Electromagnetics Microwave Circuit And Antenna Design for Communications Engineering by Peter Russer

Electromagnetics Microwave Circuit And Antenna Design for Communications Engineering

PDF Free Download | Electromagnetics Microwave Circuit And Antenna Design for Communications Engineering 2nd Edition by Peter Russer

Contents of Electromagnetics Microwave Circuit

  • Chapter 1 Introduction
  • References
  • Chapter 2 Basic Electromagnetics
  • The Electromagnetic Field Concept
  • Field Intensities
  • Current and Flux Densities
  • Constitutive Relations
  • The Charge Density
  • The Maxwell Puzzle
  • The Integral Form of Maxwell’s Equations
  • The Electromagnetic Wave
  • The Wave Equation
  • The Polarization of Electromagnetic Waves
  • Kirchhoff’s Laws
  • Maxwell’s Equations in Local Form
  • Time-Harmonic Electromagnetic Fields
  • Maxwell’s Equations in the Frequency Domain
  • Curvilinear Coordinates
  • Boundary Conditions
  • Problems
  • References
  • Chapter 3 Potentials and Waves
  • The Electromagnetic Potentials
  • The Helmholtz Equation
  • Time-Harmonic Plane Waves
  • Time-Harmonic Plane Waves in Lossless Medium
  • Complex Waves
  • TM and TE Fields and Waves
  • Reflection and Transmission of Plane Waves
  • Reflection and Diffraction of a TE Wave at a Plane Boundary
  • Reflection and Diffraction of a TM Wave at a Plane Boundary
  • Total Reflection
  • Waves in Planar Layered Media
  • Thin Conducting Sheets
  • The Vector Wave Equation
  • Circular Cylindrical Waves
  • Excitation of a Cylindric Wave by a Uniform Current Filament
  • Spherical Waves
  • Problems References
  • Chapter 4 Concepts, Methods, and Theorems
  • Energy and Power
  • Field Theoretic Formulation of Tellegen’s Theorem
  • Sources of the Electromagnetic Field
  • The Uniqueness Theorem
  • The Equivalence Principle
  • Babinet’s Principle
  • Reciprocity
  • The Lorentz Reciprocity Theorem
  • The Reciprocity Theorem for Impressed Sources
  • Greens Function
  • The Integral Equation Method
  • The Free-Space Green’s Dyadic Form
  • Green’s Theorems
  • The Scalar Green’s Theorems
  • Green’s Theorems in Two Dimensions
  • The Vector Green’s Theorems
  • Integral Formulation of the Equivalence Principle
  • The Sturm-Liouville Equation
  • Spectral Representation of Green’s Functions
  • Problems References
  • Chapter 5 Static and Quasistatic Fields
  • Conditions for Static and Quasistatic Fields
  • Static and Quasistatic Electric Fields
  • Greens Function for the Static Electric Field
  • Capacitance
  • Static and Quasistatic Magnetic Fields
  • Green’s Function for the Static Magnetic Field
  • Inductance
  • The Laplace Equation
  • Potential Separation Planes
  • Three-Dimensional Laplace Equation in Cartesian Coordinates
  • Conformal Mapping
  • Field of an Elliptic Cylindric Line
  • Field of a Coaxial Line
  • Parallel Wire Line
  • The Schwarz-Christoffel Transformation
  • The Coplanar Line
  • The Coplanar Stripline
  • The Stripline
  • Problems References
  • Chapter 6 Waves at the Surface of Conducting Media
  • Transverse Magnetic Surface Waves
  • Surface Currents
  • Surface Current Losses
  • Induced Surface Currents
  • Problems References
  • Chapter 7 Transmission-Lines and Waveguides
  • Introduction
  • Phase and Group Velocity
  • The Field Components
  • Waveguides for Transverse Electromagnetic Waves
  • Chapter 8 The Transmission-Line Equations
  • The Transmission-Line Concept
  • Generalized Voltages and Currents
  • Solution of the Transmission-Line Equations
  • Wave Amplitudes
  • Reflection Coefficient and Smith Chart
  • Impedance Matching with Lumped Elements
  • Impedance Matching with Stubs
  • Solution of the Multiconductor Transmission-Line Equations
  • Multimode Excitation of Uniform Hollow Waveguides
  • The Transverse Field Equations
  • Modal Field Representation
  • Multimode Transmission-Line Equations for Hollow Waveguides
  • Multimode Transmission-Line Equations of Lossless Waveguides without Internal Sources
  • Green’s Functions for Transmission-Lines
  • Greens Function for the Transmission-Line with Matched Terminations
  • Green’s Function for the Transmission-Line with Arbitrary Linear Passive Terminations
  • Problems References
  • Chapter 9 Resonant Circuits and Resonators
  • The Linear Passive One- Port
  • The Reactance Theorem
  • Resonant Circuits
  • The Transmission-Line Resonator
  • Cavity Resonators
  • The Rectangular Cavity Resonator
  • The Circular Cylindric Cavity Resonator
  • Coupling of Resonant Circuits and Resonators
  • The Loaded Quality Factor
  • Termination of a Transmission-Line with a Resonant Circuit
  • Inductive Coupling of Cavity Resonators
  • Orthogonality of the Resonator Modes
  • Excitation of Resonators by Internal Sources
  • Problems
  • Chapter 10 Passive Microwave Circuits
  • Linear Multiports
  • Source-Free Linear Multiports
  • Impedance and Admittance Representations
  • The Chain Matrix
  • The Scattering Matrix
  • The Transmission Matrix
  • Tellegen’s Theorem
  • Connection Networks
  • Tellegen’s Theorem for Discretized Fields
  • The Power Properties
  • Reciprocal Multiports
  • Elementary Two-Ports
  • Signal Flow Graphs
  • Lumped Element Equivalent Circuits
  • Foster Representation of Reactance Multiports
  • Cauer Representation of Radiating Structures
  • Obstacles in Waveguides
  • The Symmetry Properties of Waveguide Junctions
  • Symmetric Three-Port Waveguide Junctions
  • Symmetric Four-Port Waveguide Junctions
  • Problems References
  • Chapter 11 Periodic Structures and Filters
  • Periodic Electromagnetic Structures
  • TE Modes in Rectangular Periodic Waveguides
  • Sinusoidal Variation of the Permittivity
  • Wave Parameter Theory of Two-Ports
  • Lumped Low-Pass Filter Prototypes
  • The Butterworth Prototype
  • The Chebyshev Prototype
  • Ladder Filter Networks
  • Butterworth Ladder Networks
  • Chebyshev Ladder Networks
  • Frequency Transformation
  • Low-Pass to High-Pass Transformation
  • Low-Pass to Band-Pass Transformation
  • Low-Pass to Band-Stop Transformation
  • Transmission-Line with Periodic Load
  • Plane Wave Scattering by Periodic Structures
  • Scattering of te Waves by Periodic Structures
  • Scattering of tm Waves by Periodic Structures
  • Metamaterials
  • Problems References
  • Chapter 12 Radiation from Dipoles
  • The Hertzian Dipole
  • Aperiodic Spherical Waves
  • Vertically Oriented Electric Dipole over Lossy Half-Space
  • The Far-Field of the Vertical Dipole over Ground
  • The Surface Wave
  • Horizontally Oriented Electric Dipole over Lossy Half-Space
  • Problems References
  • Chapter 13 Antennas
  • Introduction
  • Linear Antennas
  • The Integral Equation for the Linear Antenna
  • The Impedance of the Linear Antenna
  • The Loop Antenna
  • Receiving Antennas
  • The Hertzian Dipole as Receiving Antenna
  • The Loop Antenna as Receiving Antenna
  • The Linear Dipole Antenna as Receiving Antenna
  • Gain and Effective Antenna Aperture
  • Antenna Arrays
  • Linear Antenna Arrays
  • Circular Antenna Arrays
  • Aperture Antennas
  • Radiating Apertures
  • Horn Antennas
  • Gain and Effective Area of Aperture Antennas
  • Mirror and Lens Antennas
  • Slot Antennas
  • Microstrip Antennas
  • Planar Rectangular Patch Antenna
  • Broadband Antennas
  • Problems References
  • Chapter 14 Numerical Electromagnetics
  • Introduction
  • The Method of Moments
  • The Transmission-Line Matrix Method
  • The Mode Matching Method References
  • Appendix A Vectors and Differential Forms A Vectors A Differential Forms
  • Products of Exterior Differential Forms A The Contraction
  • The Exterior Derivative
  • The Laplace Operator
  • Stokes’ Theorem A Curvilinear Coordinates
  • General Cylindrical Coordinates A Circular Cylindric Coordinates A Spherical Coordinates
  • Twisted Forms
  • Integration of Differential Forms by Pullback
  • Double Differential Forms
  • Relations between Exterior Calculus and Conventional
  • Vector Notation A Differential Operators
  • Maxwell’s Equations
  • References
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Electromagnetics Microwave Circuit And Antenna Design for Communications Engineering by Peter Russer

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