Sie sind bereits eingeloggt. Klicken Sie auf 2. tolino select Abo, um fortzufahren.
Bitte loggen Sie sich zunächst in Ihr Kundenkonto ein oder registrieren Sie sich bei bücher.de, um das eBook-Abo tolino select nutzen zu können.
This book presents and discusses strategies for the design and implementation of common-mode suppressed balanced microwave filters, including, narrowband, wideband, and ultra-wideband filters This book examines differential-mode, or balanced, microwave filters by discussing several implementations of practical realizations of these passive components. Topics covered include selective mode suppression, designs based on distributed and semi-lumped approaches, multilayer technologies, defect ground structures, coupled resonators, metamaterials, interference techniques, and substrate integrated…mehr
This book presents and discusses strategies for the design and implementation of common-mode suppressed balanced microwave filters, including, narrowband, wideband, and ultra-wideband filters This book examines differential-mode, or balanced, microwave filters by discussing several implementations of practical realizations of these passive components. Topics covered include selective mode suppression, designs based on distributed and semi-lumped approaches, multilayer technologies, defect ground structures, coupled resonators, metamaterials, interference techniques, and substrate integrated waveguides, among others. Divided into five parts, Balanced Microwave Filters begins with an introduction that presents the fundamentals of balanced lines, circuits, and networks. Part 2 covers balanced transmission lines with common-mode noise suppression, including several types of common-mode filters and the application of such filters to enhance common-mode suppression in balanced bandpass filters. Next, Part 3 examines wideband and ultra-wideband (UWB) balanced bandpass filters with intrinsic common-mode suppression. Narrowband and dual-band balanced bandpass filters with intrinsic common-mode suppression are discussed in Part 4. Finally, Part 5 covers other balanced circuits, such as balanced power dividers and combiners, and differential-mode equalizers with common-mode filtering. In addition, the book: * Explores a research topic of increasing interest due to the growing demand of balanced transmission lines and circuits in modern communication systems * Includes contributions from prominent worldwide experts in the field * Provides readers with the necessary knowledge to analyze and synthesize balanced filters and circuits Balanced Microwave Filters is an important text for R&D engineers, professionals, and specialists working on the topic of microwave filters. Post graduate students and Masters students in the field of microwave engineering and wireless communications, especially those involved in courses related to microwave filters, and balanced filters and circuits will also find it to be a vital resource.
Ferran Martín, IEEE Fellow, is a Full Professor of Electronics at Universitat Autònoma de Barcelona (UAB), Spain. Lei Zhu, IEEE Fellow, is a Full Professor in the Faculty of Science and Technology at the University of Macau, Macau SAR, China. Jiasheng Hong, IEEE Fellow, is a Full Professor in the Department of Electrical, Electronic and Computer Engineering at Heriot-Watt University, Edinburgh, UK. Francisco Medina, IEEE Fellow, is a Full Professor of Electromagnetism at Universidad de Sevilla, Seville, Spain
Inhaltsangabe
LIST OF CONTRIBUTORS xix
PREFACE xxiii
PART 1 INTRODUCTION 1
1 INTRODUCTION TO BALANCED TRANSMISSION LINES, CIRCUITS, AND NETWORKS 3 Ferran Martín, Jordi Naqui, Francisco Medina, Lei Zhu, and Jiasheng Hong
1.1 Introduction 3
1.2 Balanced Versus Single-Ended Transmission Lines and Circuits 4
1.3 Common-Mode Noise 5
1.4 Fundamentals of Differential Transmission Lines 6
1.4.1 Topology 6
1.4.2 Propagating Modes 8
1.4.2.1 Even and Odd Mode 8
1.4.2.2 Common and Differential Mode 11
1.5 Scattering Parameters 13
1.5.1 Single-Ended S-Parameters 13
1.5.2 Mixed-Mode S-Parameters 16
1.6 Summary 19
References 19
PART 2 BALANCED TRANSMISSION LINES WITH COMMON-MODE NOISE SUPPRESSION 21
2 STRATEGIES FOR COMMON-MODE SUPPRESSION IN BALANCED LINES 23 Ferran Martín, Paris Vélez, Armando Fernández-Prieto, Jordi Naqui, Francisco Medina, and Jiasheng Hong
2.1 Introduction 23
2.2 Selective Mode Suppression in Differential Transmission Lines 25
2.3 Common-Mode Suppression Filters Based on Patterned Ground Planes 27
2.3.1 Common-Mode Filter Based on Dumbbell-Shaped Patterned Ground Plane 27
2.3.2 Common-Mode Filter Based on Complementary Split Ring Resonators (CSRRs) 30
2.3.3 Common-Mode Filter Based on Defected Ground Plane Artificial Line 40
2.3.4 Common-Mode Filter Based on C-Shaped Patterned Ground Structures 44
2.4 Common-Mode Suppression Filters Based on Electromagnetic Bandgaps (EBGs) 49
2.4.1 Common-Mode Filter Based on Nonuniform Coupled Lines 50
2.4.2 Common-Mode Filter Based on Uniplanar Compact Photonic Bandgap (UC-PBG) Structure 55
2.5 Other Approaches for Common-Mode Suppression 55
2.6 Comparison of Common-Mode Filters 60
2.7 Summary 61
Appendix 2.A: Dispersion Relation for Common-Mode Rejection Filters with Coupled CSRRs or DS-CSRRs 61
Appendix 2.B: Dispersion Relation for Common-Mode Rejection Filters with Coupled Patches Grounded through Inductive Strips 64
References 65
3 COUPLED-RESONATOR BALANCED BANDPASS FILTERS WITH COMMON-MODE SUPPRESSION DIFFERENTIAL LINES 73 Armando Fernández-Prieto, Jordi Naqui, Jesús Martel, Ferran Martín, and Francisco Medina
3.1 Introduction 73
3.2 Balanced Coupled-Resonator Filters 74
3.2.1 Single-Band Balanced Bandpass Filter Based on Folded Stepped-Impedance Resonators 75
3.2.2 Balanced Filter Loaded with Common-Mode Rejection Sections 79
1 INTRODUCTION TO BALANCED TRANSMISSION LINES, CIRCUITS, AND NETWORKS 3 Ferran Martín, Jordi Naqui, Francisco Medina, Lei Zhu, and Jiasheng Hong
1.1 Introduction 3
1.2 Balanced Versus Single-Ended Transmission Lines and Circuits 4
1.3 Common-Mode Noise 5
1.4 Fundamentals of Differential Transmission Lines 6
1.4.1 Topology 6
1.4.2 Propagating Modes 8
1.4.2.1 Even and Odd Mode 8
1.4.2.2 Common and Differential Mode 11
1.5 Scattering Parameters 13
1.5.1 Single-Ended S-Parameters 13
1.5.2 Mixed-Mode S-Parameters 16
1.6 Summary 19
References 19
PART 2 BALANCED TRANSMISSION LINES WITH COMMON-MODE NOISE SUPPRESSION 21
2 STRATEGIES FOR COMMON-MODE SUPPRESSION IN BALANCED LINES 23 Ferran Martín, Paris Vélez, Armando Fernández-Prieto, Jordi Naqui, Francisco Medina, and Jiasheng Hong
2.1 Introduction 23
2.2 Selective Mode Suppression in Differential Transmission Lines 25
2.3 Common-Mode Suppression Filters Based on Patterned Ground Planes 27
2.3.1 Common-Mode Filter Based on Dumbbell-Shaped Patterned Ground Plane 27
2.3.2 Common-Mode Filter Based on Complementary Split Ring Resonators (CSRRs) 30
2.3.3 Common-Mode Filter Based on Defected Ground Plane Artificial Line 40
2.3.4 Common-Mode Filter Based on C-Shaped Patterned Ground Structures 44
2.4 Common-Mode Suppression Filters Based on Electromagnetic Bandgaps (EBGs) 49
2.4.1 Common-Mode Filter Based on Nonuniform Coupled Lines 50
2.4.2 Common-Mode Filter Based on Uniplanar Compact Photonic Bandgap (UC-PBG) Structure 55
2.5 Other Approaches for Common-Mode Suppression 55
2.6 Comparison of Common-Mode Filters 60
2.7 Summary 61
Appendix 2.A: Dispersion Relation for Common-Mode Rejection Filters with Coupled CSRRs or DS-CSRRs 61
Appendix 2.B: Dispersion Relation for Common-Mode Rejection Filters with Coupled Patches Grounded through Inductive Strips 64
References 65
3 COUPLED-RESONATOR BALANCED BANDPASS FILTERS WITH COMMON-MODE SUPPRESSION DIFFERENTIAL LINES 73 Armando Fernández-Prieto, Jordi Naqui, Jesús Martel, Ferran Martín, and Francisco Medina
3.1 Introduction 73
3.2 Balanced Coupled-Resonator Filters 74
3.2.1 Single-Band Balanced Bandpass Filter Based on Folded Stepped-Impedance Resonators 75
3.2.2 Balanced Filter Loaded with Common-Mode Rejection Sections 79