Introduction To Modern Planar Transmission Lines Physical Analytical and Circuit Models Approach 1st Edition by Anand Verma 1119632474 9781119632474

Introduction To Modern Planar Transmission Lines Physical Analytical and Circuit Models Approach 1st Edition by Anand Verma – Ebook PDF Instant Download/DeliveryISBN:  1119632474, 9781119632474 

Full download Introduction To Modern Planar Transmission Lines Physical Analytical and Circuit Models Approach 1st Edition after payment.

Product details:

ISBN-10 :  1119632474 

ISBN-13 : 9781119632474

Author:  Anand Verma 

Provides a comprehensive discussion of planar transmission lines and their applications, focusing on physical understanding, analytical approach, and circuit models  Planar transmission lines form the core of the modern high-frequency communication, computer, and other related technology. This advanced text gives a complete overview of the technology and acts as a comprehensive tool for radio frequency (RF) engineers that reflects a linear discussion of the subject from fundamentals to more complex arguments.    Introduction to Modern Planar Transmission Lines: Physical, Analytical, and Circuit Models Approach begins with a discussion of waves on transmission lines and waves in material medium, including a large number of illustrative examples from published results. After explaining the electrical properties of dielectric media, the book moves on to the details of various transmission lines including waveguide, microstrip line, co-planar waveguide, strip line, slot line, and coupled transmission lines. A number of special and advanced topics are discussed in later chapters, such as fabrication of planar transmission lines, static variational methods for planar transmission lines, multilayer planar transmission lines, spectral domain analysis, resonators, periodic lines and surfaces, and metamaterial realization and circuit models.   Emphasizes modeling using physical concepts, circuit-models, closed-form expressions, and full derivation of a large number of expressions   Explains advanced mathematical treatment, such as the variation method, conformal mapping method, and SDA   Connects each section of the text with forward and backward cross-referencing to aid in personalized self-study  Introduction to Modern Planar Transmission Lines is an ideal book for senior undergraduate and graduate students of the subject. It will also appeal to new researchers with the inter-disciplinary background, as well as to engineers and professionals in industries utilizing RF/microwave technologies.

Introduction To Modern Planar Transmission Lines Physical Analytical and Circuit Models Approach 1st Table of contents:

1 Overview of Transmission Lines
Introduction
1.1 Overview of the Classical Transmission Lines
1.2 Planar Transmission Lines
1.3 Overview of Present Book
References
2 Waves on Transmission Lines – I
Introduction
2.1 Uniform Transmission Lines
2.2 Multisection Transmission Lines and Source Excitation
2.3 Nonuniform Transmission Lines
References
3 Waves on Transmission Lines – II
Introduction
3.1 Matrix Description of Microwave Network
3.2 Conversion and Extraction of Parameters
3.3 Wave Velocity on Transmission Line
3.4 Linear Dispersive Transmission Lines
References
4 Waves in Material Medium – I
Introduction
4.1 Basic Electrical Quantities and Parameters
4.2 Electrical Property of Medium
4.3 Circuit Model of Medium
4.4 Maxwell Equations and Power Relation
4.5 EM‐waves in Unbounded Isotropic Medium
4.6 Polarization of EM‐waves
4.7 EM‐waves Propagation in Unbounded Anisotropic Medium
References
5 Waves in Material Medium‐II
Introduction
5.1 EM‐Waves at Interface of Two Different Media
5.2 Oblique Incidence of Plane Waves
5.3 Special Cases of Angle of Incidence
5.4 EM‐Waves Incident at Dielectric Slab
5.5 EM‐Waves in Metamaterials Medium
References
6 Electrical Properties of Dielectric Medium
Introduction
6.1 Modeling of Dielectric‐Medium
6.2 Static Dielectric Constants of Materials
6.3 Dielectric Mixtures
6.4 Frequency Response of Dielectric Materials
6.5 Resonance Response of the Dielectric‐Medium
6.6 Interfacial Polarization
6.7 Circuit Models of Dielectric Materials
6.8 Substrate Materials for Microwave Planar Technology
References
7 Waves in Waveguide Medium
Introduction
7.1 Classification of EM‐Fields
7.2 Boundary Surface and Boundary Conditions
7.3 TEM‐Mode Parallel‐Plate Waveguide
7.4 Rectangular Waveguides
7.5 Conductor Backed Dielectric Sheet Surface Wave Waveguide
7.6 Equivalent Circuit Model of Waveguide
7.7 Transverse Resonance Method (TRM)
7.8 Substrate Integrated Waveguide (SIW)
References
8 Microstrip Line
Introduction
8.1 General Description
8.2 Static Closed‐Form Models of Microstrip Line
8.3 Dispersion in Microstrip Line
8.4 Losses in Microstrip Line
8.5 Circuit Model of Lossy Microstrip Line
References
9 Coplanar Waveguide and Coplanar Stripline
Introduction
9.1 General Description
9.2 Fundamentals of Conformal Mapping Method
9.3 Conformal Mapping Analysis of Coplanar Waveguide
9.4 Coplanar Stripline
9.5 Effect of Conductor Thickness on Characteristics of CPW and CPS Structures
9.6 Modal Field and Dispersion of CPW and CPS Structures
9.7 Losses in CPW and CPS Structures
9.8 Circuit Models and Synthesis of CPW and CPS
References
10 Slot Line
Introduction
10.1 Slot Line Structures
10.2 Analysis and Modeling of Slot Line
10.3 Waveguide Model
10.4 Closed‐form Models
References
Journals
Appendix – I
Appendix – II
11 Coupled Transmission Lines
Introduction
11.1 Some Coupled Line Structures
11.2 Basic Concepts of Coupled Transmission Lines
11.3 Circuit Models of Coupling
11.4 Even–Odd Mode Analysis of Symmetrical Coupled Lines
11.5 Wave Equation for Coupled Transmission Lines
References
12 Planar Coupled Transmission Lines
Introduction
12.1 Line Parameters of Symmetric Edge Coupled Microstrips
12.2 Line Parameters of Asymmetric Coupled Microstrips
12.3 Line Parameters of Coupled CPW
12.4 Network Parameters of Coupled Line Section
12.5 Asymmetrical Coupled Lines Network Parameters
References
13 Fabrication of Planar Transmission Lines
Introduction
13.1 Elements of Hybrid MIC (HMIC) Technology
13.2 Elements of Monolithic MIC (MMIC) Technology
13.3 Micromachined Transmission Line Technology
13.4 Elements of LTCC
References
14 Static Variational Methods for Planar Transmission Lines
Introduction
14.1 Variational Formulation of Transmission Line
14.2 Variational Expression of Line Capacitance in Fourier Domain
14.3 Analysis of Microstrip Line by Variational Method
14.4 Analysis of Multilayer Microstrip Line
14.5 Analysis of Coupled Microstrip Line in Multilayer Dielectric Medium
14.6 Discrete Fourier Transform Method
References
15 Multilayer Planar Transmission Lines
Introduction
15.1 SLR Process for Multilayer Microstrip Lines
15.2 SLR Process for Multilayer Coupled Microstrip Lines
15.3 SLR Process for Multilayer ACPW/CPW
15.4 Further Consideration of SLR Formulation
References
16 Dynamic Spectral Domain Analysis
Introduction
16.1 General Discussion of SDA
16.2 Green’s Function of Single‐Layer Planar Line
16.3 Solution of Hybrid Mode Field Equations (Galerkin’s Method in Fourier Domain)
16.4 Basis Functions for Surface Current Density and Slot Field
16.5 Coplanar Multistrip Structure
16.6 Multilayer Planar Transmission Lines
References
17 Lumped and Line Resonators
Introduction
17.1 Basic Resonating Structures
17.2 Zero‐Dimensional Lumped Resonator
17.3 Transmission Line Resonator
References
18 Planar Resonating Structures
Introduction
18.1 Microstrip Line Resonator
18.2 CPW Resonator
18.3 Slot Line Resonator
18.4 Coupling of Line Resonator to Source and Load
18.5 Coupled Resonators
18.6 Microstrip Patch Resonators
18.7 2D Fractal Resonators
18.8 Dual‐Mode Resonators
References
19 Planar Periodic Transmission Lines
Introduction
19.1 1D and 2D Lattice Structures
19.2 Space Harmonics of Periodic Structures
19.3 Circuit Models of 1D Periodic Transmission Line
19.4 1D Planar EBG Structures
References
20 Planar Periodic Surfaces
Introduction
20.1 2D Planar EBG Surfaces
20.2 Circuit Models of Mushroom‐Type EBG
20.3 Uniplanar EBG Structures
20.4 2D Circuit Models of EBG Structures
References
21 Metamaterials Realization and Circuit Models – I
Introduction
21.1 Artificial Electric Medium
21.2 Artificial Magnetic Medium
21.3 Double Negative Metamaterials
21.4 Homogenization and Parameters Extraction
References
22 Metamaterials Realization and Circuit Models – II
Introduction
22.1 Circuit Models of 1D‐Metamaterials
22.2 Nonresonant Microstrip Metalines
22.3 Resonant Metalines
22.4 Some Applications of Metalines
22.5 Modeling and Characterization of Metsurfaces
22.6 Applications of Metasurfaces

People also search for Introduction To Modern Planar Transmission Lines Physical Analytical and Circuit Models Approach 1st:

basic principle of transmission line
    
introduction of transmission line
    
how are transmission lines built
    
what are transmission lines
    
introduction to modern planar transmission lines pdf

Tags: Introduction, Modern Planar, Transmission, Physical, Analytical, Circuit Models, Anand Verma