Жанры Авторы Контакты О сайте

Книжные новинки Популярные книги

Главная Авторы Anand K. Verma Introduction To Modern Planar Transmission Lines

Читать книгу Introduction To Modern Planar Transmission Lines - Anand K. Verma - Страница 1

Оглавление

Предыдущая Следующая

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 ...257

Оглавление

Introduction To Modern Planar Transmission Lines

Купить и скачать книгу Вернуться на страницу книги Introduction To Modern Planar Transmission Lines

Оглавление

Страница 1 Table of Contents List of Tables List of Illustrations Guide Pages Страница 7Страница 8Страница 9 Preface Страница 11Страница 12 1 Overview of Transmission Lines: (Historical Perspective, Overview of Present Book) Introduction Objectives 1.1 Overview of the Classical Transmission Lines 1.1.1 Telegraph Line 1.1.2 Development of Theoretical Concepts in EM‐Theory Electrostatics and Scalar Potential Magnetic Effect of Current Ohm's Law Electric Effect of the Time‐Varying Magnetic Field Concept of the Magnetic Vector Potential Maxwell's Dynamic Electromagnetic Theory Generation and Transmission of Electromagnetic Waves Further Information on Potentials EM‐Modeling of Medium 1.1.3 Development of the Transmission Line Equations Kelvin's Cable Theory Heaviside Transmission Line Equation 1.1.4 Waveguides as Propagation Medium 1.2 Planar Transmission Lines 1.2.1 Development of Planar Transmission Lines 1.2.2 Analytical Methods Applied to Planar Transmission Lines 1.3 Overview of Present Book 1.3.1 The Organization of Chapters in This Book Introductory Transmission Line and EM‐Wave Theory Basic Planar Lines and Resonators Analytical Methods Contemporary Engineered Planar Structures 1.3.2 Key Features, Intended Audience, and Some Suggestions Key Features Intended Audience Some Suggestions References Books Journals 2 Waves on Transmission Lines – I: (Basic Equations, Multisection Transmission Lines) Introduction Objectives 2.1 Uniform Transmission Lines 2.1.1 Wave Motion 2.1.2 Circuit Model of Transmission Line The Resistance of a Line The Inductance of a Line The Capacitance of a Line The Conductance of a Line 2.1.3 Kelvin–Heaviside Transmission Line Equations in Time Domain The Loop Equation The Node Equation 2.1.4 Kelvin–Heaviside Transmission Line Equations in Frequency‐Domain 2.1.5 Characteristic of Lossy Transmission Line Characteristic Impedance Propagation Constant 2.1.6 Wave Equation with Source Shunt Current Source The Loop Equation The Node Equation 2.1.7 Solution of Voltage and Current‐Wave Equation The Hyperbolic Form of a Solution Short‐Circuited Receiving End Open‐Circuited Receiving End Matched and Mismatched Termination Exponential Form of Solution 2.1.8 Application of Thevenin's Theorem to Transmission Line Transfer Function 2.1.9 Power Relation on Transmission Line Available Power from Generator 2.2 Multisection Transmission Lines and Source Excitation 2.2.1 Multisection Transmission Lines 2.2.2 Location of Sources Current Source at the Junction of Finite Length Line and Infinite Length Line Series Voltage Source 2.3 Nonuniform Transmission Lines 2.3.1 Wave Equation for Nonuniform Transmission Line 2.3.2 Lossless Exponential Transmission Line References Books Journals 3 Waves on Transmission Lines – II: (Network Parameters, Wave Velocities, Loaded Lines) Introduction Objectives 3.1 Matrix Description of Microwave Network 3.1.1 [Z] Parameters Example 3.1 Solution Example 3.2 Solution 3.1.2 Admittance Matrix Example 3.3 Solution Example 3.4 Solution 3.1.3 Transmission [ABCD] Parameter Example 3.5 Solution Example 3.6 Solution Example 3.7 Solution 3.1.4 Scattering [S] Parameters Basic Concept Scattering [S] Matrix Reflection Coefficient S_ii Transmission Coefficient S_ij Properties of [S] Matrix Reciprocity Property Unitary Property Phase Shift Property Example 3.8 Solution Example 3.9 Solution Example 3.10 Solution Example 3.11 Solution 3.2 Conversion and Extraction of Parameters 3.2.1 Relation Between Matrix Parameters [Z] and [ABCD] Parameters [S] and [Z] Parameters [ABCD] and [S] Parameters 3.2.2 De‐Embedding of True S‐Parameters 3.2.3 Extraction of Propagation Characteristics 3.3 Wave Velocity on Transmission Line 3.3.1 Phase Velocity 3.3.2 Group Velocity Formation of Two‐Frequency Wave‐Packet 3.4 Linear Dispersive Transmission Lines 3.4.1 Wave Equation of Dispersive Transmission Lines 3.4.2 Circuit Models of Dispersive Transmission Lines Shunt Inductor Loaded Line Backward Wave Supporting Line Series Connected Parallel L_sh‐C Type Line Series Capacitor Loaded LC‐Line References Books Journals 4 Waves in Material Medium – I: (Waves in Isotropic and Anisotropic Media, Polarization of Waves) Introduction Objectives 4.1 Basic Electrical Quantities and Parameters 4.1.1 Flux Field and Force Field Gauss’s Law for Electric Flux Gauss’s Law for Magnetic Flux 4.1.2 Constitutive Relations 4.1.3 Category of Materials Dielectric Materials Magnetic Materials Conductors 4.2 Electrical Property of Medium 4.2.1 Linear and Nonlinear Medium 4.2.2 Homogeneous and Nonhomogeneous Medium 4.2.3 Isotropic and Anisotropic Medium Symmetric Anisotropic Materials Anti‐symmetric Anisotropic Materials Gyroelectric Medium Gyromagnetic Medium Magneto‐dielectric Composite Materials Magnetoelectric Materials 4.2.4 Nondispersive and Dispersive Medium 4.2.5 Non‐lossy and Lossy Medium 4.2.6 Static Conductivity of Materials 4.3 Circuit Model of Medium 4.3.1 RC Circuit Model of Lossy Dielectric Medium 4.3.2 Circuit Model of Lossy Magnetic Medium 4.4 Maxwell Equations and Power Relation 4.4.1 Maxwell’s Equations 4.4.2 Power and Energy Relation from Maxwell Equations 4.5 EM‐waves in Unbounded Isotropic Medium 4.5.1 EM‐wave Equation 4.5.2 1D Wave Equation 4.5.3 Uniform Plane Waves in Linear Lossless Homogeneous Isotropic Medium 4.5.4 Vector Algebraic Form of Maxwell Equations 4.5.5 Uniform Plane Waves in Lossy Conducting Medium 4.6 Polarization of EM‐waves 4.6.1 Linear Polarization 4.6.2 Circular Polarization 4.6.3 Elliptical Polarization 4.6.4 Jones Matrix Description of Polarization States Jones Vector Jones Matrix Jones Matrix of Linear Polarizer Jones Matrix of a Linear Polarizer Rotated at Angle θ with the y‐Axis Transformation of E‐vector Components Transformation of Jones Matrix of Polarizer Jones Matrix for Retarder (Phase Shifter) Jones Matrix of Half‐waveplate Jones Matrix of Quarter‐waveplate 4.7 EM‐waves Propagation in Unbounded Anisotropic Medium 4.7.1 Wave Propagation in Uniaxial Medium Waveplates and Phase Shifters 4.7.2 Wave Propagation in Uniaxial Gyroelectric Medium 4.7.3 Dispersion Relations in Biaxial Medium 4.7.4 Concept of Isofrequency Contours and Isofrequency Surfaces 4.7.5 Dispersion Relations in Uniaxial Medium References Books Journals 5 Waves in Material Medium‐II: (Reflection & Transmission of Waves, Introduction to Metamaterials) Introduction Objectives 5.1 EM‐Waves at Interface of Two Different Media 5.1.1 Normal Incidence of Plane Waves 5.1.2 The Interface of a Dielectric and Perfect Conductor 5.1.3 Transmission Line Model of the Composite Medium 5.2 Oblique Incidence of Plane Waves 5.2.1 TE (Perpendicular) Polarization Case The Oblique Incidence on a Perfect Electric Conductor 5.2.2 TM (Parallel) Polarization Case The Oblique Incidence on a Perfect Electric Conductor 5.2.3 Dispersion Diagrams of Refracted Waves in Isotropic and Uniaxial Anisotropic Media 5.2.4 Wave Impedance and Equivalent Transmission Line Model Formulation of Transmission Line Model Correspondence between Wave Impedance and Characteristic Impedance Refection/Transmission Coefficients at Media Interface and Lines Junction Computation of Reflection and Transmission Coefficients 5.3 Special Cases of Angle of Incidence 5.3.1 Brewster Angle TE‐Polarization TM‐Polarization 5.3.2 Critical Angle Case #1: θ₁ < θ_c Case#2: θ₁ = θ_c Case#3: θ₁ > θ_c TE Polarization TM Polarization 5.4 EM‐Waves Incident at Dielectric Slab 5.4.1 Oblique Incidence 5.4.2 Normal Incidence 5.5 EM‐Waves in Metamaterials Medium 5.5.1 General Introduction of Metamaterials and Their Classifications 5.5.2 EM‐Waves in DNG Medium Lossless DNG Medium Refractive Index of DNG Medium Wave Impedance of DNG and SNG Media Negative Refraction in DPS‐DNG Composite Medium 5.5.3 Basic Transmission Line Model of the DNG Medium 5.5.4 Lossy DPS and DNG Media 5.5.5 Wave Propagation in DNG Slab Phase – Compensation in the DPS‐DNG Slab Amplitude‐Compensation in the DNG Slab 5.5.6 DNG Flat Lens and Superlens Veselago Flat Lens Pendry Superlens Lens HyperLens 5.5.7 Doppler and Cerenkov Radiation in DNG Medium Doppler Effect Inverse Doppler Effect Cerenkov Radiation Inverse Cerenkov Radiation 5.5.8 Metamaterial Perfect Absorber (MPA) Salisbury Absorber Metasurface Absorber DNG Slab Absorber Lossy DNG Slab with Conductor Backing Lossy DNG Slab Without Conductor Backing References Books Journals {buyButton}

Подняться наверх

Популярные жанры Детективы Классика Искусство Психология Наука и образование Фантастика Фэнтези

Книжные новинки Популярные книги Жанры Авторы Контакты О сайте

© КнигаЛит.ру 2015 - 2024. Рейтинг книг, рецензии и отзывы о бумажных и электронных книгах, сравнение цен на книги в магазинах.

На нашем сайте вы можете скачать бесплатно и читать бесплатно онлайн фрагмент интересующего вас произведения, заказать и купить бумажную книгу с доставкой в книжных интернет-магазинах, или электронную книгу в одном из популярных форматов для чтения на ридере, мобильном устройстве и ПК. Подробнее о сайте.