An Introduction to Applied Electromagnetics and Optics (eBook, PDF)
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An Introduction to Applied Electromagnetics and Optics (eBook, PDF)
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Modern technology is rapidly developing and for this reason future engineers need to acquire advanced knowledge in science and technology, including electromagnetic phenomena. This book is a contemporary text of a one-semester course for junior electrical engineering students. It covers a broad spectrum of electromagnetic phenomena such as, surface waves, plasmas, photonic crystals, negative refraction as well as related materials including superconductors. In addition, the text brings together electromagnetism and optics as the majority of texts discuss electromagnetism disconnected from…mehr
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- Produktdetails
- Verlag: Taylor & Francis
- Seitenzahl: 368
- Erscheinungstermin: 18. November 2016
- Englisch
- ISBN-13: 9781498776301
- Artikelnr.: 52845575
- Verlag: Taylor & Francis
- Seitenzahl: 368
- Erscheinungstermin: 18. November 2016
- Englisch
- ISBN-13: 9781498776301
- Artikelnr.: 52845575
Dmitry I. Sementsov is Professor of Physics at Ulyanovsk State University, Russia. He is the author of one textbook and more than 420 research papers published in peer-reviewed journals.
ELECTROSTATICS. Electric charges, electric charge conservation law,
Coulomb's law. Electric field vector, principle of superposition. Electric
potential and electric field energy. Gauss's law for the electric field.
Relation between the electric field and the electric potential. Poisson's
and Laplace equations. Electric field in a medium, electric displacement.
Problems. CHAPTER 2. MAGNETOSTATICS. Interaction of moving charges. The
field of moving charges and currents, the Biot-Savart law. Ampere's law.
Magnetic field of a solenoid. Magnetic field in a medium, magnetic field
intensity. Problems. CHAPTER 3. MAXWELL'S EQUATIONS FOR ELECTROMAGNETIC
FIELDS. Faraday's law. Self-inductance and mutual inductance. Magnetic
field energy. Transient processes in circuits with capacitors and
inductors. Displacement current. Maxwell's equations. Problems. PART II:
ELECTROMAGNETIC WAVES IN HOMOGENEOUS, HETEROGENEOUS AND ANISOTROPIC MEDIA.
CHAPTER 4. ELECTROMAGNETIC WAVES IN HOMOGENEOUS MEDIA WITHOUT ABSORPTION.
Electromagnetic wave spectrum. Wave equation. Plane monochromatic waves.
olarization of electromagnetic waves. Superposition of electromagnetic
waves. Energy and momentum of a wave. Standing waves. Interference and
coherence of electromagnetic waves. Problems. CHAPTER 5. ELECTROMAGNETIC
FIELDS AND WAVES AT THE INTERFACE BETWEEN TWO MEDIA. Boundary conditions
and inverse boundary value problem in electromagnetism Boundary conditions
for the electric field of an electromagnetic wave. Boundary conditions for
the magnetic field of an electromagnetic wave. Laws of reflection and
refraction of waves. Reflection and transmission coefficients of waves.
Total internal reflection. Reflection of a wave from a dielectric layer.
Problems. CHAPTER 6. ELECTROMAGNETIC WAVES IN ANISOTROPIC AND OPTICALLY
ACTIVE MEDIA. The structure of plane wave in an anisotropic medium.
Dispersion relation and normal waves. Waves in uniaxial crystals. The
refractive index ellipsoid. Optically active media. Waves in chiral media.
Problems. CHAPTER 7. ELECTROMAGNETIC WAVES IN CONDUCTING MEDIA. The
dielectric permittivity and impedance of a metal. Skin effect. Wave
incidence on a metal surface. Surface waves at the interface between a
dielectric and a conductor. Superconductivity. Quantum effects in
superconductivity. Problems. PART III: ELECTROMAGNETIC WAVES IN PERIODIC
AND WAVEGUIDING STRUCTURES. CHAPTER 8. WAVES IN PERIODIC STRUCTURES.
Diffraction phenomena. Diffraction by a slit. Diffraction by a
one-dimensional lattice. Diffraction by a three-dimensional lattice. Waves
in continuous periodic media. Waves in planar layered periodic structures.
Photonic crystals. Problems. CHAPTER 9. WAVES IN GUIDING STRUCTURES. Types
of guiding structures. Field structure over the conducting plane. Field
between two parallel metal planes. Fields in a rectangular waveguide. The
waveguide operating conditions. Attenuation of waves in waveguides.
Reflections in transmission lines and need of their matching. Two-wire,
coaxial, and strip-line transmission lines. Optical waveguides
(lightguides). Problems. CHAPTER 10. EMISSION OF
ELECTROSTATICS. Electric charges, electric charge conservation law,
Coulomb's law. Electric field vector, principle of superposition. Electric
potential and electric field energy. Gauss's law for the electric field.
Relation between the electric field and the electric potential. Poisson's
and Laplace equations. Electric field in a medium, electric displacement.
Problems. CHAPTER 2. MAGNETOSTATICS. Interaction of moving charges. The
field of moving charges and currents, the Biot-Savart law. Ampere's law.
Magnetic field of a solenoid. Magnetic field in a medium, magnetic field
intensity. Problems. CHAPTER 3. MAXWELL'S EQUATIONS FOR ELECTROMAGNETIC
FIELDS. Faraday's law. Self-inductance and mutual inductance. Magnetic
field energy. Transient processes in circuits with capacitors and
inductors. Displacement current. Maxwell's equations. Problems. PART II:
ELECTROMAGNETIC WAVES IN HOMOGENEOUS, HETEROGENEOUS AND ANISOTROPIC MEDIA.
CHAPTER 4. ELECTROMAGNETIC WAVES IN HOMOGENEOUS MEDIA WITHOUT ABSORPTION.
Electromagnetic wave spectrum. Wave equation. Plane monochromatic waves.
olarization of electromagnetic waves. Superposition of electromagnetic
waves. Energy and momentum of a wave. Standing waves. Interference and
coherence of electromagnetic waves. Problems. CHAPTER 5. ELECTROMAGNETIC
FIELDS AND WAVES AT THE INTERFACE BETWEEN TWO MEDIA. Boundary conditions
and inverse boundary value problem in electromagnetism Boundary conditions
for the electric field of an electromagnetic wave. Boundary conditions for
the magnetic field of an electromagnetic wave. Laws of reflection and
refraction of waves. Reflection and transmission coefficients of waves.
Total internal reflection. Reflection of a wave from a dielectric layer.
Problems. CHAPTER 6. ELECTROMAGNETIC WAVES IN ANISOTROPIC AND OPTICALLY
ACTIVE MEDIA. The structure of plane wave in an anisotropic medium.
Dispersion relation and normal waves. Waves in uniaxial crystals. The
refractive index ellipsoid. Optically active media. Waves in chiral media.
Problems. CHAPTER 7. ELECTROMAGNETIC WAVES IN CONDUCTING MEDIA. The
dielectric permittivity and impedance of a metal. Skin effect. Wave
incidence on a metal surface. Surface waves at the interface between a
dielectric and a conductor. Superconductivity. Quantum effects in
superconductivity. Problems. PART III: ELECTROMAGNETIC WAVES IN PERIODIC
AND WAVEGUIDING STRUCTURES. CHAPTER 8. WAVES IN PERIODIC STRUCTURES.
Diffraction phenomena. Diffraction by a slit. Diffraction by a
one-dimensional lattice. Diffraction by a three-dimensional lattice. Waves
in continuous periodic media. Waves in planar layered periodic structures.
Photonic crystals. Problems. CHAPTER 9. WAVES IN GUIDING STRUCTURES. Types
of guiding structures. Field structure over the conducting plane. Field
between two parallel metal planes. Fields in a rectangular waveguide. The
waveguide operating conditions. Attenuation of waves in waveguides.
Reflections in transmission lines and need of their matching. Two-wire,
coaxial, and strip-line transmission lines. Optical waveguides
(lightguides). Problems. CHAPTER 10. EMISSION OF