Microwave Active Circuit Analysis and Design 1st Edition by Clive Poole, Izzat Darwazeh ISBN 9780124078239 0124078230

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ISBN 10: 0124078230
ISBN 13: 9780124078239
Author: Clive Poole, Izzat Darwazeh

This book teaches the skills and knowledge required by today’s RF and microwave engineer in a concise, structured and systematic way. Reflecting modern developments in the field, this book focuses on active circuit design covering the latest devices and design techniques.

From electromagnetic and transmission line theory and S-parameters through to amplifier and oscillator design, techniques for low noise and broadband design; This book focuses on analysis and design including up to date material on MMIC design techniques.

With this book you will:

• Learn the basics of RF and microwave circuit analysis and design, with an emphasis on active circuits, and become familiar with the operating principles of the most common active system building blocks such as amplifiers, oscillators and mixers
• Be able to design transistor-based amplifiers, oscillators and mixers by means of basic design methodologies
• Be able to apply established graphical design tools, such as the Smith chart and feedback mappings, to the design RF and microwave active circuits
• Acquire a set of basic design skills and useful tools that can be employed without recourse to complex computer aided design
• Structured in the form of modular chapters, each covering a specific topic in a concise form suitable for delivery in a single lecture
• Emphasis on clear explanation and a step-by-step approach that aims to help students to easily grasp complex concepts
• Contains tutorial questions and problems allowing readers to test their knowledge
• An accompanying website containing supporting material in the form of slides and software (MATLAB) listings
• Unique material on negative resistance oscillator design, noise analysis and three-port design techniques
• Covers the latest developments in microwave active circuit design with new approaches that are not covered elsewhere

Microwave Active Circuit Analysis and Design 1st Edition Table of contents:

Section A: Foundations

Chapter 1: Introduction

Abstract

Intended Learning Outcomes

1.1 Introduction to microwave electronics

1.2 Properties of materials at microwave frequencies

1.3 Behavior of real components at microwave frequencies

1.4 The importance of impedance matching

1.5 Common microwave metrics

1.6 Quality factor, Q

1.7 Takeaways

Tutorial problems

Chapter 2: Transmission line theory

Abstract

Intended Learning Outcomes

2.1 Introduction

2.2 Propagation and reflection on a transmission line

2.3 Sinusoidal steady-state conditions: standing waves

2.4 Primary line constants

2.5 The lossless transmission line

2.6 Derivation of the characteristic impedance

2.7 Transmission lines with arbitrary terminations

2.8 The effect of line losses

2.9 Power considerations

2.10 Takeaways

Tutorial problems

Chapter 3: Practical transmission lines

Abstract

Intended Learning Outcomes

3.1 Introduction

3.2 Waveguide

3.3 Co-axial cable

3.4 Twisted pair

3.5 Microstrip

3.6 Microstrip discontinuities

3.7 Stripline

3.8 Coplanar waveguide

3.9 Takeaways

Tutorial problems

Chapter 4: The Smith Chart

Abstract

Intended Learning Outcomes

4.1 Introduction to the Smith Chart

4.2 Smith Chart Derivation

4.3 Using the Smith Chart

4.4 Smith Chart Variants

4.5 Takeaways

Tutorial problems

Section B: Microwave Circuit Analysis

Chapter 5: Immittance parameters

Abstract

Intended Learning Outcomes

5.1 Introduction

5.2 Conversion between immittance parameters

5.3 Input and output impedance of a two-port in terms of immittance parameters

5.4 Classification of immittance matrices

5.5 Immittance parameter representation of active devices

5.6 Immittance parameter analysis of two-ports with feedback

5.7 Takeaways

Tutorial problems

Chapter 6: S-parameters

Abstract

Intended Learning Outcomes

6.1 Introduction

6.2 Input and output impedance of a two-port in terms of S-parameters

6.3 Classification of S-matrices

6.4 Signal flow graphs

6.5 Scattering transfer parameters

6.6 Relationship between S-parameters and immittance parameters

6.7 Measurement of S-parameters

6.8 Takeaways

Tutorial problems

Chapter 7: Gain and stability of active networks

Abstract

Intended Learning Outcomes

7.1 Introduction

7.2 Power gain in terms of immittance parameters

7.3 Stability in terms of immittance parameters

7.4 Stability in terms of S-parameters

7.5 Power gain in terms of S-parameters

7.6 Takeaways

Tutorial problems

Chapter 8: Three-port analysis techniques

Abstract

Intended Learning Outcomes

8.1 Introduction

8.2 Three-port immittance parameters

8.3 Three-port S-parameters

8.4 Configuration conversion

8.5 Feedback mappings

8.6 Application of three-port design techniques

8.7 Reverse feedback mappings

8.8 Takeaways

Tutorial problems

Chapter 9: Lumped element matching networks

Abstract

Intended learning outcomes

9.1 Introduction

9.2 L-section matching networks

9.3 Three element matching networks

9.4 Bandwidth of lumped element matching networks

9.5 Takeaways

Tutorial problems

Chapter 10: Distributed element matching networks

Abstract

Intended Learning Outcomes

10.1 Introduction

10.2 Impedance transformation with line sections

10.3 Single stub matching

10.4 Double stub matching

10.5 Triple stub matching

10.6 Quarter-Wave transformer matching

10.7 Bandwidth of distributed element matching networks

10.8 Summary

10.9 Takeaways

Tutorial problems

Section C: Microwave Circuit Design

Chapter 11: Microwave semiconductor materials and diodes

Abstract

Intended Learning Outcomes

11.1 Introduction

11.2 Choice of microwave semiconductor materials

11.3 Microwave semiconductor fabrication technology

11.4 The pn-junction

11.5 Schottky diodes

11.6 Varactor diodes

11.7 PIN diodes

11.8 Tunnel diodes

11.9 Gunn diodes

11.10 The IMPATT diode family

11.11 Takeaways

Chapter 12: Microwave transistors and MMICs

Abstract

Intended learning outcomes

12.1 Introduction

12.2 Microwave bipolar junction transistors

12.3 Heterojunction bipolar transistor

12.4 Microwave field-effect Transistors

12.5 MESFET and HEMT equivalent circuit

12.6 Monolithic microwave integrated circuits

12.7 MMIC technologies

12.8 MMIC circuit elements

12.9 MMIC application example

12.10 Takeaways

Chapter 13: Microwave amplifier design

Abstract

Intended Learning Outcomes

13.1 Introduction

13.2 Single-stage amplifier design

13.3 Single-stage feedback amplifier design

13.4 Multistage amplifiers

13.5 Broadband amplifiers

13.6 Takeaways

Chapter 14: Low-noise amplifier design

Abstract

Intended learning outcomes

14.1 Introduction

14.2 Types of electrical noise

14.3 Noise factor, noise figure, and noise temperature

14.4 Representation of noise in active two-port networks

14.5 Single-stage low-noise amplifier design

14.6 Multistage low-noise amplifier design

14.7 Noise measurements

14.8 Takeaways

Chapter 15: Microwave oscillator design

Abstract

Intended Learning Outcomes

15.1 Introduction

15.2 RF Feedback oscillators

15.3 Cross-coupled oscillators

15.4 Negative resistance oscillators

15.5 Frequency stabilization

15.6 Voltage controlled oscillators

15.7 Injection locked and synchronous oscillators

15.8 Takeaways

Chapter 16: Low-noise oscillator design

Abstract

Intended Learning Outcomes

16.1 Introduction

16.2 Definition of phase noise

16.3 Why Oscillator Phase Noise Is Important

16.4 Root causes of phase noise

16.5 Modeling oscillator phase noise

16.6 Low-Noise Oscillator Design

16.7 Phase-noise measurements

16.8 Takeaways

Chapter 17: Microwave mixers

Abstract

Intended Learning Outcomes

17.1 Introduction

17.2 Mixer characterization

17.3 Basic mixer operation

17.4 Passive mixer circuits

17.5 Active mixer circuits

17.6 Takeaways

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Tags: Clive Poole, Izzat Darwazeh, Microwave Active, Design