| Description |
1 online resource (xii, 224 pages) : illustrations |
| Contents |
880-01 2.7 The Potential Function -- 2.8 Field Due to a Continuous Distribution of Charges -- 2.9 Equipotential Surfaces -- 2.10 Conductors -- 2.11 Gauss's Divergence theorem -- 2.12 Integral form of Divergence -- 2.13 Alternate statement of Gauss's law -- 2.14 Poission's Equation and Laplace's Equation -- 2.15 Problem of Electrostatics -- 2.16 Solution for Some Simple Cases -- 2.17 Electrical Image Method -- 2.18 Example -- 2.19 Capacitance -- 2.20 Electrostatic Energy Stored in a Capacitor -- 2.21 Energy Associated to An Electrostatic Field -- 2.22 Boundary Conditions Between the Two Dielectrics |
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880-01/(S 2.23 The Electrostatic Uniqueness Theorem -- 2.24 Dirac-delta Representation for a Point Charge -- 2.25 Dirac Delta (δ ) Representation for an Infinitesimal Dipole -- CHAPTER 3 STEADY MAGNETIC FIELDS -- 3.1 The Steady Magnetic Field -- 3.2 Magnetic Induction and Faraday's Law -- 3.3 Some Parameters -- 3.4 Ampere's Work Law in the Differential Form -- 3.5 Ampere's Law for a Current Element or Biot-Savart's Law -- 3.6 Magnetic Field Due to Volume Distribution of Current and the Dirac Delta -- 3.7 Ampere's Force Law -- 3.8 Magnetic Vector Potential -- 3.9 The Vector Potential (Alternate Approach) |
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3.10 The Far Magnetic field of a Current Distribution -- 3.11 Equation of Continuity (Conservation of nos. of Charges) -- CHAPTER 4 TIME VARYING FIELDS AND MAXWELL'S EQUATIONS -- 4.1 Inconsistency of Ampere's Law -- 4.2 Maxwell's Equations -- 4.3 Maxwell's Equations in Static Field -- 4.4 Derivation: (Maxwell's Equations in Differential Form) -- 4.5 Physical Significance of Maxwell's Equations -- 4.6 Plane Wave Equation in a Homogeneous Medium -- 4.7 Plane Wave Equation in Free Space -- 4.8 Uniform Plane Wave Propagation -- 4.9 Uniform Plane Wave |
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4.10 Relation between 'E' and 'H' in a Uniform Plane Wave -- 4.11 The Wave Equations for a Conducting Medium -- 4.12 Poynting's Theorem -- 4.13 Power Loss in a Plane Conductor -- 4.14 Maxwell's Equations Using Phasor Notation -- 4.15 Electromagnetic Equations in Phasor Notation -- 4.16 Wave Propagation in a Conducting Medium -- 4.17 Conductors and Dielectrics -- 4.18 Wave Propagation in Good Dielectrics -- 4.19 Wave Propagation in Good Conductor -- 4.20 Depth of Penetration or Skin Depth -- 4.21 Polarization -- CHAPTER 5 REFLECTION AND REFRACTION OF E.M.WAVES -- 5.1 Introduction |
| Summary |
This textbook presents the fundamental concepts and theories in electromagnetic theory in a very simple, systematic, and comprehensive way. The book is written in a lucid manner so that they are able to understand the realization behind the mathematical concepts which are the backbone of this subject. All the subject fundamentals and related derivations are discussed in an easy and comprehensive way to make the students strong about the basics of the electromagnetic theory. The philosophy of presentation and material content in the book is based on concept-based approach toward the subject. The key features also lies in the solutions of several interesting numerical problems so that the students should have the idea of the practical usages of the subject. The book benefits students who are taking introductory courses in electromagnetic wave and field theory for applications in communication engineering |
| Notes |
Online resource; title from PDF title page (SpringerLink, viewed August 22, 2022) |
| Subject |
Electromagnetic theory.
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Electromagnetic theory
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| Form |
Electronic book
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| Author |
Dhasmana, Hrishikesh, author.
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| ISBN |
9783031123184 |
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3031123182 |
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