Pierre Jarry, Jacques Beneat
Design and Realizations of Miniaturized Fractal Microwave and RF Filters
Pierre Jarry, Jacques Beneat
Design and Realizations of Miniaturized Fractal Microwave and RF Filters
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Miniaturized filters are well suited for the increasing number of compact and low power applications. Presenting studies of the performance of fractal resonators and sensitivity analyses of suspended substrate realizations, Design and Realizations of Miniaturized Fractal Microwave and RF Filters provides RF and microwave engineers and researchers, advanced graduate students, and wireless and telecommunication engineers with the knowledge and skills to design and realize miniaturized fractal microwave and RF filters. This definitive source provides timely insight on fractal resonators for compact and low power microwave and RF.…mehr
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Miniaturized filters are well suited for the increasing number of compact and low power applications. Presenting studies of the performance of fractal resonators and sensitivity analyses of suspended substrate realizations, Design and Realizations of Miniaturized Fractal Microwave and RF Filters provides RF and microwave engineers and researchers, advanced graduate students, and wireless and telecommunication engineers with the knowledge and skills to design and realize miniaturized fractal microwave and RF filters. This definitive source provides timely insight on fractal resonators for compact and low power microwave and RF.
Produktdetails
- Produktdetails
- Verlag: John Wiley & Sons / Wiley
- Seitenzahl: 208
- Erscheinungstermin: 1. November 2009
- Englisch
- Abmessung: 240mm x 161mm x 16mm
- Gewicht: 484g
- ISBN-13: 9780470487815
- ISBN-10: 047048781X
- Artikelnr.: 27510737
- Verlag: John Wiley & Sons / Wiley
- Seitenzahl: 208
- Erscheinungstermin: 1. November 2009
- Englisch
- Abmessung: 240mm x 161mm x 16mm
- Gewicht: 484g
- ISBN-13: 9780470487815
- ISBN-10: 047048781X
- Artikelnr.: 27510737
Pierre Jarry graduated from the University of Limoges. As a professor at University of Brest, he directed the Laboratory of Electronics and Telecommunication Systems (LEST), affiliated with the French National Center for Scientific Research (CNRS). He later joined the University of Bordeaux and the CNRS laboratory IMS. He has published 300 technical papers in microwave and RF circuit synthesis, and is a senior member of the IEEE. Jacques Beneat received his PhD in electrical and computer engineering from Worcester Polytechnic Institute with a focus in advanced microwave structures for satellite communications, and a doctorate degree from the University of Bordeaux with Mention Très Honorable avec Félicitations du Jury. He was a research scientist at the Center for Wireless Information Network Studies at WPI and is currently Associate Professor of Electrical and Computer Engineering at Norwich University. Pierre Jarry and Jacques Beneat are the authors of the bestselling book Advanced Design Techniques and Realizations of Microwave an RF Filters, published by Wiley-IEEE Press and available also in electronic form.
FOREWORD. PREFACE. 1 MICROWAVE FILTER STRUCTURES. 1.1 Background. 1.2
Cavity Filters. 1.3 Planar Filters. 1.4 Planar Filter Technology. 1.5
Active Filters. 1.6 Superconductivity or HTS Filters. 1.7 Periodic
Structure Filters. 1.8 SAW Filters. 1.9 Micromachined Filters. 1.10
Summary. References. 2 IN-LINE SYNTHESIS OF PSEUDO-ELLIPTIC FILTERS. 2.1
Introduction. 2.2 Approximation and Synthesis. 2.3 Chebyshev Filters. 2.4
Pseudo-elliptic Filters. 2.5 Prototype Synthesis Examples. 2.6 Theoretical
Coupling Coefficients and External Quality Factors. References. 3 SUSPENDED
SUBSTRATE STRUCTURE. 3.1 Introduction. 3.2 Suspended Substrate Technology.
3.3 Unloaded Quality Factor of a Suspended Substrate Resonator. 3.4
Coupling Coefficients of Suspended Substrate Resonators. 3.5 Enclosure
Design Considerations. References. 4 MINIATURIZATION OF PLANAR RESONATORS
USING FRACTAL ITERATIONS. 4.1 Introduction. 4.2 Miniaturization of Planar
Resonators. 4.3 Fractal Iteration Applied to Planar Resonators. 4.4
Minkowski Resonators. 4.5 Hibert Resonators. References. 5 DESIGN AND
REALIZATIONS OF MEANDERED LINE FILTERS. 5.1 Introduction. 5.2 Third-order
Pseudo-elliptic Filters with Transmission Zero on the Right. 5.3
Third-order Pseudo-elliptic Filters with Transmission Zero on the Left.
References. 6 DESIGN AND REALIZATIONS OF HILBERT FILTERS. 6.1 Introduction.
6.2 Design of Hilbert Filters. 6.3 Realizations and Measured Performance.
References. 7 DESIGN AND REALIZATION OF DUAL-MODE MINKOWSKI FILTERS. 7.1
Introduction. 7.2 Study of Minkowski Dual-Mode Resonators. 7.3 Design of
Fourth-Order Pseudo-elliptic Filters with Two Transmission Zeros. 7.4
Realization and Measured Performance. References. APPENDIX 1: Equivalence
Between J and K Lowpass Prototypes. APPENDIX 2: Extraction of the Unloaded
Quality Factor of Suspended Substrate Resonators. INDEX.
Cavity Filters. 1.3 Planar Filters. 1.4 Planar Filter Technology. 1.5
Active Filters. 1.6 Superconductivity or HTS Filters. 1.7 Periodic
Structure Filters. 1.8 SAW Filters. 1.9 Micromachined Filters. 1.10
Summary. References. 2 IN-LINE SYNTHESIS OF PSEUDO-ELLIPTIC FILTERS. 2.1
Introduction. 2.2 Approximation and Synthesis. 2.3 Chebyshev Filters. 2.4
Pseudo-elliptic Filters. 2.5 Prototype Synthesis Examples. 2.6 Theoretical
Coupling Coefficients and External Quality Factors. References. 3 SUSPENDED
SUBSTRATE STRUCTURE. 3.1 Introduction. 3.2 Suspended Substrate Technology.
3.3 Unloaded Quality Factor of a Suspended Substrate Resonator. 3.4
Coupling Coefficients of Suspended Substrate Resonators. 3.5 Enclosure
Design Considerations. References. 4 MINIATURIZATION OF PLANAR RESONATORS
USING FRACTAL ITERATIONS. 4.1 Introduction. 4.2 Miniaturization of Planar
Resonators. 4.3 Fractal Iteration Applied to Planar Resonators. 4.4
Minkowski Resonators. 4.5 Hibert Resonators. References. 5 DESIGN AND
REALIZATIONS OF MEANDERED LINE FILTERS. 5.1 Introduction. 5.2 Third-order
Pseudo-elliptic Filters with Transmission Zero on the Right. 5.3
Third-order Pseudo-elliptic Filters with Transmission Zero on the Left.
References. 6 DESIGN AND REALIZATIONS OF HILBERT FILTERS. 6.1 Introduction.
6.2 Design of Hilbert Filters. 6.3 Realizations and Measured Performance.
References. 7 DESIGN AND REALIZATION OF DUAL-MODE MINKOWSKI FILTERS. 7.1
Introduction. 7.2 Study of Minkowski Dual-Mode Resonators. 7.3 Design of
Fourth-Order Pseudo-elliptic Filters with Two Transmission Zeros. 7.4
Realization and Measured Performance. References. APPENDIX 1: Equivalence
Between J and K Lowpass Prototypes. APPENDIX 2: Extraction of the Unloaded
Quality Factor of Suspended Substrate Resonators. INDEX.
FOREWORD. PREFACE. 1 MICROWAVE FILTER STRUCTURES. 1.1 Background. 1.2
Cavity Filters. 1.3 Planar Filters. 1.4 Planar Filter Technology. 1.5
Active Filters. 1.6 Superconductivity or HTS Filters. 1.7 Periodic
Structure Filters. 1.8 SAW Filters. 1.9 Micromachined Filters. 1.10
Summary. References. 2 IN-LINE SYNTHESIS OF PSEUDO-ELLIPTIC FILTERS. 2.1
Introduction. 2.2 Approximation and Synthesis. 2.3 Chebyshev Filters. 2.4
Pseudo-elliptic Filters. 2.5 Prototype Synthesis Examples. 2.6 Theoretical
Coupling Coefficients and External Quality Factors. References. 3 SUSPENDED
SUBSTRATE STRUCTURE. 3.1 Introduction. 3.2 Suspended Substrate Technology.
3.3 Unloaded Quality Factor of a Suspended Substrate Resonator. 3.4
Coupling Coefficients of Suspended Substrate Resonators. 3.5 Enclosure
Design Considerations. References. 4 MINIATURIZATION OF PLANAR RESONATORS
USING FRACTAL ITERATIONS. 4.1 Introduction. 4.2 Miniaturization of Planar
Resonators. 4.3 Fractal Iteration Applied to Planar Resonators. 4.4
Minkowski Resonators. 4.5 Hibert Resonators. References. 5 DESIGN AND
REALIZATIONS OF MEANDERED LINE FILTERS. 5.1 Introduction. 5.2 Third-order
Pseudo-elliptic Filters with Transmission Zero on the Right. 5.3
Third-order Pseudo-elliptic Filters with Transmission Zero on the Left.
References. 6 DESIGN AND REALIZATIONS OF HILBERT FILTERS. 6.1 Introduction.
6.2 Design of Hilbert Filters. 6.3 Realizations and Measured Performance.
References. 7 DESIGN AND REALIZATION OF DUAL-MODE MINKOWSKI FILTERS. 7.1
Introduction. 7.2 Study of Minkowski Dual-Mode Resonators. 7.3 Design of
Fourth-Order Pseudo-elliptic Filters with Two Transmission Zeros. 7.4
Realization and Measured Performance. References. APPENDIX 1: Equivalence
Between J and K Lowpass Prototypes. APPENDIX 2: Extraction of the Unloaded
Quality Factor of Suspended Substrate Resonators. INDEX.
Cavity Filters. 1.3 Planar Filters. 1.4 Planar Filter Technology. 1.5
Active Filters. 1.6 Superconductivity or HTS Filters. 1.7 Periodic
Structure Filters. 1.8 SAW Filters. 1.9 Micromachined Filters. 1.10
Summary. References. 2 IN-LINE SYNTHESIS OF PSEUDO-ELLIPTIC FILTERS. 2.1
Introduction. 2.2 Approximation and Synthesis. 2.3 Chebyshev Filters. 2.4
Pseudo-elliptic Filters. 2.5 Prototype Synthesis Examples. 2.6 Theoretical
Coupling Coefficients and External Quality Factors. References. 3 SUSPENDED
SUBSTRATE STRUCTURE. 3.1 Introduction. 3.2 Suspended Substrate Technology.
3.3 Unloaded Quality Factor of a Suspended Substrate Resonator. 3.4
Coupling Coefficients of Suspended Substrate Resonators. 3.5 Enclosure
Design Considerations. References. 4 MINIATURIZATION OF PLANAR RESONATORS
USING FRACTAL ITERATIONS. 4.1 Introduction. 4.2 Miniaturization of Planar
Resonators. 4.3 Fractal Iteration Applied to Planar Resonators. 4.4
Minkowski Resonators. 4.5 Hibert Resonators. References. 5 DESIGN AND
REALIZATIONS OF MEANDERED LINE FILTERS. 5.1 Introduction. 5.2 Third-order
Pseudo-elliptic Filters with Transmission Zero on the Right. 5.3
Third-order Pseudo-elliptic Filters with Transmission Zero on the Left.
References. 6 DESIGN AND REALIZATIONS OF HILBERT FILTERS. 6.1 Introduction.
6.2 Design of Hilbert Filters. 6.3 Realizations and Measured Performance.
References. 7 DESIGN AND REALIZATION OF DUAL-MODE MINKOWSKI FILTERS. 7.1
Introduction. 7.2 Study of Minkowski Dual-Mode Resonators. 7.3 Design of
Fourth-Order Pseudo-elliptic Filters with Two Transmission Zeros. 7.4
Realization and Measured Performance. References. APPENDIX 1: Equivalence
Between J and K Lowpass Prototypes. APPENDIX 2: Extraction of the Unloaded
Quality Factor of Suspended Substrate Resonators. INDEX.