Description
Wiley Microwave Engineering An Indian Adaptation Theory and Techniques 2020 Edition by David M. Pozar
Microwave Engineering: Theory and Techniques is a self-sustaining literature for an undergraduate aswell as a graduate program on the principles of microwave engineering. The book provides a comprehensive discourse of the fundamentals of the subject and design principles as applied to modern RF and microwave engineering. Starting with the fundamental principles of electromagnetic theory, the book goes on to cover microwave network analysis, impedance matching, directional couplers and hybrids, microwave filters, ferrite devices, noise, nonlinear effects, and the design of microwave oscillators, amplifiers, and mixers. Material on microwave and RF systems includes wireless communication, radar, radiometry, and radiation hazards. About the AuthorDavid Pozar is professor of Electrical and Computer Engineering at University of Massachusetts, Amherst. He has received numerous awards both for his teaching and for his research, including an IEEE Third Millenium award. Dr. Pozar is acknowledged as a leading figure in Microwave and RF circuit design research. Table of Contents : - Chapter 1 REVIEW OF ELECTROMAGNETIC THEORY 1.1 Introduction to Microwave Engineering 1.2 Maxwell’s Equations 1.3 Fields in Media and Boundary Conditions1.4 The Wave Equation and Basic Plane Wave Solutions 1.5 General Plane Wave Solutions 1.6 Energy and Power1.7 Plane Wave Reflection from a Media Interface1.8 Oblique Incidence at a Dielectric Interface1.9 Some Useful Theorems Chapter 2 TRANSMISSION LINE THEORY2.1 The Lumped-Element Circuit Model for a Transmission Line 2.2 Field Analysis of Transmission Lines2.3 The Terminated Lossless Transmission Line2.4 The Smith Chart2.5 Generator and Load Mismatches2.6 Lossy Transmission Lines2.7 Transients on Transmission Lines Chapter 3 TRANSMISSION LINES AND WAVEGUIDES3.1 General Solutions for TEM, TE, and TM Waves3.2 Parallel Plate Waveguide3.3 Rectangular Waveguide3.4 Circular Waveguide3.5 Coaxial Line3.6 Surface Waves on a Grounded Dielectric Sheet3.7 Stripline3.8 Microstrip Line3.9 The Transverse Resonance Technique3.10 Wave Velocities and Dispersion3.11 Summary of Transmission Lines and Waveguides Chapter 4 MICROWAVE NETWORK ANALYSIS4.1 Impedance and Equivalent Voltages and Currents4.2 Impedance and Admittance Matrices4.3 The Scattering Matrix4.4 The Transmission (ABCD) Matrix4.5 Signal Flow Graphs4.6 Discontinuities and Modal Analysis 4.7 Excitation of Waveguides—Electric and Magnetic Currents Chapter 5 IMPEDANCE MATCHING AND TUNING5.1 Matching with Lumped Elements (L Networks)5.2 Single-Stub Tuning5.3 Double-Stub Tuning5.4 The Quarter-Wave Transformer5.5 The Theory of Small Reflections5.6 Binomial Multisection Matching Transformers5.7 Chebyshev Multisection Matching Transformers5.8 Tapered Lines Chapter 6 MICROWAVE RESONATORS6.1 Series and Parallel Resonant Circuits6.2 Transmission Line Resonators6.3 Rectangular Waveguide Cavity Resonators6.4 Circular Waveguide Cavity Resonators6.5 Dielectric Resonators6.6 Excitation of Resonators Chapter 7 POWER DIVIDERS AND DIRECTIONAL COUPLERS7.1 Basic Properties of Dividers and Couplers7.2 The T-Junction Power Divider7.3 The Wilkinson Power Divider7.4 Waveguide Directional Couplers7.5 The Quadrature (90◦) Hybrid7.6 Coupled Line Directional Couplers7.7 The Lange Coupler7.8 The 180◦ Hybrid7.9 Other Couplers Chapter 8 MICROWAVE FILTERS 8.1 Periodic Structures8.2 Filter Design by the Image Parameter Method8.3 Filter Design by the Insertion Loss Method8.4 Filter Transformations8.5 Filter Implementation8.6 Stepped-Impedance Low-Pass Filters8.7 Coupled Line Filters Chapter 9 THEORY AND DESIGN OF FERRIMAGNETIC COMPONENTS9.1 Basic Properties of Ferrimagnetic Materials9.2 Plane Wave Propagation in a Ferrite Medium9.3 Propagation in a Ferrite-Loaded Rectangular Waveguide9.4 Ferrite Isolators9.5 Ferrite Phase Shifters 9.6 Ferrite Circulators Chapter 10 NOISE AND NONLINEAR DISTORTION10.1 Noise in Microwave Circuits10.2 Noise Figure10.3 Nonlinear Distortion10.4 Precipitation Titrations Chapter 11 ACTIVE RF AND MICROWAVE DEVICES11.1 Diodes and Diode Circuits11.2 Bipolar Junction Transistors11.3 Field Effect Transistors11.4 Microwave Integrated Circuits11.5 Microwave Tubes Chapter 12 MICROWAVE AMPLIFIER DESIGN 12.1 Two-Port Power Gains12.2 Stability12.3 Single-Stage Transistor Amplifier Design12.4 Broadband Transistor Amplifier Design12.5 Power Amplifiers Chapter 13 OSCILLATORS AND MIXERS13.1 RF Oscillators13.2 Microwave Oscillators13.3 Oscillator Phase Noise 13.4 Frequency Multipliers13.5 Mixers Chapter 14 INTRODUCTION TO MICROWAVE SYSTEMS14.1 System Aspects of Antennas14.2 Wireless Communication14.3 Radar Systems14.4 Radiometer Systems14.5 Microwave Propagation14.6 Other Applications and Topics ReferencesProblemsMultiple Choice Questions AppendicesAppendix A PrefixesAppendix B Vector AnalysisAppendix C Bessel FunctionsAppendix D Useful ResultsAppendix E Other Mathematical ResultsAppendix F Physical ConstantsAppendix G Conductivities for Some MaterialsAppendix H Dielectric Constants and Loss Tangents for Some MaterialsAppendix I Properties of Some Microwave Ferrite MaterialsAppendix J Standard Rectangular Waveguide DataAppendix K Standard Coaxial Cable DataANSWERS TO SELECTEDPROBLEMS