Electromagnetic Field Theory Fundamentals Guru Pdf Free Download
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Electromagnetic Field Theory Fundamentals by Bhag Singh Guru and HÃseyin R. Hiziroglu
This is a book review of Electromagnetic Field Theory Fundamentals by Bhag Singh Guru and HÃseyin R. Hiziroglu, published by Cambridge University Press in 2004[^1^]. The book is intended for undergraduate students who want to learn the basic concepts and applications of electromagnetic fields.
The book covers electrostatics, magnetostatics, time-varying fields, plane wave propagation, transmission lines, waveguides, cavity resonators, antennas, and computer-aided analysis of electromagnetic fields. It also includes appendices on Smith chart, computer programs for various problems, and useful mathematical tables. The book features many worked examples and problems in every chapter, as well as chapter summaries and background revision material where appropriate.
The book is written in a clear and concise style, with an emphasis on physical understanding and practical applications. The authors explain the fundamental principles of electromagnetic field theory using vector analysis and Maxwell's equations. They also provide relevant examples from engineering and physics to illustrate the concepts and phenomena. The book is well-organized and easy to follow, with a logical progression of topics and a consistent notation.
The book is suitable for students who have a basic knowledge of calculus, differential equations, and physics. It can be used as a textbook for a one-semester or two-semester course on electromagnetic field theory. It can also be used as a reference book for engineers and scientists who work with electromagnetic fields.
The book is available as an ebook or a print book from Cambridge University Press[^1^]. It can also be accessed from Google Books[^2^] or Archive.org[^3^]. However, these sources may not provide the full content of the book or may require registration or payment. Therefore, it is recommended to buy the book from the publisher or a reputable online bookstore.Here is a possible continuation of the article:
The following is a brief overview of the main topics covered in each chapter of the book:
Chapter 1 introduces the electromagnetic field theory and its historical development. It also reviews the basic units and dimensions used in electromagnetics.
Chapter 2 presents the vector analysis tools needed to describe and manipulate electromagnetic fields. It covers vector algebra, coordinate systems, differential operators, line and surface integrals, divergence theorem, and Stokes' theorem.
Chapter 3 deals with electrostatics, which is the study of electric fields produced by stationary charges. It derives the Coulomb's law, electric potential, Gauss's law, Poisson's and Laplace's equations, capacitance, energy and force in electrostatic fields.
Chapter 4 discusses steady electric currents, which are electric currents that do not vary with time. It introduces the concepts of current density, Ohm's law, resistance, Kirchhoff's laws, power and energy in electric circuits.
Chapter 5 focuses on magnetostatics, which is the study of magnetic fields produced by steady currents. It derives the Biot-Savart law, magnetic vector potential, Ampere's law, magnetic flux and flux density, magnetic force and torque, magnetic dipole moment, and magnetic materials.
Chapter 6 explores some applications of static fields in engineering and physics. It covers electrostatic generators and motors, electrostatic precipitation and painting, magnetostatic generators and motors, magnetic levitation and propulsion, magnetic recording and storage.
Chapter 7 extends the electromagnetic field theory to time-varying fields. It introduces the concept of electromagnetic induction and Faraday's law. It also derives the displacement current and Maxwell's equations in integral and differential forms.
Chapter 8 studies plane wave propagation in different media. It defines the wave equation, wave parameters, polarization, reflection and refraction at boundaries, Snell's law, Brewster's angle, total internal reflection, Fresnel's equations.
Chapter 9 analyzes transmission lines as a special case of wave propagation. It introduces the concepts of characteristic impedance, reflection coefficient, standing wave ratio, input impedance, impedance matching, Smith chart.
Chapter 10 examines waveguides and cavity resonators as another special case of wave propagation. It classifies waveguides into rectangular and circular types. It also discusses the modes of propagation, cut-off frequency, phase velocity and group velocity in waveguides.
Chapter 11 investigates antennas as devices that radiate or receive electromagnetic waves. It covers the basic parameters of antennas such as radiation pattern, directivity, gain, beamwidth, efficiency. It also describes some common types of antennas such as dipole antenna, loop antenna, horn antenna.
Chapter 12 introduces some computer-aided methods for solving electromagnetic field problems. It covers the finite element method (FEM) and the finite difference method (FDM) as numerical techniques for solving partial differential equations. It also provides some examples of using MathCad software for electromagnetic field analysis. aa16f39245