Modern RF and Microwave Filter Design
Published on 1. January 2016
412 pages
978-1-63081-382-6 (ISBN)
Description
This authoritative resource presents current practices for the design of RF and microwave filters. This one-stop reference provides readers with essential and practical information in order to design their own filter design software package, ultimately saving time and money. Essential building blocks for each type of filter are presented including network theory, transmission lines, and coupling mechanisms. This book presents a detailed discussion of the Low Pass Filter prototype, which is then extended to other configurations such as high pass, band pass, band stop, diplexers, and multiplexers. Microwave Network Theory and Transmission Line Coupling Mechanisms are presented along with a comprehensive discussion of the characteristics of commonly used transmission lines such as waveguides, Striplines, and Microstrip lines. Numerous design examples are presented to demonstrate an inclusive design methodology.
More details
Other editions
Additional editions
Prakash Bhartia | Protap Pramanick
Modern RF and Microwave Filter Design
Book
08/2016
Artech House Publishers
Unfortunately, price unknown
Available (delivery time upon request)
Content
- Intro
- Modern RF and Microwave Filter Design
- Contents
- Preface
- CHAPTER 1 Introduction
- 1.1 Applications of RF And Microwave Filters
- 1.2 Impedance Matching Networks
- 1.3 The Concept of Complex Frequency
- 1.4 Useful Definitions
- 1.5 Realizable Driving-Point Impedances
- References
- CHAPTER 2 Microwave Network Theory
- 2.1 Introduction
- 2.2 Concepts Of Equivalent Voltage And Current
- 2.3 Impedance And Admittance Matrices
- 2.4 Scattering Matrix
- 2.4.1 Definition of Scattering Matrix
- 2.4.2 Transformation of Scattering Matrix Due to Shift in Reference Plane
- 2.4.3 Scattering Matrix of a Lossless Three-Port Network
- 2.4.4 Usefulness of Scattering Matrix
- 2.4.5 Scattering Matrix and the Concept of Insertion Loss
- 2.5 Measurement of Scattering Matrix
- 2.6 Chain Or ABCD Matrix
- 2.6.1 Use of ABCD Matrix in Computing Network Properties
- 2.6.2 Normalized ABCD Matrix
- References
- CHAPTER 3 Properties Of Microwave Transmission Lines
- 3.1 Introduction
- 3.2 Transmission Line Equations
- 3.3 Transmission Line With Electrical Discontinuity
- 3.4 Two-Conductor Transmission Lines
- 3.4.1 Two Round Conductors of Equal Diameter
- 3.4.2 Coaxial Line
- 3.4.3 Other Forms of Coaxial Line
- 3.4.4 General Equation for Attenuation in Two-Conductor Transmission Lines
- 3.4.5 Maximum Power-Handling Capability of a Coaxial Line
- 3.4.6 Coaxial Line Discontinuities
- 3.5 Rectangular Coaxial Line
- 3.5.1 Higher-Order Modes in a Rectangular Coaxial Line
- 3.5.2 Square Coaxial Line with Circular Inner Conductor
- 3.6 Strip Transmission Line
- 3.6.1 Basic Configuration
- 3.6.2 Modes in a Stripline
- 3.6.3 Characteristic Impedance of a Balanced Stripline
- 3.6.4 Unbalanced Stripline
- 3.6.5 Propagation Constant in a Stripline
- 3.6.6 Synthesis of a Stripline
- 3.6.7 Attenuation Constant in a Stripline
- 3.6.8 Power-Handling Capability of a Stripline
- 3.6.9 Stripline Discontinuities
- 3.7 Parallel-Coupled Lines
- 3.7.1 Edge-Coupled Striplines
- 3.7.2 Synthesis Equations
- 3.7.3 Attenuation in Coupled Striplines
- 3.7.4 Broadside Coupled Striplines
- 3.7.5 Coupled-Slab Lines
- 3.8 Inhomogeneous Transmission Lines
- 3.8.1 Shielded Microstrip Line
- 3.8.2 Coupled Microstrip Line
- 3.8.3 Suspended Microstrip Line
- 3.8.4 Shielded Suspended Microstrip Line
- 3.8.5 Edge-Coupled Suspended Microstrip Lines
- 3.8.6 Broadside-Coupled Suspended Striplines
- 3.8.7 Microstrip and Suspended Stripline Discontinuities
- 3.9 Single-Conductor Closed Transmission Lines
- 3.9.1 Hollow Metallic Waveguides
- 3.9.2 Characteristic Impedance of a Circular Waveguide
- 3.9.3 Attenuation in a Circular Waveguide
- 3.9.4 Maximum Power-Handling Capability of a Waveguide
- 3.9.5 Power-Handling Capability of a Circular Waveguide
- 3.9.6 Discontinuities in Waveguides and the Circuit Parameters
- 3.9.7 Waveguide Asymmetric H-Plane Step
- 3.9.8 Mode Matching Method and Waveguide Discontinuities
- 3.9.9 Waveguide Discontinuity Analysis in General
- 3.9.10 Finite Element Modal Expansion Method
- 3.9.11 Typical Three-Dimensional Discontinuity in a Rectangular Waveguide
- References
- CHAPTER 4 Lowpass Filter Design
- 4.1 Insertion Loss Method of Filter Design
- 4.2 Belevitch Matrix And Transfer Function Synthesis
- 4.2.1 Butterworth Approximation
- 4.2.2 Cauer Synthesis
- 4.2.3 General Solution for Butterworth Lowpass Filter Response
- 4.2.4 Chebyshev Approximation
- 4.2.5 Elliptic Function Approximation
- 4.2.6 Generalized Chebyshev Lowpass Filters
- 4.3 Concept Of Impedance Inverter
- 4.3.1 Physical Realization of Impedance and Admittance Inverters
- 4.4 Lowpass Prototype Using Cross-Coupled Networks
- 4.5 Design Of Lowpass Prototypes Using Optimization And The Method Of Least Squares
- References
- Appendix 4A
- 4A.1.1 Darlington Synthesis [17]
- CHAPTER 5 Theory Of Distributed Circuits
- 5.1 Distributed Element Equivalence Of Lumped Elements
- 5.2 TLE or UE and Kuroda Identity
- 5.3 Effects Of Line Length And Impedance On Commensurate Line Filters
- 5.3.1 Design Example
- 5.3.1 Low-Pass Filter Prototype with a Mixture of UEs and Impedance Inverters
- 5.3.2 Quasi-Distributed Element TEM Filters
- 5.4 High-Pass Filter Design
- 5.4.1 Low-Pass to High-Pass Transformation
- 5.4.2 Quasi-Lumped Element High-Pass Filter
- 5.4.3 Levy's Procedure for Planar High-Pass Filter Design
- 5.4.4 Waveguide High-Pass Filter Design
- 5.5 Band-Stop Filter Design
- 5.5.1 Low-Pass to Band-Stop Transformation
- 5.5.2 Determination of Fractional 3-dB Bandwidth of a Single Branch
- 5.5.3 Effects of Dissipation Loss in Band-Stop Filters
- 5.5.4 Stub-Loaded Band-Stop Filter
- 5.5.4 Design Steps for Waveguide Band-Stop Filters
- References
- CHAPTER 6 Band-Pass Filters
- 6.1 Theory Of Band-Pass Filters
- 6.2 Distributed Transmission Line Form Of Capacitively Coupled Band-Pass Filter
- 6.2.1 Gap-Coupled Transmission Line Band-Pass Filters
- 6.2.2 Edge Parallel-Coupled Band-Pass Filters
- 6.2.3 Hairpin-Line Filter
- 6.2.4 Interdigital Filters
- 6.2.5 Capacitively Loaded Interdigital Filters
- 6.2.6 Band-Pass Filter Design Based on Coupling Matrix
- 6.2.7 Coaxial Cavity Band-Pass Filter Design
- 6.2.8 Combline Filters
- 6.2.9 Waveguide Band-Pass Filter Design
- 6.2.10 Evanescent-Mode Waveguide Band-Pass Filter Design
- 6.2.11 Cross-Coupled Resonator Filter Design
- 6.2.12 Design of Cross-Coupled Filters Using Dual-Mode Resonators
- 6.2.13 Folded Resonator Cross-Coupled Filters
- 6.2.14 Cross-Coupled Filters Using Planar Transmission Lines
- 6.3 Cross-Coupled Band-Pass Filters With Independently Controlled Transmission Zeros
- 6.4 Unified Approach To Tuning Coupled Resonator Filters
- 6.5 Dielectric Resonator Filters
- 6.5.1 Introduction
- 6.5.2 Modes in a Dielectric Resonator
- References
- Appendix 6A Slot Coupled Coaxial Combline Filter Design
- Appendix 6B A Step-By-Step Procedure For Waveguide Folded and Elliptic Filter Design
- Step 1: Designing the Basic Filter
- Step 2: Bringing the Nonadjacent Resonators to Be Cross Coupled Close to Each Other
- Step 3: Generating the Cross Coupling
- Appendix 6C Design of Dielectric Resonator Filters
- CHAPTER 7 Design Of Multiplexers
- 7.1 Definition Of A Multiplexer
- 7.2 Common Junction Multiplexer With Susceptance Annulling Network
- 7.3 Cascaded Directional Filter
- 7.4 Circulator Based Multiplexer
- 7.5 Manifold Multiplexer
- 7.5.1 Diplexer Design
- 7.5.2 Multiplexer Design
- References
- About the Authors
- Index
