Microwave Engineering: Fundamentals, Design and Applications, Second Edition, emphasises the basic concepts, design techniques and applications of microwave engineering in a markedly different manner. Based on feedback from students and faculty, this new edition fully covers the latest AICTE syllabus for Electronics and Communication Engineering (ECE) students. It also covers the syllabus of most universities abroad, for graduate as well as post-graduate courses of ECE.
Subal Kar is former Professor and Head of the Institute of Radio Physics and Electronics, University of Calcutta. His fields of specialisation cover microwave and millimetre-wave devices and circuits, metamaterials, THz imaging, optical communication and high energy physics. He has published a large number of research papers in international journals, contributed chapters in edited books, authored another textbook and has three patents to his credit. Dr Kar was visiting scientist to Kyoto University, Japan (1997), Lawrence Berkeley National Laboratory, USA (1999–2000), Oxford University, UK (2013) as well as to other Institutes and Universities in Europe and the USA. Dr Kar received the Young Scientist Award of URSI and IEEE MTT as well as the Fulbright Award of the USA Government. He is a Fulbright Fellow, Senior Member of IEEE, Fellow of IETE and Fellow VEDA Society.
Foreword Preface to the Second Edition Preface to the First Edition Chapter 1 Introduction 1.1 Microwaves and Their Applications 1.2 Importance of Microwaves 1.3 Why is ‘Microwaves’ a Special Subject? 1.4 A Brief History of the Development of Microwave Engineering Review Questions Chapter 2 Electromagnetics Revisited 2.1 Introduction 2.2 Time-varying Fields and Maxwell’s Equations 2.3 The Wave Equation and Plane Electromagnetic Waves in Unbounded Media 2.4 Electromagnetic Wave Propagation in Material Media 2.4.1 Principle of Dielectric Heating and Microwave Oven 2.5 Electromagnetic Power Flow and Poynting Vector 2.6 Polarisation of Electromagnetic Wave 2.7 Wave Propagation in Interfacing Media 2.7.1 Electromagnetic Boundary Conditions 2.7.2 Reflection and Transmission of Waves for Normal and Oblique Incidence 2.7.2.1 Normal incidence on plane boundaries 2.7.2.2 Oblique incidence on plane boundaries 2.8 Radiation of Electromagnetic Waves and Antennae 2.8.1 Retarded Vector Potential for Antenna Analysis 2.8.2 Antenna Characteristic Parameters Review Questions Numerical Problems Chapter 3 High Frequency Behaviour of Transmission Lines 3.1 Introduction 3.2 Analysis of HF Transmission Lines 3.2.1 Transmission Line Equations 3.2.2 Characteristic Parameters of HF Transmission Lines 3.2.3 Terminated HF Transmission Lines 3.2.4 Transmission Line as HF Circuit Elements 3.3 Smith Chart and its Applications 3.4 Planar Transmission Lines 3.4.1 Microstrip Line 3.4.1.1 Even and odd mode in coupled transmission lines 3.4.2 Variants of Microstrip Line 3.4.2.1 Inverted microstrip and trapped inverted microstrip 3.4.3 Slot-line 3.4.4 Coplanar-line 3.4.5 Fin-line 3.4.6 Dielectric integrated guide Review Questions Numerical Problems Chapter 4 Guided Structures: Waveguides and Cavity Resonators 4.1 Introduction 4.2 Rectangular Waveguide 4.2.1 Transverse Electric (TE)-mode/H-wave 4.2.2 Transverse Magnetic (TM)-mode/E-wave 4.2.3 TE-mode vs TM-mode and the Dominant Mode 4.2.4 Field Patterns in a Rectangular Waveguide 4.2.5 Wave Dispersion and Wave Velocities 4.2.6 Choice of Waveguide Dimensions and Characteristics of Standard Rectangular Waveguides 4.2.7 Launching of Modes in Rectangular Waveguides 4.2.8 Power Handling Capacity of a Rectangular Waveguide 4.2.9 Attenuation Due to Losses in a Rectangular Waveguide 4.3 Circular Waveguide 4.3.1 TM and TE Modes in Circular Guides 4.3.2 Launching of Modes in Circular Waveguides 4.3.3 Characteristics of Standard Circular Waveguides 4.3.4 Attenuation in Circular Waveguides 4.4 Cavity Resonators 4.4.1 Rectangular Cavity Resonator 4.4.2 The Quality Factor (Q) of the TE101 Cavity Mode 4.4.3 Cylindrical Cavity Resonator 4.4.4 The Quality Factor (Q) of the TE011 Cavity Mode 4.4.5 Mode Chart 4.5 Strip/Disc Resonator 4.6 Dielectric Resonator 4.7 Coupling and Tuning of Microwave Resonators Review Questions Numerical Problems Chapter 5 Microwave Network and Scattering Matrix 5.1 Introduction 5.2 S-parameter Formulation of Microwave Network 5.3 Properties of S-parameters 5.4 Signal Flow Graphs: Decomposition Rules and Mason’s Rule Review Questions Chapter 6 Microwave Passive Circuit Components 6.1 Introduction 6.2 Waveguide and Planar Transmission Line Based Components 6.2.1 Terminations 6.2.2 Tee-Junctions and Hybrids 6.2.3 Tuners 6.2.4 Directional Coupler 6.2.5 Attenuator 6.2.6 Isolator 6.2.7 Circulator 6.2.8 Phase Shifter 6.2.9 Bends and Corners 6.2.10 Waveguide Twist, Transitions and Adaptor 6.2.11 Flanges and Connectors 6.3 Lumped-circuit Elements at Microwave Frequency 6.4 Distributed-circuit Elements Using Microstrip Transmission Line 6.5 S-Matrix of Microwave Components 6.5.1 S-matrix of Directional Coupler 6.5.2 S-matrix of Magic Tee 6.5.3 S-matrix of Circulator Review Questions Chapter 7 Impedance Matching in Transmission Lines and Waveguides 7.1 Introduction 7.2 Stub Matching 7.2.1 Single Stub Matching 7.2.2 Double Stub Matching 7.2.3 Smith Chart Technique for Solving Stub Matching Problems 7.3 Impedance Transformers 7.3.1 Frequency Response of Quarter-Wave Transformer 7.3.2 Theory of Small Reflections 7.3.2.1 Binomial stepped impedance transformer 7.3.2.2 Tchebyscheff stepped impedance transformer 7.3.2.3 Tapered impedance matching transformers 7.4 Inductive/Capacitive Windows (iris) and Matching Screws in Waveguide 7.5 Impedance Matching with Lumped Component/Planar Distributed Line Reactive Elements Review Questions Numerical Problems Chapter 8 Microwave Filters 8.1 Introduction 8.2 Insertion-loss Method for Low-pass Prototype Design 8.2.1 Low-pass Prototype Filter Design Technique 8.3 Filter Transformations from Prototype 8.3.1 Prototype to Actual Low-pass Transformation 8.3.2 Low-pass Prototype to High-pass Transformation 8.3.3 Low-pass to Band-pass and Band-stop Transformations 8.4 Microwave Implementation 8.4.1 Richard’s Transformation 8.4.2 Kuroda’s Identities 8.4.3 Impedance and Admittance Inverters 8.5 Practical Microwave Filters—Analysis and Design 8.5.1 Stepped-impedance (High–Low) Low-pass Filter 8.5.2 Coupled-line Band-pass Filter 8.5.3 Coupled-resonator Band-stop Filter Review Questions Numerical Problems Chapter 9 Microwave Tube Devices 9.1 Introduction 9.2 Linear Beam Tubes 9.2.1 Klystron 9.2.1.1 Two cavity/multi-cavity klystron amplifier 9.2.1.2 Reflex klystron oscillator 9.2.2 Travelling-wave tube 9.2.2.1 Principle of operation 9.2.2.2 Analytical derivations for TWT amplifier: 9.3 Crossed-field tubes 9.3.1 Magnetron 9.3.1.1 Principle of operation 9.3.1.2 Analysis of cylindrical magnetron 9.3.1.3 Practical considerations 9.3.2 Pulsing of Magnetron with Pulse Forming Network (PFN) 9.3.3 Coaxial Magnetron 9.4 Fast-Wave Electron Tubes 9.4.1 Gyrotron 9.4.1.1 Principle of operation 9.4.1.2 Analytical derivations for gyrotron 9.4.1.3 Gyromonotron or gyrotron oscillator Review Questions Numerical Problems Chapter 10 Solid-State and Quantum Electronic Devices at Microwave Frequencies 10.1 Microwave Solid-state Devices 10.1.1 Introduction 10.1.2 Microwave Solid-State Diodes 10.1.2.1 Schottky diode, tunnel diode 10.1.2.2 PIN diode and its applications 10.1.2.3 Transferred electron device (Gunn diode) 10.1.2.4 Avalanche transit-time device (IMPATT diode) 10.1.3 Microwave Transistors 10.1.3.1 MESFET and HEMT devices 10.1.3.2 HBT device 10.2 Quantum Electronic Microwave Device—MASER Review Questions Numerical Problems Chapter 11 Microwave Oscillators, Amplifiers and Power Combiners with Solid-state Devices 11.1 Introduction 11.2 Oscillator/Amplifier with Two-terminal Device (Diode) 11.2.1 Fundamental Theoretical Background of MicrowaveDiode Oscillator/Amplifier 11.2.2 Oscillator/Amplifier Configurations with IMPATT/Gunn Diodes 11.2.3 IMPATT Oscillator and VCO Design with 3D Electromagnetic Field Simulator 11.3 Amplifier/Oscillator with Three-terminal Microwave Device (Transistor) 11.3.1 Fundamental Theoretical Background of Transistor Amplifier/Oscillator 11.3.2 Low-noise Amplifier vs Power Amplifier 11.3.3 Design of LNA and PA using EDA Simulation Tool 11.3.4 Broadband Transistor Amplifiers at Microwave Frequency 11.3.5 Dielectric Resonator (DR) Based Transistor Oscillator 11.4 Power Combiners with IMPATT/Gunn Diodes Review Questions Chapter 12 Microwave Mixers 12.1 Introduction 12.2 Diode-based Microwave Mixers 12.2.1 Single Device/Single-ended Diode Mixer 12.2.2 Balanced Mixer with Diode 12.2.3 Subharmonically Pumped Mixer 12.3 Transistor-based Microwave Mixers 12.4 Image-rejection Mixer 12.5 Distributed Mixers 12.6 Mixer Design using EDA Simulation Tool Review Questions Chapter 13 Microwave Antennae and Wave Propagation 13.1 Introduction 13.2 Principle of Operation and Performance Parameters of Conventional Microwave Antennae 13.2.1 Horn Antenna 13.2.2 Reflector Antenna 13.2.2.1 Feed mechanism for parabolic antennae 13.2.2.2 Fan-beam with parabolic antenna 13.2.3 Slot Antenna 13.2.4 Lens Antenna 13.2.5 Surface Wave (Dielectric Rod) Antenna 13.3 Microstrip Patch Antenna 13.4 Dielectric Resonator Antenna 13.5 Principle of Microwave Signal Propagation 13.5.1 Line-of-Sight (LOS) Propagation 13.5.2 Atmospheric Duct Propagation 13.5.3 Troposperic Propagation 13.5.4 Fading and its Mitigation Review Questions Chapter 14 Radar and Radio-aids to Navigation 14.1 Introduction 14.2 Radar Range Performance Equation 14.2.1 Introduction 14.2.2 Primary Radar Range Equation 14.2.2.1 Comments from range equation 14.2.3 Effect of Noise on Range Equation 14.2.4 The Generation of Echo Signal in Primary Radar 14.2.5 Secondary (Beacon) Radar Range Equation 14.3 Pulse and CW Radar 14.3.1 Introduction 14.3.2 Maximum Unambiguous Range and Minimum Range Resolution of Pulse Radar 14.3.3 Bandwidth Requirement of Pulse and CW Radar 14.3.4 System Block Diagram of Pulse Radar 14.4 Radar Cross-section of Targets and Radar Clutter 14.4.1 Radar Cross-section of Targets 14.4.2 Radar Clutter 14.5 CW and FM–CW radar 14.5.1 Introduction 14.5.2 Doppler Effect in Radar 14.5.3 Principle of FM–CW Radar 14.5.4 System Block Diagram of CW and FM–CW Radar 14.6 Pulse Doppler and MTI Radar 14.6.1 Introduction 14.6.2 MTI Radar Principle 14.6.3 MTI Radar System Block Diagram 14.6.4 Blind Speed and Multiple Staggered PRF to Mitigate the Effect of Blind Speed 14.7 Surveillance and Tracking Radar 14.7.1 Introduction 14.7.2 Effect of Scanning on Range Performance 14.7.3 Tracking Radar Principle and Techniques 14.8 Special Radar Techniques—Synthetic Aperture and Pulse Compression Radar 14.8.1 Synthetic Aperture Radar 14.8.2 Pulse Compression Radar 14.9 Radio-aids to Navigation 14.9.1 Introduction 14.9.2 Conventional RAN Systems 14.9.2.1 Direction finder (DF) 14.9.2.2 Very High Frequency (VHF) Omni-directional Range (VOR) 14.9.2.3 Distance Measuring Equipment (DME) and TACtical Air Navigation (TACAN) 14.9.2.4 Instrument Landing System (ILS)/Microwave Landing System (MLS) 14.9.2.5 Hyperbolic navigation systems 14.9.3 Satellite-based Navigation and Global Positioning System (GPS) 14.9.3.1 Global Positioning System (GPS) Review Questions Numerical Problems Chapter 15 Microwave Measurement Techniques 15.1 Introduction 15.2 Impedance Measurement at Microwave Frequencies 15.2.1 SWD Technique of Impedance Measurement 15.2.2 Reflectometer Technique of Impedance Measurement 15.2.3 Bridge Technique of Impedance Measurement 15.3 Detection and Measurement of Power at Microwave Frequencies 15.3.1 Microwave Power Detector 15.3.2 Bolometer Technique of Microwave Power Measurement 15.3.3 Microwave Power Meter 15.3.4 Peak Power Measurement 15.4 Measurement of Quality Factor (Q) of Microwave Cavities 15.4.1 VSWR or Impedance Method of Q Measurement 15.4.2 Transient Decay or Decrement Method 15.4.3 Dynamic Methods of Q measurement 15.5 Microwave Frequency Measurement 15.5.1 Mechanical Technique of Frequency Measurement—Wavemeter 15.5.2 Electronic Technique of Frequency Measurement—Frequency Counter 15.6 Antenna Measurement at Microwave Frequency 15.6.1 Horn Antenna Measurement 15.7 Measurement of Dielectric Constant and Loss Factor of Materials at Microwave Frequencies 15.8 Measurement of Noise Figure and Phase-noise 15.8.1 Noise Figure and its Measurement 15.8.2 Phase Noise and its Characterisation for Microwave Oscillators 15.9 Fundamentals of Spectrum Analyser and Network Analyser 15.9.1 Spectrum Analyser 15.9.1.1 Introduction 15.9.1.2 Basic principle and block diagram of spectrum analyser 15.9.1.3 A few passing comments 15.9.2 Network Analyser 15.9.2.1 Introduction 15.9.2.2 Block diagram to understand VNA operation 15.9.2.3 VNA calibration Review Questions Chapter 16 Microwave Integrated Circuits 16.1 Introduction 16.2 HMIC vs MMIC 16.3 Fabrication Process Steps of HMIC and MMIC 16.3.1 HMIC Fabrication 16.3.2 MMIC Fabrication 16.4 Materials for HMIC and MMIC Fabrication 16.4.1 Substrate Materials 16.4.2 Conductor Dielectric and Resistive Materials 16.5 Fabrication Processes Related with HMIC and MMIC 16.5.1 Diffusion, Ion-implantation and Epitaxial Techniques 16.5.2 Masked Lithography and Mask-less Lithography 16.5.3 Thick and Thin-film Technology Review Questions Chapter 17 Electromagnetic Interference (EMI) and Electromagnetic Compatibility (EMC) 17.1 Introduction 17.2 Causes and Case Studies for EMI 17.3 Electromagnetic Compatibility (EMC) 17.4 RF/Microwave Shielding for EMI/EMC 17.4.1 Introduction 17.4.2 Physical Understanding of RF Shielding 17.4.3 Qualitative and Quantitative Analysis of RF Shield and Shielding Effectiveness 17.4.4 Issues Affecting the Shielding Effectiveness and their Mitigation 17.5 EMI/EMC Standards, Regulations and Testing 17.6 Human Exposure Limit to Electromagnetic Radiation Review Questions Chapter 18 An Emerging Topic of Microwave Engineering: Metamaterials and Metasurfaces 18.1 Introduction 18.2 Counter-intuitiveness of LHM 18.3 Plasmonic and Transmission Line Metamaterials 18.3.1 Plasmonic Metamaterials 18.3.1.1 Negative permittivity with thin-wire (TW) and cut-wire (CW) 18.3.1.2 Negative permeability with split-ring resonator (SRR) 18.3.2 Transmission Line Metamaterials 18.3.2.1 CRLH transmission line characteristics and ZOR 18.3.2.2 Design of unit cell of CRLH 18.4 Properties of Electromagnetic Signal Propagation Through LHM 18.5 Metamaterial-inspired Microwave Components and Antennae 18.5.1 CSRR Loaded Microstrip Patch Antenna Design 18.5.2 CRLH Based Microwave Filter Design 18.6 Problems and Possibilities of Terahertz and Optical Metamaterials 18.7 Metamaterials: Application Scenario, Challenges and Possibilities 18.8 Metasurfaces or 2D Metamaterials Review Questions Chapter 19 Applications of Microwave Engineering 19.1 Introduction 19.2 Microwave Engineering in Communication Applications 19.2.1 Broadband Microwave Access for Mobile Communications 19.2.2 Microwave Communication Links 19.2.3 Microwave Remote Sensing 19.3 Industrial Applications of Microwaves 19.3.1 Drying 19.3.2 Vulcanisation 19.3.3 Thickness Monitoring of Metal/Dielectric Sheets in Rolling Mills 19.4 Microwaves in Medical Applications 19.4.1 Microwave Hyperthermia and Microwave Ablation 19.4.1.1 Microwave hyperthermia 19.4.1.2 Microwave ablation 19.5 Microwave Cooking: Design and Usage of Microwave Oven 19.6 Microwave/RF Life-detection Systems 19.7 Some Emerging Applications of Microwave Engineering 19.7.1 Radio-Frequency Identification (RFID) System 19.7.2 RF MEMS for Microwave Components 19.7.3 Microwave and Terahertz Imaging 19.7.3.1 Microwave imaging 19.7.3.2 Terahertz (THz) imaging Review Questions Appendix: Useful Formulae and Tables for Microwave Engineering Bibliography Further Reading Index