The first edition of “Microstrip Filters for RF/Microwave Applications” was published in 2001. Over the years the book has been well received and is used extensively in both academia and industry by microwave researchers and engineers. From its inception as a manuscript the book is almost 8 years old. While the fundamentals of filter circuits have not changed, further innovations in filter realizations and other applications have occurred with changes in the technology and use of new fabrication processes, such as the recent advances in RF MEMS and ferroelectric films for tunable filters; the use of liquid crystal polymer (LCP) substrates for multilayer circuits, as well as the new filters for dual-band, multi-band and ultra wideband (UWB) applications.
Although the microstrip filter remains as the main transmission line medium for these new developments, there has been a new trend of using combined planar transmission line structures such as co-planar waveguide (CPW) and slotted ground structures for novel physical implementations beyond the single layer in order to achieve filter miniaturization and better performance.
Also, over the years, practitioners have suggested topics that should be added for completeness, or deleted in some cases, as they were not very useful in practice.
In view of the above, the authors are proposing a revised version of the “Microstrip Filters for RF/Microwave Applications” text and a slightly changed book title of “Planar Filters for RF/Microwave Applications” to reflect the aforementioned trends in the revised book.
|Series:||Wiley Series in Microwave and Optical Engineering Series , #216|
|Edition description:||2nd ed.|
|Product dimensions:||6.40(w) x 9.40(h) x 1.70(d)|
About the Author
Jia-Sheng Hong, PhD, is a senior faculty member in the Department of Electrical, Electronic, and Computer Engineering at Heriot-Watt University, Edinburgh, United Kingdom, where he leads a research group on advanced RF/microwave device technologies. Previously, he was involved with microwave applications of high-temperature superconductors, EM modeling, and circuit optimization at the University of Birmingham.
Table of Contents
Preface to the Second Edition.
Preface to the First Edition.
2 Network Analysis.
2.1 Network Variables.
2.2 Scattering Parameters.
2.3 Short-Circuit Admittance Parameters.
2.4 Open-Circuit Impedance Parameters.
2.5 ABCD Parameters.
2.6 Transmission-Line Networks.
2.7 Network Connections.
2.8 Network Parameter Conversions.
2.9 Symmetrical Network Analysis.
2.10 Multiport Networks.
2.11 Equivalent and Dual Network.
2.12 Multimode Networks.
3 Basic Concepts and Theories of Filters.
3.1 Transfer Functions.
3.2 Lowpass Prototype Filters and Elements.
3.3 Frequency and Element Transformations.
3.4 Immittance Inverters.
3.5 Richards’ Transformation and Kuroda Identities.
3.6 Dissipation and Unloaded Quality Factor.
4 Transmission Lines and Components.
4.1 Microstrip Lines.
4.2 Coupled Lines.
4.3 Discontinuities and Components.
4.4 Other Types of Microstrip Lines.
4.5 Coplanar Waveguide (CPW).
5 Lowpass and Bandpass Filters.
5.1 Lowpass Filters.
5.2 Bandpass Filters.
6 Highpass and Bandstop Filters.
6.1 Highpass Filters.
6.2 Bandstop Filters.
7 Coupled-Resonator Circuits.
7.1 General Coupling Matrix for Coupled-Resonator Filters.
7.2 General Theory of Couplings.
7.3 General Formulation for Extracting Coupling Coefficient k.
7.4 Formulation for Extracting External Quality Factor Qe.
7.5 Numerical Examples.
7.6 General Coupling Matrix Including Source and Load.
8 CAD for Low-Cost and High-Volume Production.
8.1 Computer-Aided Design (CAD) Tools.
8.2 Computer-Aided Analysis (CAA).
8.3 Filter Synthesis by Optimization.
8.4 CAD Examples.
9 Advanced RF/Microwave Filters.
9.1 Selective Filters with a Single Pair of Transmission Zeros.
9.2 Cascaded Quadruplet (CQ) Filters.
9.3 Trisection and Cascaded Trisection (CT) Filters.
9.4 Advanced Filters with Transmission-Line Inserted Inverters.
9.5 Linear-Phase Filters.
9.6 Extracted Pole Filters.
9.7 Canonical Filters.
9.8 Multiband Filters.
10 Compact Filters and Filter Miniaturization.
10.1 Miniature Open-Loop and Hairpin Resonator Filters.
10.2 Slow-Wave Resonator Filters.
10.3 Miniature Dual-Mode Resonator Filters.
10.4 Lumped-Element Filters.
10.5 Miniature Filters Using High Dielectric-Constant Substrates.
10.6 Multilayer Filters.
11 Superconducting Filters.
11.1 High-Temperature Superconducting (HTS) Materials.
11.2 HTS Filters for Mobile Communications.
11.3 HTS Filters for Satellite Communications.
11.4 HTS Filters for Radio Astronomy and Radar.
11.5 High-Power HTS Filters.
11.6 Cryogenic Package.
12 Ultra-Wideband (UWB) Filters.
12.1 UWB Filters with Short-Circuited Stubs.
12.2 UWB-Coupled Resonator Filters.
12.3 Quasilumped Element UWB Filters.
12.4 UWB Filters Using Cascaded Miniature High- And Lowpass Filters.
12.5 UWB Filters with Notch Band(s).
13 Tunable and Reconfigurable Filters.
13.1 Tunable Combline Filters.
13.2 Tunable Open-Loop Filters without Via-Hole Grounding.
13.3 Reconfigurable Dual-Mode Bandpass Filters.
13.4 Wideband Filters with Reconfigurable Bandwidth.
13.5 Reconfigurable UWB Filters.
13.6 RF MEMS Reconfigurable Filters.
13.7 Piezoelectric Transducer Tunable Filters.
13.8 Ferroelectric Tunable Filters.
Appendix: Useful Constants and Data.
A.1 Physical Constants.
A.2 Conductivity of Metals at 25◦C (298K).
A.3 Electical Resistivity ρ in 10−8 m of Metals.
A.4 Properties of Dielectric Substrates.