E-Book, Englisch, 88 Seiten
Banerjee Performance Evaluation of Electronic Oscillators
1. Auflage 2019
ISBN: 978-3-030-25678-4
Verlag: Springer International Publishing
Format: PDF
Kopierschutz: 1 - PDF Watermark
Automated S Parameter Free Design with SPICE and Discrete Fourier Transforms
E-Book, Englisch, 88 Seiten
ISBN: 978-3-030-25678-4
Verlag: Springer International Publishing
Format: PDF
Kopierschutz: 1 - PDF Watermark
This book demonstrates a novel, efficient and automated scheme to design and evaluate the performance of electronic oscillators, operating at the 100s of Megahertz to 10s of Gigahertz frequencies. The author describes a new oscillator design and performance evaluation scheme that addresses all the issues associated with the traditional S parameter (large, small signal) based oscillator design technique by exploiting the properties of a new breed of RF or microwave transistors, the powerful Discrete Fourier Transform and the SPICE tool's transient analysis. Readers will benefit from an exhaustive set of detailed, step-by-step oscillator (feedback, negative resistance, crystal and differential) design examples, as well as the software tools (C executables) used to create the design examples. Designers will be enabled to eliminate the complexities of the traditional oscillator design/performance evaluation scheme using S (large, small) parameter, resulting in accurate, robust and reliable designs.
Describes an efficient, automated oscillator design and performance evaluation scheme that addresses all the challenges associated with the traditional S parameter (large, small signal) based oscillator design;Provides numerous step-by-step design examples, illustrating the details of the new scheme presented;Includes C executables that run on both Linux and Windows, which the reader can use to experiment and design any oscillator (feedback common emitter or base, negative resistance common emitter or base or differential).
Amal Banerjee is Engineering Manager at Analog Electronics, in Kolkata, India, specializing in design and manufacture of RF and microwave filters, precision power supplies, oscillators, microstrip waveguides etc., as well as special software for designing filters etc., The clients of Analog Electronics are spread across India, Vietnam and USA. He has authored/co-authored conference papers and books on SystemC/SystemC-AMS, distributed/lumped element electronic filter design, and broad and narrow band impedance matching techniques for RF microwave applications.
Autoren/Hrsg.
Weitere Infos & Material
1;Supplementary Online Software;5
2;Contents;6
3;Chapter 1: Introduction and Problem Statement;9
3.1;1.1 Introduction and Problem Statement;9
4;Chapter 2: Electronic Oscillator Fundamentals;12
4.1;2.1 Fundamental Oscillator Configuration: Open- and Closed-Loop Equations-Loop Gain-Barkhausen and Nyquist Conditions;12
4.2;2.2 Negative Resistance Oscillators: Start-Up and Steady-State Conditions;14
4.3;2.3 Traditional Electronic Oscillator Start-Up and Steady-State Analysis;17
4.4;2.4 Differential Oscillators as an Alternative to Feedback and Negative Resistance Oscillators;18
4.5;2.5 Common Oscillator Design Equations and Formulas;19
4.5.1;2.5.1 Common-Emitter Colpitts Resonator Feedback Oscillator;20
4.5.2;2.5.2 Common-Emitter Clapp Resonator Negative Resistance Oscillator;21
4.5.3;2.5.3 Common-Base Colpitts Resonator Feedback Oscillator;22
4.5.4;2.5.4 Common-Base LC Tank Resonator Negative Resistance Oscillator;23
4.6;2.6 Oscillator Noise: Phase Noise-An Intuitive Approach;24
4.6.1;2.6.1 Leeson´s Theory of Oscillator Phase Noise;27
4.6.2;2.6.2 Oscillator Noise: A Perturbation Approach and Characterization;28
4.7;2.7 Multiplying Signals to Get New Signals: Mixers;29
4.8;2.8 Output Buffer Amplifier: Couple Output to External Load;31
4.9;2.9 The Discrete Fourier Transform and Power Spectrum of a Signal;33
4.10;References;34
5;Chapter 3: Automated S Parameter-Free Electronic Oscillator Design, Performance Evaluation Scheme, and Step-by-Step Design Exa...;36
5.1;3.1 S Parameter-Free Electronic Oscillator Design, Performance Evaluation Scheme;36
5.2;3.2 Verification of Discrete Fourier Transform Executable Accuracy;39
5.3;3.3 1800 MHz (1.8 GHz) Common-Emitter Negative Resistance Clapp Resonator GSM Carrier Frequency Oscillator;40
5.4;3.4 1000 MHz (1 GHz) Common-Emitter Negative Resistance Clapp Resonator Oscillator;47
5.5;3.5 750 MHz Common-Emitter Negative Resistance Clapp Resonator Oscillator;49
5.6;3.6 500 MHz Common-Emitter Negative Resistance Clapp Resonator Oscillator;51
5.7;3.7 1000 Hz Common-Emitter Feedback Colpitts Resonator Oscillators;53
5.8;3.8 500 MHz Common-Emitter Feedback Colpitts Resonator Oscillator;55
5.9;3.9 750 MHz Common-Base Feedback Colpitts Resonator Oscillator;56
5.10;3.10 500 MHz Common-Base Feedback Colpitts Resonator Oscillator;59
5.11;3.11 Common-Base Negative Resistance 100 MHz Parallel RLC Resonator Oscillator;61
5.12;3.12 1000 MHz Differential Oscillator Using CMOS Level 3 MOSFET;63
5.13;3.13 750 MHz Differential Oscillator Using CMOS Level 3 MOSFET;67
5.14;3.14 500 MHz Differential Oscillator Using CMOS Level 3 MOSFET;69
5.15;3.15 14 MHz Crystal Oscillator Using CMOS Level 3 MOSFET;72
5.16;3.16 750 MHz Common-Emitter Negative Resistance Clapp Resonator Oscillator with Nonideal Resonator Inductor;73
5.17;3.17 Schottky Diode Ring Double-Balanced Mixer LO 250 MHz RF 500 MHz;74
5.18;3.18 Schottky Diode Ring Double-Balanced Mixer LO 250 MHz RF 500 MHz: Unequal Load Source Resistances;77
5.19;3.19 Common-Collector Buffer Amplifier Input Frequency 500 MHz;78
5.20;References;80
6;Chapter 4: Conclusions and Future Work;81
7;Appendix A: HFA3134 Data Sheet and SPICE Device Model;83
8;Appendix B: List of Supplied C Computer Language Executables for Linux and Windows;84
8.1;Linux;84
8.2;Windows;84
9;Appendix C: Downloading and Installing MinGW;85
10;Index;86
