.13 Theory Applied to Empirical Permittivity -- 5.14 Dispersion of a Signal Propagating through a Medium with Complex Permittivity -- Endnotes -- 6. Surface Roughness -- Introduction -- 6.1 Snowball Model for Surface Roughness -- 6.2 Perfect Electric Conductors in Static Fields -- 6.3 Spherical Conductors in Time-Varying Fields -- 6.4 The Far-Field Region -- 6.5 Electrodynamics in Good Conducting Spheres -- 6.6 Spherical Coordinate Analysis -- 6.7 Vector Helmholtz Equation Solutions -- 6.8 Multipole Moment Analysis -- 6.9 Scattering of Electromagnetic Waves -- 6.10 Power Scattered and Absorbed by Good Conducting Spheres -- 6.11 Applications of Fundamental Scattering -- Endnotes -- 7. Advanced Signal Integrity -- Introduction -- 7.1 Induced Surface Charges and Currents -- 7.2 Reduced Magnetic Dipole Moment Due to Field Penetration -- 7.3 Infl uence of a Surface Alloy Distribution -- 7.4 Screening of Neighboring Snowballs and Form Factors -- 7.5 Pulse Phase Delay and Signal Dispersion -- Chapter Conclusions -- Endnotes -- 8. Signal Integrity Simulations -- Introduction -- 8.1 Defi nition of Terms and Techniques -- 8.2 Circuit Simulation -- 8.3 Transient SPICE Simulation -- 8.4 Emerging SPICE Simulation Methods -- 8.5 Fast Convolution Analysis -- 8.6 Quasi-Static Field Solvers -- 8.7 Full-Wave 3-D FEM Field Solvers -- 8.8 Conclusions -- Endnotes -- Bibliography -- Index. 330 $aThe first book to focus on the electromagnetic basis of signal integrity The Foundations of Signal Integrity is the first of its kind-a reference that examines the physical foundation of system integrity based on electromagnetic theory derived from Maxwell's Equations. Drawing upon the cutting-edge research of Professor Paul Huray's team of industrial engineers and graduate students, it develops the physical theory of wave propagation using methods of solid state and high-energy physics, mathematics, chemistry, and electrical engineering before addressing its application 606 $aSignal integrity (Electronics) 606 $aElectromagnetic interference$xPrevention 606 $aElectric lines 615 0$aSignal integrity (Electronics) 615 0$aElectromagnetic interference$xPrevention. 615 0$aElectric lines. 676 $a530.141 676 $a621.3822 700 $aHuray$b Paul G.$f1941-$0845350 801 0$bCaBNVSL 801 1$bCaBNVSL 801 2$bCaBNVSL 906 $aBOOK 912 $a996216181703316 996 $aThe foundations of signal integrity$91887678 997 $aUNISA