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Microwave Devices, Circuits and Subsystems for Communications Engineering. Edition No. 1

  • ID: 2178087
  • Book
  • March 2005
  • 550 Pages
  • John Wiley and Sons Ltd
Microwave Devices, Circuits and Subsystems for Communications Engineering provides a detailed treatment of the common microwave elements found in modern microwave communications systems. The treatment is thorough without being unnecessarily mathematical. The emphasis is on acquiring a conceptual understanding of the techniques and technologies discussed and the practical design criteria required to apply these in real engineering situations.

Key topics addressed include:

Microwave diode and transistor equivalent circuits

Microwave transmission line technologies and microstrip design

Network methods and s-parameter measurements

Smith chart and related design techniques

Broadband and low-noise amplifier design

Mixer theory and design

Microwave filter design

Oscillators, synthesisers and phase locked loops

Each chapter is written by specialists in their field and the whole is edited by experience authors whose expertise spans the fields of communications systems engineering and microwave circuit design.

Microwave Devices, Circuits and Subsystems for Communications Engineering is suitable for senior electrical, electronic or telecommunications engineering undergraduate students, first year postgraduate students and experienced engineers seeking a conversion or refresher text.

Includes a companion website featuring:

Solutions to selected problems

Electronic versions of the figures

Sample chapter
Note: Product cover images may vary from those shown
List of contributors.


1. Overview of the Book (I.A. Glover, S.R. Pennock and P.R. Shepherd).

1.1 Introduction.

1.2 RF Devices.

1.3 Signal Transmission and Network Methods.

1.4 Amplifiers.

1.5 Mixers.

1.6 Filters.

1.7 Oscillators and Frequency Synthesisers.

2. RF Devices: Characteristics and Modelling (A. Suarez and T. Fernandez).

2.1 Introduction

2.2 Semiconductor Properties

2.3 P-N Junction.

2.4 The Schottky Diode.

2.5 PIN Diodes.

2.6 Step-Recovery Diodes.

2.7 Gunn Diodes.

2.8 IMPATT Diodes.

2.9 Transistors.


3. Signal Transmission, Network Methods and Impedance Matching (N.J. McEwan, T.C. Edwards, D. Dernikas and I.A. Glover).

3.1 Introduction.

3.2 Transmission Lines: General Considerations.

3.3 The Two-Conductor Transmission Line: Revision of Distributed Circuit Theory.

3.4 Loss, Dispersion, Phase and Group Velocity.

3.5 Field Theory Method for Ideal TEM Case.

3.6 Microstrip.

3.7 Coupled Microstrip Lines.

3.8 Network Methods.

3.9 Impedance Matching.

3.10 Network Analysers.

3.11 Summary.


4. Amplifier Design (N.J. McEwan and D. Dernikas).

4.1 Introduction.

4.2 Amplifier Gain Definitions.

4.3 Stability.

4.4. Broadband Amplifier Design.

4.5 Low Noise Amplifier Design.

4.6 Practical Circuit Considerations.

4.7 Computer-Aided Design (CAD).


5. Mixers: Theory and Design (A. Tazon and L. de la Fuente).

5.1 Introduction.

5.2 General Properties.

5.3 Devices for Mixers.

5.4 Non-Linear Analysis.

5.5 Diode Mixer Theory.

5.6 FET Mixers.

5.7 IF Amplifier.

5.8 Single-Balanced FET Mixers.

5.9 Double-Balanced FET Mixers.

5.10 Harmonic Mixers.

5.11 Monolithic Mixers.


6. Filters (A Mediavilla).

6.1 Introduction.

6.2 Filter Fundamentals.

6.3 Mathematical Filter Responses.

6.4 Low Pass Prototype Filter Design.

6.5 Filter Impedance and Frequency Scaling.

6.6 Elliptic Filter Transformation.

6.7 Filter Normalisation.

7. Oscillators, Frequency Synthesisers and PLL Techniques (E. Artal, J.P. Pascal and J. Portilla).

7.1 Introduction.

7.2 Solid State Microwave Oscillators.

7.3 Negative Resistance Diode Oscillators.

7.4 Transistor Oscillators.

7.5 Voltage-Controlled Oscillators.

7.6 Oscillator Characterisation and Testing,

7.7 Microwave Phase Locked Oscillators.

7.8 Subsystems for Microwave Phase Locked Oscillators (PLOs).

7.9 Phase Noise.

7.10 Examples of PLOs.


Note: Product cover images may vary from those shown
Ian A. Glover University of Bath, UK.

Steve Pennock University of Bath, UK.

Peter Shepherd University of Bath, UK.
Note: Product cover images may vary from those shown