Microwave Engineering, 4th Edition
Microwave Engineering, 4th Edition
ISBN: 978-0-470-63155-3 November 2011 752 Pages
Table of contents
Chapter 2. Transmission Line Theory
Chapter 3. Transmission Lines and Waveguides
Chapter 4. Microwave Network Analysis
Chapter 5. Impedance Matching and Tuning
Chapter 6. Microwave Resonators
Chapter 7. Power Dividers and Directional Couplers
Chapter 8. Microwave Filters
Chapter 9. Theory and Design of Ferromagnetic Components
Chapter 10. Noise and Active RF Components
Chapter 11. Microwave Amplifier Design. Active RF and Microwave Devices
Chapter 12. Oscillators and Mixers Microwave Amplifier Design
Chapter 13. Introduction to Microwave Systems Oscillators and Mixers
Chapter 14: Introduction to Microwave Systems
Appendix A. Prefixes
Appendix B. Vector Analysis
Appendix C. Bessel Functions
Appendix D. Other Mathematical Results
Appendix E. Physical Constants
Appendix F. Conductivities for Some Materials
Appendix G. Dielectric Constants and Loss Tangents for Some Materials
Appendix H. Properties of Some Microwave Ferrite Materials
Appendix I. Standard Rectangular Waveguide Data
Appendix J. Standard Coaxial Cable Data
Answer to Selected Problems
New To This Edition
- New material has been introduced on microwave and RF systems, and how components are linked to system performance (e.g., noise figure, effect on Bit Error Rate, link margin, cell phones, etc.)
- More coverage of active circuits has been included (CMOS circuits, SiGe circuits, Power Added Efficiency, Gilbert cell mixer, etc.)
- Additional topics (power waves, transients, frequency dependent effects of microstrip line, and more) and more open-ended EOC problems have been added.
- Number of chapters has been increased from 13 to 14, with more emphasis on noise, nonlinear effects, and active circuit design.
- Material on the following topics has been substantially revised: noise and noise effects, intermodulation distortion, dynamic range, mixers, amplifier stability, antennas and antenna noise, wireless receivers, and characteristics of diodes and transistors.
- Numerous new or revised examples and problems have been added, with many of these related to practical design problems involving planar circuits and components.
- Thorough analysis and development based on fundamental principles. Students develop understanding of core concepts and learn that the operation of microwave circuits and devices can be explained through the use of circuit theory, Maxwell's equations, and related fundamentals. See Wilkinson divider operation derived from basic circuit and transmission line theory.
- Many examples cover both theory and design. Student can see how typical problems are solved, how practical designs are carried out, and how component designs perform. The availability of realistic and thorough examples reinforces subject matter. See Example 7.7 that involves the design of a coupled line coupler on a lossy substrate. The design procedure is illustrated, and the response of the coupler is obtained using a CAD package.
- Many problems cover both theory and design. Problems test the student's understanding of the material and offer the opportunity for in-depth design and analysis of practical components. Problems offer students real-life design practice with the quick feedback of CAD tools to evaluate their work.
- Answers to selected problems allow students to test themselves on their understanding of material. The instructor can assign problems with or without answers, or modify answered problems for additional problems for use on exams. Approximately 25% of the problems have answers.