Microwave Engineering: Concepts and Fundamentals

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Features Encompasses almost all aspects of microwave generation, measurements, and processing, giving each topic equal weight Describes ferrite devices, cavity resonators, semiconductor and RF/microwave devices, and microwave integrated circuits Provides a solid understanding of wave propagation, reflection and refraction, guided waves, and transmission lines Discusses different types of microwave components, antennas, tubes, transistors, diodes, and parametric devices Contains a myriad of illustrations, homework problems, references, and numerical examples Solutions manual and PowerPoint® slides available with qualifying course adoption Summary Detailing the active and passive aspects of microwaves, Microwave Engineering: Concepts and Fundamentals covers everything from wave propagation to reflection and refraction, guided waves, and transmission lines, providing a comprehensive understanding of the underlying principles at the core of microwave engineering. This encyclopedic text not only encompasses nearly all facets of microwave engineering, but also gives all topics—including microwave generation, measurement, and processing—equal emphasis. Packed with illustrations to aid in comprehension, the book: Describes the mathematical theory of waveguides and ferrite devices, devoting an entire chapter to the Smith chart and its applications Discusses different types of microwave components, antennas, tubes, transistors, diodes, and parametric devices Examines various attributes of cavity resonators, semiconductor and RF/microwave devices, and microwave integrated circuits Addresses scattering parameters and their properties, as well as planar structures including striplines and microstrips Considers the limitations of conventional tubes, behavior of charged particles in different fields, and the concept of velocity modulation Based on the author’s own class notes, Microwave Engineering: Concepts and Fundamentals consists of 16 chapters featuring homework problems, references, and numerical examples. PowerPoint® slides and MATLAB®-based solutions are available with qualifying course adoption.

Author(s): Ahmad Shahid Khan
Publisher: CRC Press
Year: 2014

Language: English
Pages: 770

Table of Contents

Preface

Introduction

Microwave Frequency Bands

Advantages

Components of Microwave System

Applications

Health Hazards

Fundamentals of Wave Propagation

Basic Equations and Parameters

Nature of Media

Wave in Lossless Media

Wave in Lossy Media

Conductors and Dielectrics

Polarisation

Depth of Penetration

Surface Impedance

Poynting Theorem

Reflection and Refraction

Direction Cosines, Wavelength and Phase Velocity

Classification of the Cases of Reflection

Normal Incidence Cases

Oblique Incidence

Parallel Plane Guide

Transverse Waves

Characteristics of TE and TM Waves

Transverse Electromagnetic Waves

Wave Impedances

Attenuation in the Walls of Parallel Plane Guide

Transmission Lines

Equations Governing Transmission Line Behaviour

Lossless RF and UHF Lines with Different Terminations

Reflection Phenomena

Resonance Phenomena in Line Sections

Quality Factor of a Resonant Section

UHF Lines as Circuit Elements

Applications of Transmission Lines

Types of Transmission Lines

Coaxial Cables

Limitations of Different Guiding Structures

Waveguides

Interrelation between Transmission Line and Waveguide

Rectangular Waveguide

Circular Waveguide

Dielectric Waveguides

Physical Interpretation of Wave Terminology

Relative Merits of Waveguides

Limitations of Waveguides

Cavity Resonators

Shapes and Types of Cavities

Cavity Formation

Fields in Cavity Resonators

Quality Factor

Coupling Mechanism

Tuning Methods

Advantages and Applications

Dielectric Resonators

Microwave Ferrite Devices

Ferrites

Faraday’s Rotation

Non-Reciprocal Ferrite Devices

Ferrite Phase Shifter

Ferrite Attenuators

Ferrite Switches

YIG Filters

Figures of Merit of Ferrite Devices

Smith Chart

Characteristic Parameters of a Uniform Transmission Line

Polar Chart

Smith Chart for Impedance Mapping

Smith Chart for Admittance Mapping

Information Imparted by Smith Chart

Advantages of Smith Chart

Smith Chart for Lossless Transmission Lines

Stub Matching

Components

Microwave Components

Waveguides and Its Accessories

Input–Output Methods in Waveguides

Coaxial to Waveguide Adapter

Waveguide Junctions

Directional Couplers

Waveguide Terminations

Attenuators

Impedance Matching

Tuners

Phase Shifters

Microwave Filters

Duplexers

Diplexers

Mode Suppressors

Scattering Parameters

Properties of Scattering Matrices

Scattering Parameters for Networks with Different Ports

Nature of Networks

Types of s-Parameters

Scattering Matrices for Some Commonly Used Microwave Components

Electrical Properties of 2-Port Networks

s-Parameters and Smith Chart

Scattering Transfer (or T) Parameters

Microwave Antennas

Antenna Theorems and Characteristic Parameters

Types of Microwave Antennas

Antenna Arrays

Microstrip Antennas

Microwave Measurements

Klystron Power Supply

VSWR Meter

Travelling Wave Detection

Qualities of Microwave Components and Devices

Precautions

Some Standard Norms

Measurement of Basic Quantities

Some Practical Applications

Basics of Microwave Tubes

Frequency Limitations of Conventional Tubes

Influence of Fields on Motion of Charged Particles

Velocity Modulation

Classification of Microwave Tubes

Microwave Tubes

Klystron

Two-Cavity Klystron

Reflex Klystron

Travelling-Wave Tube

Magnetron

Crossed-Field Amplifier

Backward-Wave Oscillators

Microwave Diodes

Basics of Semiconductor Devices

Conventional Diodes

Microwave Diodes

Transferred Electron Devices

Avalanche Transit Time Devices

Parametric Devices

Masers

Microwave Transistors

Transistors and Vacuum Tubes

Microwave Transistors

Field Effect Transistors

Metal-Oxide-Semiconductor Transistors

Memory Devices

Charge-Coupled Devices

Planar Transmission Lines

Striplines

Microstrips

Coplanar Waveguides

Coplanar Strips

Slot Line

Fin Lines

Micromachined Lines

Realisation of Lumped Elements

Realisation of Microwave Components

Microwave Integrated Circuits

Merits and Limitations of MICs

Types of MICs

Materials Used

Fabrication Techniques

Fabrication Processes

Illustration of Fabrication by Photo-Resist Technique

Fabrication of Devices

Appendices

Index