Microwave Integrated Circuit Components Design through MATLAB 1st Edition by Raghavan 1032084995 9781032084992

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ISBN 10: 1032084995

ISBN 13: 9781032084992

Author: S. Raghavan

MICROWAVE INTEGRATED CIRCUIT COMPONENTS DESIGN THROUGH MATLAB® This book teaches the student community microwave integrated circuit component design through MATLAB®, helping the reader to become conversant in using codes and, thereafter, commercial software for verification purposes only. Microwave circuit theory and its comparisons, transmission line networks, S-parameters, ABCD parameters, basic design parameters of planar transmission lines (striplines, microstrips, slot lines, coplanar waveguides, finlines), filter theory, Smith chart, inverted Smith chart, stability circles, noise figure circles and microwave components, are thoroughly explained in the book. The chapters are planned in such a way that readers get a thorough understanding to ensure expertise in design. Aimed at senior undergraduates, graduates and researchers in electrical engineering, electromagnetics, microwave circuit design and communications engineering, this book: • Explains basic tools for design and analysis of microwave circuits such as the Smith chart and network parameters • Gives the advantage of realizing the output without wiring the circuit by simulating through MATLAB code • Compares distributed theory with network theory • Includes microwave components, filters and amplifiers S. Raghavan was a Senior Professor (HAG) in the Department of Electronics and Communication Engineering, National Institute of Technology (NIT), Trichy, India and has 39 years of teaching and research experience at the Institute. His interests include: microwave integrated circuits, RF MEMS, Bio MEMS, metamaterial, frequency selective surfaces (FSS), substrate integrated waveguides (SIW), biomedical engineering and microwave engineering. He has established state-of-the-art MICs and microwave research laboratories at NIT, Trichy with funding from the Indian government. He is a Fellow/Senior Member in more than 24 professional societies including: IEEE (MTT, EMBS, APS), IETE, IEI, CSI, TSI, ISSS, ILA and ISOI. He is twice a recipient of the Best Teacher Award, and has received the Life Time Achievement Award, Distinguished Professor of Microwave Integrated Circuit Award and Best Researcher Award.

Microwave Integrated Circuit Components Design through MATLAB 1st Table of contents:

1. Transmission Line Networks

1.1 Introduction

1.2 Characteristic Impedance for Different Lengths (λg/4, λg/2, λg/8)

1.2.1 Property of a Quarter Wavelength (λg/4) Transmission Line

1.2.2 Property of a Half Wavelength (λg/2) Transmission Line

1.2.3 Property of a One-Eighth Wavelength (λg/8) Transmission Line

1.3 T-Network and π-Network Sections Equivalent of a Transmission Line

1.4 T-Network and π-Network

1.5 Standard L-Section from Which All Other Network Topologies Are Built

1.6 Standard T-Network and π-Network Formed with Basic L-Section Shown in Figure 1.7

1.7 Relationship between Z1, Z2 and Cutoff Frequency (fc)

1.8 Methods of Realizing L and C

1.8.1 Stub Method

1.9 S-Parameters

1.10 ABCD Parameters

1.10.1 ABCD Parameters General Form

1.10.2 Series Impedance

1.10.3 Conversion of ABCD Parameters of Series Impedance to S-Parameters

1.10.4 Shunt Admittance

1.10.5 Conversion of ABCD Parameters of Shunt Admittance to S-Parameters

1.10.6 Series Impedance Cascade with a Shunt Admittance

1.10.7 Transformer

1.10.8 Properties of ABCD Parameters

1.11 Two-Port Networks Matched on Image and Iteration Basics

1.12 Equivalent Transmission Line Circuit Representation of TM (Transverse Magnetic) and TE (Transverse Electric) Waves

1.13 Basic Interconnection of the Two-Port Network

1.14 Transmission Line

1.15 Effective ABCD Parameters

1.16 Conversion of ABCD Parameters of the Transformer into S-Parameters

1.17 Unit Element (UE)

1.18 K-Inverter (Impedance Inverter)

1.19 J-Inverter (Admittance Inverter)

1.20 Analysis of Odd Mode and Even Mode

1.21 Kuroda’s Identities

1.21.1 Introduction

1.21.2 First Kuroda Identity

1.21.3 Second Kuroda Identity

1.21.4 Fourth Kuroda Identity

1.21.5 Conclusion

Bibliography

2. Planar Transmission Lines

2.1 Microwave Theory and Circuits

2.1.1 Introduction to Microwaves

2.1.2 Microwave Integrated Circuits

2.1.3 Introduction to Planar Transmission Lines

2.1.4 Various Planar Transmission Lines

2.1.5 Parameters for Selection of Transmission Structure

2.1.6 Calculation of Z0, νph, and εeff

2.2 Planar Transmission Lines and Microwave Integrated Circuits

2.3 Stripline

2.3.1 Suspended Stripline

2.3.2 Expressions for Z0, λg, and εeff

2.3.3 Summary of Stripline

2.4 Microstripline

2.4.1 Applications of Microstripline

2.4.2 Expressions of Z0 and εeff

2.4.3 Expressions for w/h in Terms of Z0 and εeff

2.4.4 Effect of Strip Thickness (t)

2.4.5 Losses

2.4.6 Power-Handling Capability

2.4.7 Average Power

2.4.8 Density of Heat Flow due to Conductor Loss

2.4.9 Microstrip–Quasi-TEM Mode

2.4.10 Frequency Limitations in Microstrip

2.4.11 Microstrip Design Summary

2.5 Suspended Microstripline and Inverted Microstripline

2.5.1 Characteristic Impedance Z0 and Effective Dielectric Constant εeff For Microstrip,

2.6 Slotline

2.6.1 Advantages

2.6.2 Disadvantages

2.7 Comparison between Slot Line and Microstrip Line

2.8 Coplanar Waveguide (CPW)

2.8.1 Calculation of Phase Velocity (νp) and Z0 for CPW with Infinitely Thick Substrate

2.8.2 Advantages

2.8.3 Disadvantages

2.8.4 Applications

2.9 Coplanar Strips

2.9.1 Calculation of Z0 and εeff

2.10 Finline

2.10.1 Basic Finline Structures

2.10.2 Some Coupled Finline Structures

2.10.3 E-Plane Transmission Lines Other than Finlines

2.10.4 Advantages

2.10.5 Disadvantages

2.11 Microwave Integrated Circuit

2.11.1 Hybrid MIC

2.11.2 Monolithic Circuits

2.11.3 Technology of Hybrid MICs

2.11.4 Transmission Media for MICs

2.11.5 Fabrication of Hybrid MICs

2.11.6 Advantages of MICs

2.11.6.1 Reduction in Cost

2.11.6.2 Improvement in Performance

2.11.6.3 Good Reproducibility and Reliability

2.11.6.4 Small Size and Weight

2.11.6.5 Wide Bandwidth

2.11.7 Difficulties of MICs

2.11.8 Applications of MMICs

2.11.9 Substrates for MICs

2.11.10 Microwave Integrated Circuits – Salient Features

2.11.11 Lumped Elements for MICs

2.12 Static –TEM Parameters

2.12.1 Static Analysis

2.13 Effects of Discontinuities

2.14 Applications of Transmission Line more than 100 GHz

2.14.1 Open Homogeneous Dielectric Guides

2.14.2 Image Guide

2.14.3 Nonradiative Dielectric Guide

2.14.4 H-Guide

2.14.5 Groove Guide

2.14.6 Dielectric Integrated Guide

2.15 Summary

2.15.1 Essentials of Microwave Integrated Circuit Component Design and Planar Transmission Lines

2.15.2 Introduction

2.15.3 Stripline and Its Variants

2.15.4 Microstripline and Its Variants

2.15.5 Slotline and Its Variants

2.15.6 Coplanar Waveguide and Its Variants

2.15.7 Coplanar Stripline and Its Variants

2.15.8 Finline and Its Variants

2.15.9 Dielectric Guides

2.15.10 Conclusion

Bibliography

3. Microwave Integrated Circuit (MIC) Components

3.1 Directional Coupler

3.2 Two-Stub Branch-Line Coupler

3.2.1 Conversion of ABCD Parameters into S-Parameter of Branch-Line Coupler

3.2.2 Midband Parameters

3.3 Hybrid Ring Coupler

3.4 Back Waveguide Coupler

3.5 Basic T-Junction Power Divider

3.5.1 Scattering Matrix of Basic Power Divider

3.5.2 Matched Two-Way Power Divider

Bibliography

4. Microwave Integrated Circuit Filters

4.1 Introduction

4.2 Filter Classification

4.3 Coupling Matrix

4.4 Lumped Element Filters

4.4.1 Maximally Flat Response

4.4.2 Chebyshev LPF (Equal Ripple)

4.4.3 Butterworth Low-Pass Prototype

4.5 Frequency and Impedance Scaling

4.6 Band Pass Filter (BPF) Design Equations

4.7 Filter Transformation

4.7.1 LPF to HPF Transformation

4.8 Filter Problems

Bibliography

5. Microwave Amplifiers

5.1 Stability

5.2 Input and Output Stability Circles

5.3 Unconditional Stability

5.4 Stability Circles

5.5 Input Stability Circles

5.6 Constant Gain Circles

5.7 Design Procedure for Stability Circles

5.8 Noise Figure

5.9 Low-Noise Amplifier

5.10 S-Parameters and Signal Flow Graphs

5.11 Derivation of GT

5.11.1 Relationship between b2 and bs

5.11.2 Evaluation of b2/bs by the Signal Flow Graph

5.11.3 Transducer Power Gain

5.11.4 Matched Transducer Power Gain (GTM)

5.11.5 Unilateral Transducer Power Gain (GTU)

5.11.6 Maximum Unilateral Transducer Power Gain (GTUmax)

5.12 Reflection Coefficients in Terms of S Parameters

5.13 Normalized Gain Factors gs and gL

5.14 Input Reflection Coefficient (Γin)

5.15 Output Reflection Coefficient (Γout)

5.16 Summary

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