Chapter One - S Parameters and Circuit Responses
1.1 Introduction
1.2 Problems of High Frequency Design
1.3 Rational of Using S Parameters
1.4 S Parameters
1.5 Interpretation of S Parameters
1.6 Change of Reference Planes
1.7 Plotting S Parameters on Smith Chart
1.8 Relationship Between S, Z, Y and h Parameters
1.9 Properties of S Parameters - Reciprocal and Lossless Networks
1.10 S Parameter Matrices for Standard Elements
1.11 Transmission [A] Parameters
1.12 Modified S Parameters - Mismatched Load and Source
1.13 Circuit Responses Calculated From S Parameters
1.14 Power Gain Equations
1.15 Scattering Matrices of Three and Four-Port Devices
1.16 Signal Flow Graphs
Problems
Chapter Two - Transmission Line Analysis
2.1 Introduction
2.2 Parallel Wire Transmission Line
2.3 Standing waves and the VSWR
2.4 The Input Impedance of a Line
2.5 Input Impedance of Lossy Lines
2.6 Low Loss Transmission Lines
2.7 Input Impedance of Infinitely Long Transmission Line
2.8 Quarter-Wave Transformer
2.9 The Smith Chart
2.10 Lumped and Distributed Elements
Problems
Chapter Three - Microstrip and Related Transmission Lines
3.1 Introduction
3.2 Evolution Of Microstrip As a Transmission Medium
3.3 Quasi-Static Mode For Microstrip Circuit
3.4 Calculation of Characteristic Impedance and Phase Constant
3.5 Results For εre and Zom Microstrip
3.6 Filling Factor q
3.7 Typical Design (Synthesis) Procedure - Graphical Method
3.8 Microstrip Discontinuities
3.9 Dispersion In Microstrip
3.10 Higher Order Modes
3.11 Microstrip Losses
3.12 Microstrip Q Factor
3.13 Effects of Top Plates and Enclosures
3.14 Microstrip Derivatives
3.15 Alternatives to Microstrip
3.16 Range of Characteristic Impedance Values for Microstrip and Other Transmission Systems
3.17 Qualitative Comparison of Transmission Structures
Problems
Chapter Four - Design of Microwave Transistor Amplifiers Using S Parameters
4.1 Introduction
4.2 Microwave Transistors
4.3 Material Properties
4.4 Microwave Bipolar Transistor
4.5 Microwave Field Effect Transistor
4.6 Microwave Transistor S-Parameter
4.7 Representations of Transistor S-parameters on Smith and Polar Charts
4.8 Transistor Equivalent Circuits
4.9 Transistor Stability
4.10 Maximum Stable Gain (MSG) and Maximum Available Gain (MAG)
4.11 Constant Gain Circles
4.12 Noise Figure Circles
4.13 Design Principles
4.14 Matching Circuit Design
4.15 Matching Using Lumped Elements
4.16 Matching Using Distributed Elements in Microstrip
4.17 Impedance Matching Examples
4.18 Bias Connections to Microstrip Circuits
4.19 Transistor Stabilization
4.20 Broadband Amplifier Design
4.21 High Power Amplifiers
4.22 Distributed Amplifiers
4.23 Non-Linear Distortion
4.24 Microwave Oscillators
Problems
Chapter Five - Microwave Filter Design
5.1 Introduction
5.2 Filter Types
5.3 General Filter Design Theory
5.4 Microwave Filter Construction
5.5 Microwave Filter Design Procedures
5.6 Phase Response
5.7 All-Pass Filter
5.8 Transformation From Prototype
5.9 Impedance and Admittance Inverters
5.10 Richard's Transformation
5.11 Kuroda Identities
5.12 Microstrip Filters
Proble
About the Author: Prof. Zaiki Awang is a Professor of Microwaves at the faculty of electrical engineering and head of Microwave Technology Centre, Universiti Teknologi MARA, Shah Alam, Malaysia. He was the past chairman, Institute of Electrical and Electronics Engineers (IEEE) USA, Malaysia Section and IEEE Malaysia Antenna and Propagation/Microwave Theory and Techniques/Electromagnetic Compatibility Joint Chapter. In addition he is the head, commission of Electronics and Photonics and Malaysia representative, International Union of Radio Science (URSI, Belgium). He has published more than 150 research papers in technical journals and proceedings, and written more than 50 technical reports for the profession and the industry.
