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_aQC670 _b.I5 1999 |
| 100 | 1 |
_aInan, Umran S. _91648 |
|
| 245 | 1 | 0 |
_aEngineering Electromagnetics / _cUmran S. Inan, Aziz S. Inan. |
| 260 |
_aMenlo Park, Calif. : _bAddison-Wesley, _cc1999. |
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| 300 |
_axx, 776, 28 p. : _bcol. ill. ; _c25 cm. |
||
| 505 | _a1. Introduction. Lumped versus Distributed Electrical Circuits. Electromagnetic Components. Maxwell's Equations and Electromagnetic Waves. Summary. 2. Transient Response of Transmission Lines. Heuristic Discussion of Transmission Line Behavior and Circuit Models. Transmission Line Equations and Wave Solutions. Reflection at Discontinuities. Transient Response of Transmission Lines with Resistive Terminations. Transient Response of Transmission Lines with Reactive or Nonlinear Terminations. Selected Practical Topics. Transmission Line Parameters. Summary. Problems. 3. Steady-State Waves on Transmission Lines Wave Solutions Using Phasors. Voltage and Current on Lines with Short- or Open-Circuit. Terminations. Lines Terminated with Arbitrary Impedance. Power Flow on a Transmission Line. Impedance Matching. The Smith Chart. Selected Application Examples. Sinusoidal Steady-State Behavior of Lossy Lines. Transmission Lines as Resonant Circuits Elements. Summary. Problems. 4. The Static Electric Field. Electric Charge. Coulomb's Law. The Electric Field. The Electric Potential. Electric Flux and Gauss's Law. Divergence: Differential Form of Gauss's Law. Metallic Conductors. Poisson's and Laplace's Equations. Capacitance. Dielectric Materials. Electrostatic Boundary Conditions. Electrostatic Energy. Electrostatic Forces. Summary. Problems. 5. Steady Electric Currents. Current Density and the Microscopic View of Conduction. Current Flow, ohm's Law, and Resistance. Electromotive Force and Kirchoff's Voltage Law. The Continuity Equation and Kirchoff's Current Law. Redistribution of Free Charge. Boundary Conditions for Steady Current Flow. Duality of J and D: The Resistance-Capacitance Analogy. Joule's Law. Summary. Problems. 6. The Static Magnetic Field. Ampere's Law of Force. The Biot-Savart Law and Its Applications. Ampere's Circuital Law. Curl of the Magnetic Field: Differential Form of Ampere's Law. Vector Magnetic Potential. The Magnetic Dipole. Divergence of B, | ||
| 520 | _aEngineering Electromagnetics provides a solid foundation in electromagnetics fundamentals by emphasizing physical understanding and practical applications. Electromagnetics, with its requirements for abstract thinking, can prove challenging for students. The authors' physical and intuitive approach has produced a book that will inspire enthusiasm and interest for the material. Benefiting from a review of electromagnetic curricula at several schools and repeated use in classroom settings, this text presents material in a rigorous yet readable manner. | ||
| 650 | 0 |
_aElectromagnetic theory. _91649 |
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| 942 |
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