E-Book, Englisch, 1052 Seiten
Reihe: Engineering
Aluf Microwave RF Antennas and Circuits
1. Auflage 2016
ISBN: 978-3-319-45427-6
Verlag: Springer Nature Switzerland
Format: PDF
Kopierschutz: 1 - PDF Watermark
Nonlinearity Applications in Engineering
E-Book, Englisch, 1052 Seiten
Reihe: Engineering
ISBN: 978-3-319-45427-6
Verlag: Springer Nature Switzerland
Format: PDF
Kopierschutz: 1 - PDF Watermark
This book describes a new concept for analyzing RF/microwave circuits, which includes RF/microwave antennas. The book is unique in its emphasis on practical and innovative microwave RF engineering applications. The analysis is based on nonlinear dynamics and chaos models and shows comprehensive benefits and results. All conceptual RF microwave circuits and antennas are innovative and can be broadly implemented in engineering applications.
Given the dynamics of RF microwave circuits and antennas, they are suitable for use in a broad range of applications. The book presents analytical methods for microwave RF antennas and circuit analysis, concrete examples, and geometric examples. The analysis is developed systematically, starting with basic differential equations and their bifurcations, and subsequently moving on to fixed point analysis, limit cycles and their bifurcations.
Engineering applications include microwave RF circuits and antennas in a variety of topological structures, RFID ICs and antennas, microstrips, circulators, cylindrical RF network antennas, Tunnel Diodes (TDs), bipolar transistors, field effect transistors (FETs), IMPATT amplifiers, Small Signal (SS) amplifiers, Bias-T circuits, PIN diode circuits, power amplifiers, oscillators, resonators, filters, N-turn antennas, dual spiral coil antennas, helix antennas, linear dipole and slot arrays, and hybrid translinear circuits. In each chapter, the concept is developed from the basic assumptions up to the final engineering outcomes. The scientific background is explained at basic and advanced levels and closely integrated with mathematical theory.
The book also includes a wealth of examples, making it ideal for intermediate graduate level studies. It is aimed at electrical and electronic engineers, RF and microwave engineers, students and researchers in physics, and will also greatly benefit all engineers who have had no formal instruction in nonlinear dynamics, but who nowdesire to bridge the gap between innovative microwave RF circuits and antennas and advanced mathematical analysis methods.
Autoren/Hrsg.
Weitere Infos & Material
1;Preface;5
2;Contents;11
3;Introduction;14
4;1 RFID Antennas Systems Descriptions and Analysis;17
4.1;1.1 Active RFID TAGs System Analysis of Energy Consumption as Excitable Linear Bifurcation System;18
4.2;1.2 RFID TAG’s Dimensional Parameters Optimization as Excitable Linear Bifurcation Systems;30
4.3;1.3 RFID TAGs Coil’s System Stability Optimization Under Delayed Electromagnetic Interferences;38
4.4;1.4 Semi-Passive RFID Tags with Double Loop Antennas Arranged as a Shifted Gate System for Stability Optimization Under Delayed Electromagnetic Interferences;60
4.5;1.5 RFID TAGs Detectors Stability Analysis Under Delayed Schottky Diode’s Internal Elements in Time;88
4.6;1.6 RFID System Burst Switch Stability Analysis Under Delayed Internal Diode Circuitry Parasitic Effects in Time;120
4.7;Exercises;160
5;2 Microwave Elements Description and Stability Analysis;170
5.1;2.1 Microstrip Transmission Lines Delayed in Time Power Limiters Stability Analysis;171
5.2;2.2 Three Ports Active Circulator’s Reflection Type Phase Shifter (RTPS) Circuit Transmission Lines Delayed in Time System Stability Analysis;186
5.3;2.3 Cylindrical RF Network Antennas for Coupled Plasma Sources Copper Legs Delayed in Time System Stability Analysis;211
5.4;2.4 Tunnel Diode (TD) as a Microwave Oscillator System Cavity Parasitic Elements Stability Analysis;236
5.5;Exercises;282
6;3 Microwave Semiconductor Amplifiers Analysis;293
6.1;3.1 Bipolar Transistor at Microwave Frequencies Description and Stability Analysis;293
6.2;3.2 Field Effect Transistor (FETs) at Microwave Frequencies Description;313
6.3;3.3 Field Effect Transistor (FETs) at Microwave Frequencies Stability Analysis;332
6.4;3.4 IMPATT Amplifier Stability Analysis;347
6.5;3.5 Multistage IMPATT Amplifier System Microstrip Delayed in Time Stability Switching Analysis;387
6.6;3.6 FET Combined Biasing and Matching Circuit Stability Analysis;396
6.7;Exercises;406
7;4 Small Signal (SS) Amplifiers and Matching Network Stability Analysis;418
7.1;4.1 Small Signal (SS) Amplifiers and Matching Network;419
7.2;4.2 Small Signal (SS) Amplifiers PI & T’s Matching Network and Transformation;435
7.3;4.3 Small Signal (SS) Amplifiers Matching Network Stability Analysis Under Microstrip Parasitic Parameters Variation;448
7.4;4.4 Bias—T Three Port Network Stability Switching Under Delayed Micro Strip in Time;473
7.5;4.5 PIN Diode Stability Analysis Under Parameters Variation;502
7.6;Exercises;514
8;5 Power Amplifier (PA) System Stability Analysis;525
8.1;5.1 Class AB Push-Pull Power Amplifiers Stability Analysis Under Parameters Variation;526
8.2;5.2 Class C Power Amplifier (PA) with Parallel Resonance Circuit Stability Analysis Under Parameters Variation;540
8.3;5.3 Single Ended Class B Amplifier Gummel-Poon Model Analysis Under Parameters Variation;571
8.4;5.4 Wideband Low Noise Amplifier (LNA) with Negative Feedback Circuit Stability Analysis Under Circuit’s Parameters Variation;585
8.5;Exercises;599
9;6 Microwave/RF Oscillator Systems Stability Analysis;613
9.1;6.1 A Resonator Circuit 180° Phase Shift from Its Input to Output Stability Analysis Under Delayed Variables in Time;614
9.2;6.2 Closed Loop Functioning Oscillator Stability Analysis Under Parameters Variations;629
9.3;6.3 Hartley Oscillator Stability Analysis;642
9.4;6.4 Colpitts Oscillator Stability Analysis;656
9.5;Exercises;673
10;7 Filters Systems Stability Analysis;685
10.1;7.1 BPF Diplexer Without a Series Input Stability Analysis;686
10.2;7.2 Dual Band Diplexer Filter Stability Analysis Under Parameters Variation;709
10.3;7.3 A Crystal-Lattice BPF Circuit Stability Analysis;723
10.4;7.4 A Tunable BPF Employing Varactor Diodes Stability Analysis;757
10.5;Exercises;780
11;8 Antennas System Stability Analysis;794
11.1;8.1 N-Turn Multilayer Circular Coil Antennas Transceiver System Stability Optimization Under Delayed Electromagnetic Interferences;796
11.2;8.2 Double Rectangular Spiral Coils Antennas System Stability Optimization Under Delayed Electromagnetic Interferences and Parasitic Effects;829
11.3;8.3 Single-Turn Square Planar Straight Thin Film Inductors Antenna System Stability Optimization Under Microstrip Delayed in Time;860
11.4;8.4 Helix Antennas System Stability Analysis Under Parameters Variation;884
11.5;Exercises;896
12;9 Microwave RF Antennas and Circuits Bifurcation Behavior, Investigation, Comparison and Conclusion;914
13;Appendix A: RFID LF TAG 125 kHz/134 kHz Design and Analysis;923
13.1;A.1 LF TAG 125 kHz/134 kHz Design and Analysis;923
13.2;A.2 LF TAG 125 kHz/134 kHz Two Rectangular Spiral Antennas Design Analysis;933
14;Appendix B: RF Amplifiers Basic and Advance Topics and Design Methods;951
14.1;B.1 Amplifier Design Concepts and Matching Guidelines;951
14.2;B.2 Amplifier Distortion and Noise Products;961
14.3;B.3 Small Signal (SS) Amplifier Design & Matching Network;974
15;Appendix C: BJT Transistor Ebers-Moll Model and MOSFET Model;1002
16;References;1043
17;Index;1049
