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2008 IEEE MTT-S International Microwave Workshop Series (IMWS) on Art of Miniaturizing RF and Microwave Passive Components proceeding : December 14-15, 2008, University of Electronic Science and Technology of China, Chengdu, China / / proceeding editors, Xiao-Hong Tang and Shao-Qiu Xiao
| 2008 IEEE MTT-S International Microwave Workshop Series (IMWS) on Art of Miniaturizing RF and Microwave Passive Components proceeding : December 14-15, 2008, University of Electronic Science and Technology of China, Chengdu, China / / proceeding editors, Xiao-Hong Tang and Shao-Qiu Xiao |
| Pubbl/distr/stampa | New York : , : IEEE, , 2009 |
| Descrizione fisica | 1 online resource (238 pages) |
| Soggetto topico |
Electric filters
Microwave filters Strip transmission lines |
| ISBN |
1-5090-7782-0
1-4244-2877-7 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNISA-996203030203316 |
| New York : , : IEEE, , 2009 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. di Salerno | ||
| ||
2008 IEEE MTT-S International Microwave Workshop Series (IMWS) on Art of Miniaturizing RF and Microwave Passive Components proceeding : December 14-15, 2008, University of Electronic Science and Technology of China, Chengdu, China / / proceeding editors, Xiao-Hong Tang and Shao-Qiu Xiao
| 2008 IEEE MTT-S International Microwave Workshop Series (IMWS) on Art of Miniaturizing RF and Microwave Passive Components proceeding : December 14-15, 2008, University of Electronic Science and Technology of China, Chengdu, China / / proceeding editors, Xiao-Hong Tang and Shao-Qiu Xiao |
| Pubbl/distr/stampa | New York : , : IEEE, , 2009 |
| Descrizione fisica | 1 online resource (238 pages) |
| Soggetto topico |
Electric filters
Microwave filters Strip transmission lines |
| ISBN |
1-5090-7782-0
1-4244-2877-7 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910145401903321 |
| New York : , : IEEE, , 2009 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Advanced design techniques and realizations of microwave and RF filters / / Pierre Jarry, Jacques Beneat
| Advanced design techniques and realizations of microwave and RF filters / / Pierre Jarry, Jacques Beneat |
| Autore | Jarry Pierre <1946-> |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : J. Wiley & Sons, , c2008 |
| Descrizione fisica | 1 online resource (376 p.) |
| Disciplina |
621.381
621.3813224 |
| Altri autori (Persone) | BeneatJacques <1964-> |
| Soggetto topico |
Microwave filters
Electric filters |
| ISBN |
0-470-65264-0
1-281-73271-0 9786611732714 0-470-29417-5 1-61583-611-X 0-470-29416-7 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Foreword -- Preface -- Part I: Microwave Filter Fundamentals -- 1. Scattering Parameters and ABCD Matrices -- 2. Approximations and Synthesis -- 3. Waveguides and Transmission Lines -- 4. Categorization of Microwave Filters -- Part II: Minimum-Phase Filters -- 5. Capacitive-Gap Filters for Millimeter Waves -- 6. Evanescent-Mode Waveguide Filters with Dielectric Inserts -- 7. Interdigital Filters -- 8. Combline Filters Implemented In SSS -- Part III: Non-Minimum-Phase Symmetrical Response Filters -- 9. Generalized Interdigital Filters with Conditions on Amplitude and Phase -- 10. Temperature-Stable Narrowband Monomode TE011 Linear-Phase Filters -- Part IV: Non-Minimum-Phase Asymmetrical Response Filters -- 11. Asymmetrical Capacitive-Gap Coupled Line Filters -- 12. Asymmetrical Dual-Mode TE102 / TE301 Thick Iris Rectangular In-Line Waveguide Filters with Transmission Zeros -- 13. Asymmetrical Cylindrical Dual-Mode Waveguide Filters with Transmission Zeros -- 14. Asymmetrical Multimode Rectangular Building Block Filters Using Genetic Optimization -- Appendix 1: Lossless Systems -- Appendix 2: Redundant Elements -- Appendix 3: Modal Analysis of Waveguide Step Discontinuities -- Appendix 4: Trisections with Unity Inverters on the Inside or on the Outside -- Appendix 5: Reference Fields and Scattering Matrices for Multimodal Rectangular Waveguide Filters -- Index. |
| Record Nr. | UNINA-9910144138403321 |
Jarry Pierre <1946->
|
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| Hoboken, New Jersey : , : J. Wiley & Sons, , c2008 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Advanced design techniques and realizations of microwave and RF filters / / Pierre Jarry, Jacques Beneat
| Advanced design techniques and realizations of microwave and RF filters / / Pierre Jarry, Jacques Beneat |
| Autore | Jarry Pierre <1946-> |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : J. Wiley & Sons, , c2008 |
| Descrizione fisica | 1 online resource (376 p.) |
| Disciplina |
621.381
621.3813224 |
| Altri autori (Persone) | BeneatJacques <1964-> |
| Soggetto topico |
Microwave filters
Electric filters |
| ISBN |
0-470-65264-0
1-281-73271-0 9786611732714 0-470-29417-5 1-61583-611-X 0-470-29416-7 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Foreword -- Preface -- Part I: Microwave Filter Fundamentals -- 1. Scattering Parameters and ABCD Matrices -- 2. Approximations and Synthesis -- 3. Waveguides and Transmission Lines -- 4. Categorization of Microwave Filters -- Part II: Minimum-Phase Filters -- 5. Capacitive-Gap Filters for Millimeter Waves -- 6. Evanescent-Mode Waveguide Filters with Dielectric Inserts -- 7. Interdigital Filters -- 8. Combline Filters Implemented In SSS -- Part III: Non-Minimum-Phase Symmetrical Response Filters -- 9. Generalized Interdigital Filters with Conditions on Amplitude and Phase -- 10. Temperature-Stable Narrowband Monomode TE011 Linear-Phase Filters -- Part IV: Non-Minimum-Phase Asymmetrical Response Filters -- 11. Asymmetrical Capacitive-Gap Coupled Line Filters -- 12. Asymmetrical Dual-Mode TE102 / TE301 Thick Iris Rectangular In-Line Waveguide Filters with Transmission Zeros -- 13. Asymmetrical Cylindrical Dual-Mode Waveguide Filters with Transmission Zeros -- 14. Asymmetrical Multimode Rectangular Building Block Filters Using Genetic Optimization -- Appendix 1: Lossless Systems -- Appendix 2: Redundant Elements -- Appendix 3: Modal Analysis of Waveguide Step Discontinuities -- Appendix 4: Trisections with Unity Inverters on the Inside or on the Outside -- Appendix 5: Reference Fields and Scattering Matrices for Multimodal Rectangular Waveguide Filters -- Index. |
| Record Nr. | UNINA-9910831042603321 |
|
Jarry Pierre <1946->
|
||
| Hoboken, New Jersey : , : J. Wiley & Sons, , c2008 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Advanced design techniques and realizations of microwave and RF filters / Pierre Jarry, Jacques Beneat
| Advanced design techniques and realizations of microwave and RF filters / Pierre Jarry, Jacques Beneat |
| Autore | Jarry, Pierre, 1946- |
| Pubbl/distr/stampa | Hoboken, N.J. : J. Wiley & Sons : IEEE Press, c2008 |
| Descrizione fisica | xix, 354 p. : ill. ; 25 cm. |
| Disciplina | 621.38132 |
| Altri autori (Persone) | Beneat, Jacques, 1964-author |
| Soggetto topico | Microwave filters |
| ISBN | 9780470183106 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNISALENTO-991002482389707536 |
|
Jarry, Pierre, 1946-
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| Hoboken, N.J. : J. Wiley & Sons : IEEE Press, c2008 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. del Salento | ||
| ||
Balanced microwave filters / / edited by Ferran Martín, Lei Zhu, Jiasheng Hong, Francisco Medina
| Balanced microwave filters / / edited by Ferran Martín, Lei Zhu, Jiasheng Hong, Francisco Medina |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : John Wiley & Sons, , 2018 |
| Descrizione fisica | 1 online resource (689 pages) : illustrations |
| Disciplina | 621.3813224 |
| Collana | Wiley series in microwave and optical engineering |
| Soggetto topico | Microwave filters |
| ISBN |
1-119-23823-4
1-119-23762-9 1-119-23838-2 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
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 -- 3.2.3 Balanced Dual-Band Bandpass Filter Loaded with Common-Mode Rejection Sections 82 -- 3.3 Summary 88 -- References 88 -- PART 3 WIDEBAND AND ULTRA-WIDEBAND (UWB) BALANCED BAND PASS FILTERS WITH INTRINSIC COMMON-MODE SUPPRESSION 91 -- 4 WIDEBAND AND UWB BALANCED BANDPASS FILTERS BASED ON BRANCH-LINE TOPOLOGY 93 /Teck Beng Lim and Lei Zhu -- 4.1 Introduction 93 -- 4.2 Branch-Line Balanced Wideband Bandpass Filter 97 -- 4.3 Balanced Bandpass Filter for UWB Application 105 -- 4.4 Balanced Wideband Bandpass Filter with Good Common-Mode Suppression 111 -- 4.5 Highly Selective Balanced Wideband Bandpass Filters 116 -- 4.6 Summary 131 -- References 131 -- 5 WIDEBAND AND UWB COMMON-MODE SUPPRESSED DIFFERENTIAL-MODE FILTERS BASED ON COUPLED LINE SECTIONS 135 /Qing-Xin Chu, Shi-Xuan Zhang, and Fu-Chang Chen -- 5.1 Balanced UWB Filter by Combining UWB BPF with UWB BSF 135 -- 5.2 Balanced Wideband Bandpass Filter Using Coupled Line Stubs 142 -- 5.3 Balanced Wideband Filter Using Internal Cross-Coupling 148 -- 5.4 Balanced Wideband Filter Using Stub-Loaded Ring Resonator 155 -- 5.5 Balanced Wideband Filter Using Modified Coupled Feed Lines and Coupled Line Stubs 161 -- 5.6 Summary 173 -- References 174 -- 6 WIDEBAND DIFFERENTIAL CIRCUITS USING T-SHAPED STRUCTURES AND RING RESONATORS 177 /Wenquan Che and Wenjie Feng -- 6.1 Introduction 177 -- 6.2 Wideband Differential Bandpass Filters Using T-Shaped Resonators 179 -- 6.2.1 Mixed-Mode S-Parameters for Four-Port Balanced Circuits 179 -- 6.2.2 T-Shaped Structures with Open/Shorted Stubs 184. 6.2.2.1 T-Shaped Structure with Shorted Stubs 184 -- 6.2.2.2 T-Shaped Structure with Open Stubs 185 -- 6.2.3 Wideband Bandpass Filters without Cross Coupling 187 -- 6.2.3.1 Differential-Mode Excitation 189 -- 6.2.3.2 Common-Mode Excitation 191 -- 6.2.4 Wideband Bandpass Filter with Cross Coupling 193 -- 6.3 Wideband Differential Bandpass Filters Using Half-/Full-Wavelength Ring Resonators 201 -- 6.3.1 Differential Filter Using Half-Wavelength Ring Resonators 201 -- 6.3.2 Differential Filter Using Full-Wavelength Ring Resonators 206 -- 6.3.3 Differential Filter Using Open/Shorted Coupled Lines 215 -- 6.3.4 Comparisons of Several Wideband Balanced Filters Based on Different Techniques 220 -- 6.4 Wideband Differential Networks Using Marchand Balun 223 -- 6.4.1 S-Parameter for Six-Port Differential Network 223 -- 6.4.2 Wideband In-Phase Differential Network 227 -- 6.4.3 Wideband Out-of-Phase Differential Network 236 -- 6.5 Summary 244 -- References 245 -- 7 UWB AND NOTCHED-BAND UWB DIFFERENTIAL FILTERS USING MULTILAYER AND DEFECTED GROUND STRUCTURES (DGSS) 249 /Jian-Xin Chen, Li-Heng Zhou, and Quan Xue -- 7.1 Conventional Multilayer Microstrip-to-Slotline Transition (MST) 250 -- 7.2 Differential MST 251 -- 7.2.1 Differential MST with a Two-Layer Structure 251 -- 7.2.2 Differential MST with Three-Layer Structure 252 -- 7.3 UWB Differential Filters Based on the MST 253 -- 7.3.1 Differential Wideband Filters Based on the Conventional MST 253 -- 7.3.2 Differential Wideband Filters Based on the Differential MST 255 -- 7.4 Differential Wideband Filters Based on the Strip-Loaded Slotline Resonator 262 -- 7.4.1 Differential Wideband Filters Using Triple-Mode Slotline Resonator 265 -- 7.4.2 Differential Wideband Filters Using Quadruple-Mode Slotline Resonator 267 -- 7.5 UWB Differential Notched-Band Filter 270 -- 7.5.1 UWB Differential Notched-Band Filter Based on the Traditional MST 270 -- 7.5.2 UWB Differential Notched-Band Filter Based on the Differential MST 272 -- 7.6 Differential UWB Filters with Enhanced Stopband Suppression 277. 7.7 Summary 280 -- References 281 -- 8 APPLICATION OF SIGNAL INTERFERENCE TECHNIQUE TO THE IMPLEMENTATION OF WIDEBAND DIFFERENTIAL FILTERS 283 /Wei Qin and Quan Xue -- 8.1 Basic Concept of the Signal Interference Technique 283 -- 8.1.1 Fundamental Theory 284 -- 8.1.2 One Filter Example Based on Ring Resonator 287 -- 8.1.3 Simplified Circuit Model 288 -- 8.2 Signal Interference Technique for Wideband Differential Filters 290 -- 8.2.1 Circuit Model of Wideband Differential Bandpass Filter 290 -- 8.2.2 S-Matrix for Differential Bandpass Filters 292 -- 8.3 Several Designs of Wideband Differential Bandpass Filters 293 -- 8.3.1 Differential Bandpass Filter Based on Wideband Marchand Baluns 293 -- 8.3.2 Differential Bandpass Filter Based on π-Type UWB 180 Phase Shifters 299 -- 8.3.3 Differential Bandpass Filter Based on DSPSL UWB 180 Phase Inverter 302 -- 8.3.3.1 Differential-Mode Analysis 305 -- 8.3.3.2 Common-Mode Analysis 305 -- 8.3.3.3 Filter Design and Measurement 308 -- 8.4 Summary 308 -- References 309 -- 9 WIDEBAND BALANCED FILTERS BASED ON MULTI-SECTION MIRRORED STEPPED IMPEDANCE RESONATORS (SIRs) 311 /Ferran Martín, Jordi Selga, Paris Vélez, Marc Sans, Jordi Bonache, Ana Rodríguez, Vicente E. Boria, Armando Fernández-Prieto, and Francisco Medina -- 9.1 Introduction 311 -- 9.2 The Multi-Section Mirrored Stepped Impedance Resonator (SIR) 312 -- 9.3 Wideband Balanced Bandpass Filters Based on -- 7-Section Mirrored SIRs Coupled Through Admittance Inverters 317 -- 9.3.1 Finding the Optimum Filter Schematic 319 -- 9.3.2 Layout Synthesis 325 -- 9.3.2.1 Resonator Synthesis 325 -- 9.3.2.2 Determination of the Line Width 327 -- 9.3.2.3 Optimization of the Line Length (Filter Cell Synthesis) 327 -- 9.3.3 A Seventh-Order Filter Example 330 -- 9.3.4 Comparison with Other Approaches 334 -- 9.4 Compact Ultra-Wideband (UWB) Balanced Bandpass Filters Based on 5-Section Mirrored SIRs and Patch Capacitors 336 -- 9.4.1 Topology and Circuit Model of the Series Resonators 337. 9.4.2 Filter Design 341 -- 9.4.3 Comparison with Other Approaches 345 -- 9.5 Summary 346 -- Appendix 9.A: General Formulation of Aggressive Space Mapping (ASM) 347 -- References 349 -- 10 METAMATERIAL-INSPIRED BALANCED FILTERS 353 /Ferran Martín, Paris Vélez, Ali Karami-Horestani, Francisco Medina, and Christophe Fumeaux -- 10.1 Introduction 353 -- 10.2 Balanced Bandpass Filters Based on Open Split Ring ResonatorS (OSRRS) and Open Complementary Split Ring Resonators (OCSRRS) 354 -- 10.2.1 Topology of the OSRR and OCSRR 354 -- 10.2.2 Filter Design and Illustrative Example 356 -- 10.3 Balanced Filters Based on S-Shaped Complementary Split Ring Resonators (S-CSRRs) 363 -- 10.3.1 Principle for Balanced Bandpass Filter Design and Modeling 365 -- 10.3.2 Illustrative Example 367 -- 10.4 Summary 369 -- References 369 -- 11 WIDEBAND BALANCED FILTERS ON SLOTLINE RESONATOR WITH INTRINSIC COMMON-MODE REJECTION 373 /Xin Guo, Lei Zhu, and Wen Wu -- 11.1 Introduction 373 -- 11.2 Wideband Balanced Bandpass Filter on Slotline MMR 375 -- 11.2.1 Working Mechanism 375 -- 11.2.2 Synthesis Method 378 -- 11.2.3 Geometry and Layout 382 -- 11.2.4 Fabrication and Experimental Verification 388 -- 11.3 Wideband Balanced BPF on Strip-Loaded Slotline Resonator 392 -- 11.3.1 Strip-Loaded Slotline Resonator 392 -- 11.3.2 Wideband Balanced Bandpass Filters 396 -- 11.3.2.1 Wideband Balanced BPF on Strip-Loaded Triple-Mode Slotline Resonator 397 -- 11.3.2.2 Wideband Balanced BPF on Strip-Loaded Quadruple-Mode Slotline Resonator 403 -- 11.4 Wideband Balanced Bandpass Filter on Hybrid MMR 408 -- 11.4.1 Hybrid MMR 408 -- 11.4.2 Wideband Balanced Bandpass Filters 416 -- 11.5 Summary 420 -- References 420 -- PART 4 NARROWBAND AND DUAL-BAND BALANCED BANDPASS FILTERS WITH INTRINSIC COMMON-MODE SUPPRESSION 423 -- 12 NARROWBAND COUPLED-RESONATOR BALANCED BANDPASS FILTERS AND DIPLEXERS 425 /Armando Fernández-Prieto, Francisco Medina, and Jesús Martel -- 12.1 Introduction 425 -- 12.2 Coupled-Resonator Balanced Filters with Intrinsic Common-Mode Rejection 426. 12.2.1 Loop and SIR Resonator Filters with Mixed Coupling 427 -- 12.2.1.1 Quasi-elliptic Response BPF: First Example 428 -- 12.2.1.2 Quasi-elliptic Response BPF: Second Example 434 -- 12.2.2 Magnetically Coupled Open-Loop and FSIR Balanced Filters 439 -- 12.2.2.1 Filters with Magnetic Coupling: First Example 439 -- 12.2.2.2 Filters with Magnetic Coupling: Second Example 447 -- 12.2.3 Interdigital Line Resonators Filters 449 -- 12.2.3.1 ILR Filter Design Example 450 -- 12.2.4 Dual-Mode and Dual-Behavior Resonators for Balanced Filter Design 451 -- 12.2.4.1 Dual-Mode Square Patch Resonator Filters 453 -- 12.2.4.2 Filters Based on Dual-Behavior Resonators 458 -- 12.2.5 LTCC-Based Multilayer Balanced Filter 464 -- 12.2.6 Balanced Bandpass Filters Based on Dielectric Resonators 466 -- 12.3 Loaded Resonators for Common-Mode Suppression Improvement 469 -- 12.3.1 Capacitively, Inductively, and Resistively Center-Loaded Resonators 470 -- 12.3.1.1 Open-Loop UIR-Loaded Filter 470 -- 12.3.1.2 Folded SIR Loaded Filter 476 -- 12.3.2 Filters with Defected Ground Structures (DGS) 484 -- 12.3.2.1 Control of the Transmission Zeros 488 -- 12.3.3 Multilayer Loaded Resonators 490 -- 12.3.3.1 Design Example 492 -- 12.4 Coupled Line Balanced Bandpass Filter 493 -- 12.4.1 Type-II Design Example 495 -- 12.5 Balanced Diplexers 499 -- 12.5.1 Unbalanced-to-Balanced Diplexer Based on Uniform Impedance Stub-Loaded Coupled Resonators 500 -- 12.5.1.1 Resonator Geometry 500 -- 12.5.1.2 Unbalanced-to-Balanced Diplexer Design 502 -- 12.5.2 Example Two: Balanced-to-Balanced Diplexer Based on UIRs and Short-Ended Parallel-Coupled Lines 505 -- 12.6 Summary 508 -- References 510 -- 13 DUAL-BAND BALANCED FILTERS BASED ON LOADED AND COUPLED RESONATORS 515 /Jin Shi and Quan Xue -- 13.1 Dual-Band Balanced Filter with Loaded Uniform Impedance Resonators 516 -- 13.1.1 Center-Loaded Uniform Impedance Resonator 516 -- 13.1.2 Dual-Band Balanced Filter Using the Uniform Impedance Resonator with Center-Loaded Lumped Elements 520. 13.1.3 Dual-Band Balanced Filter Using Stub-Loaded Uniform Impedance Resonators 526 -- 13.2 Dual-Band Balanced Filter with Loaded Stepped-Impedance Resonators 528 -- 13.2.1 Center-Loaded Stepped-Impedance Resonator 528 -- 13.2.2 Dual-Band Balanced Filter Using Stepped-Impedance Resonators with Center-Loaded Lumped Elements 531 -- 13.2.3 Dual-Band Balanced Filter Using Stub-Loaded Stepped-Impedance Resonators 535 -- 13.3 Dual-Band Balanced Filter Based on Coupled Resonators 538 -- 13.3.1 Dual-Band Balanced Filter with Coupled Stepped-Impedance Resonators 538 -- 13.3.2 Dual-Band Balanced Filter with Coupled Stub-Loaded Short-Ended Resonators 542 -- 13.4 Summary 546 -- References 547 -- 14 DUAL-BAND BALANCED FILTERS IMPLEMENTED IN SUBSTRATE INTEGRATED WAVEGUIDE (SIW) TECHNOLOGY 549 /Wen Wu, Jianpeng Wang, and Chunxia Zhou -- 14.1 Substrate Integrated Waveguide (SIW) Cavity 550 -- 14.2 Closely Proximate Dual-Band Balanced Filter Design 551 -- 14.3 Dual-Band Balanced Filter Design Utilizing High-Order Modes in SIW Cavities 555 -- 14.4 Summary 563 -- References 563 -- PART 5 OTHER BALANCED CIRCUITS 565 -- 15 BALANCED POWER DIVIDERS/COMBINERS 567 /Lin-Sheng Wu, Bin Xia, and Jun-Fa Mao -- 15.1 Introduction 567 -- 15.2 Balanced-to-Balanced Wilkinson Power Divider with Microstrip Line 569 -- 15.2.1 Mixed-Mode Analysis 569 -- 15.2.1.1 Mixed-Mode Scattering Matrix of a Balanced-to-Balanced Power Divider 569 -- 15.2.1.2 Constraint Rules of Balanced-to-Balanced Power Divider 571 -- 15.2.1.3 Odd- and Even-Mode Scattering Matrices of Balanced-to-Balanced Power Divider 572 -- 15.2.2 A Transmission-Line Balanced-to-Balanced Power Divider 572 -- 15.2.2.1 Even-Mode Circuit Model 572 -- 15.2.2.2 Odd-Mode Circuit Model 573 -- 15.2.2.3 Scattering Matrix of the Balanced-to-Balanced Power Divider 575 -- 15.2.3 Theoretical Result 575 -- 15.2.4 Simulated and Measured Results 576 -- 15.3 Balanced-to-Balanced Gysel Power Divider with Half-Mode Substrate Integrated Waveguide (SIW) 580 -- 15.3.1 Conversion from Single-Ended Circuit to Balanced Form 580. 15.3.2 Half-Mode SIW Ring Structure 581 -- 15.3.3 Results and Discussion 583 -- 15.4 Balanced-to-Balanced Gysel Power Divider with Arbitrary Power Division 585 -- 15.4.1 Analysis and Design 585 -- 15.4.2 Results and Discussion 587 -- 15.5 Balanced-to-Balanced Gysel Power Divider with Bandpass Filtering Response 590 -- 15.5.1 Coupled-Resonator Circuit Model 590 -- 15.5.2 Realization in Transmission Lines 591 -- 15.5.2.1 Internal Coupling Coefficient 592 -- 15.5.2.2 External Q Factor 594 -- 15.5.3 Results and Discussion 595 -- 15.6 Filtering Balanced-to-Balanced Power Divider with Unequal Power Division 598 -- 15.7 Dual-Band Balanced-to-Balanced Power Divider 599 -- 15.7.1 Analysis and Design 599 -- 15.7.2 Results and Discussion 601 -- 15.8 Summary 603 -- References 603 -- 16 DIFFERENTIAL-MODE EQUALIZERS WITH COMMON-MODE FILTERING 607 /Tzong-Lin Wu and Chiu-Chih Chou -- 16.1 Introduction 607 -- 16.2 Design Considerations 610 -- 16.2.1 Equalizer Design 610 -- 16.2.2 Common-Mode Filter Design 612 -- 16.3 First Design 613 -- 16.3.1 Proposed Topology 613 -- 16.3.2 Odd-Mode Analysis 616 -- 16.3.2.1 Equalizer Optimization in Time Domain 617 -- 16.3.3 Even-Mode Analysis 623 -- 16.3.4 Measurement Validation 628 -- 16.4 Second Design 633 -- 16.4.1 Proposed Circuit and Analysis 633 -- 16.4.2 Realization and Measurement 637 -- 16.4.2.1 Realization 637 -- 16.4.2.2 Common-Mode Noise Suppression 638 -- 16.4.2.3 Differential-Mode Equalization 640 -- 16.5 Summary 641 -- References 641 -- INDEX 645. |
| Record Nr. | UNINA-9910270864203321 |
| Hoboken, New Jersey : , : John Wiley & Sons, , 2018 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Balanced microwave filters / / edited by Ferran Martín, Lei Zhu, Jiasheng Hong, Francisco Medina
| Balanced microwave filters / / edited by Ferran Martín, Lei Zhu, Jiasheng Hong, Francisco Medina |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : John Wiley & Sons, , 2018 |
| Descrizione fisica | 1 online resource (689 pages) : illustrations |
| Disciplina | 621.3813224 |
| Collana | Wiley series in microwave and optical engineering |
| Soggetto topico | Microwave filters |
| ISBN |
1-119-23823-4
1-119-23762-9 1-119-23838-2 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
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 -- 3.2.3 Balanced Dual-Band Bandpass Filter Loaded with Common-Mode Rejection Sections 82 -- 3.3 Summary 88 -- References 88 -- PART 3 WIDEBAND AND ULTRA-WIDEBAND (UWB) BALANCED BAND PASS FILTERS WITH INTRINSIC COMMON-MODE SUPPRESSION 91 -- 4 WIDEBAND AND UWB BALANCED BANDPASS FILTERS BASED ON BRANCH-LINE TOPOLOGY 93 /Teck Beng Lim and Lei Zhu -- 4.1 Introduction 93 -- 4.2 Branch-Line Balanced Wideband Bandpass Filter 97 -- 4.3 Balanced Bandpass Filter for UWB Application 105 -- 4.4 Balanced Wideband Bandpass Filter with Good Common-Mode Suppression 111 -- 4.5 Highly Selective Balanced Wideband Bandpass Filters 116 -- 4.6 Summary 131 -- References 131 -- 5 WIDEBAND AND UWB COMMON-MODE SUPPRESSED DIFFERENTIAL-MODE FILTERS BASED ON COUPLED LINE SECTIONS 135 /Qing-Xin Chu, Shi-Xuan Zhang, and Fu-Chang Chen -- 5.1 Balanced UWB Filter by Combining UWB BPF with UWB BSF 135 -- 5.2 Balanced Wideband Bandpass Filter Using Coupled Line Stubs 142 -- 5.3 Balanced Wideband Filter Using Internal Cross-Coupling 148 -- 5.4 Balanced Wideband Filter Using Stub-Loaded Ring Resonator 155 -- 5.5 Balanced Wideband Filter Using Modified Coupled Feed Lines and Coupled Line Stubs 161 -- 5.6 Summary 173 -- References 174 -- 6 WIDEBAND DIFFERENTIAL CIRCUITS USING T-SHAPED STRUCTURES AND RING RESONATORS 177 /Wenquan Che and Wenjie Feng -- 6.1 Introduction 177 -- 6.2 Wideband Differential Bandpass Filters Using T-Shaped Resonators 179 -- 6.2.1 Mixed-Mode S-Parameters for Four-Port Balanced Circuits 179 -- 6.2.2 T-Shaped Structures with Open/Shorted Stubs 184. 6.2.2.1 T-Shaped Structure with Shorted Stubs 184 -- 6.2.2.2 T-Shaped Structure with Open Stubs 185 -- 6.2.3 Wideband Bandpass Filters without Cross Coupling 187 -- 6.2.3.1 Differential-Mode Excitation 189 -- 6.2.3.2 Common-Mode Excitation 191 -- 6.2.4 Wideband Bandpass Filter with Cross Coupling 193 -- 6.3 Wideband Differential Bandpass Filters Using Half-/Full-Wavelength Ring Resonators 201 -- 6.3.1 Differential Filter Using Half-Wavelength Ring Resonators 201 -- 6.3.2 Differential Filter Using Full-Wavelength Ring Resonators 206 -- 6.3.3 Differential Filter Using Open/Shorted Coupled Lines 215 -- 6.3.4 Comparisons of Several Wideband Balanced Filters Based on Different Techniques 220 -- 6.4 Wideband Differential Networks Using Marchand Balun 223 -- 6.4.1 S-Parameter for Six-Port Differential Network 223 -- 6.4.2 Wideband In-Phase Differential Network 227 -- 6.4.3 Wideband Out-of-Phase Differential Network 236 -- 6.5 Summary 244 -- References 245 -- 7 UWB AND NOTCHED-BAND UWB DIFFERENTIAL FILTERS USING MULTILAYER AND DEFECTED GROUND STRUCTURES (DGSS) 249 /Jian-Xin Chen, Li-Heng Zhou, and Quan Xue -- 7.1 Conventional Multilayer Microstrip-to-Slotline Transition (MST) 250 -- 7.2 Differential MST 251 -- 7.2.1 Differential MST with a Two-Layer Structure 251 -- 7.2.2 Differential MST with Three-Layer Structure 252 -- 7.3 UWB Differential Filters Based on the MST 253 -- 7.3.1 Differential Wideband Filters Based on the Conventional MST 253 -- 7.3.2 Differential Wideband Filters Based on the Differential MST 255 -- 7.4 Differential Wideband Filters Based on the Strip-Loaded Slotline Resonator 262 -- 7.4.1 Differential Wideband Filters Using Triple-Mode Slotline Resonator 265 -- 7.4.2 Differential Wideband Filters Using Quadruple-Mode Slotline Resonator 267 -- 7.5 UWB Differential Notched-Band Filter 270 -- 7.5.1 UWB Differential Notched-Band Filter Based on the Traditional MST 270 -- 7.5.2 UWB Differential Notched-Band Filter Based on the Differential MST 272 -- 7.6 Differential UWB Filters with Enhanced Stopband Suppression 277. 7.7 Summary 280 -- References 281 -- 8 APPLICATION OF SIGNAL INTERFERENCE TECHNIQUE TO THE IMPLEMENTATION OF WIDEBAND DIFFERENTIAL FILTERS 283 /Wei Qin and Quan Xue -- 8.1 Basic Concept of the Signal Interference Technique 283 -- 8.1.1 Fundamental Theory 284 -- 8.1.2 One Filter Example Based on Ring Resonator 287 -- 8.1.3 Simplified Circuit Model 288 -- 8.2 Signal Interference Technique for Wideband Differential Filters 290 -- 8.2.1 Circuit Model of Wideband Differential Bandpass Filter 290 -- 8.2.2 S-Matrix for Differential Bandpass Filters 292 -- 8.3 Several Designs of Wideband Differential Bandpass Filters 293 -- 8.3.1 Differential Bandpass Filter Based on Wideband Marchand Baluns 293 -- 8.3.2 Differential Bandpass Filter Based on π-Type UWB 180 Phase Shifters 299 -- 8.3.3 Differential Bandpass Filter Based on DSPSL UWB 180 Phase Inverter 302 -- 8.3.3.1 Differential-Mode Analysis 305 -- 8.3.3.2 Common-Mode Analysis 305 -- 8.3.3.3 Filter Design and Measurement 308 -- 8.4 Summary 308 -- References 309 -- 9 WIDEBAND BALANCED FILTERS BASED ON MULTI-SECTION MIRRORED STEPPED IMPEDANCE RESONATORS (SIRs) 311 /Ferran Martín, Jordi Selga, Paris Vélez, Marc Sans, Jordi Bonache, Ana Rodríguez, Vicente E. Boria, Armando Fernández-Prieto, and Francisco Medina -- 9.1 Introduction 311 -- 9.2 The Multi-Section Mirrored Stepped Impedance Resonator (SIR) 312 -- 9.3 Wideband Balanced Bandpass Filters Based on -- 7-Section Mirrored SIRs Coupled Through Admittance Inverters 317 -- 9.3.1 Finding the Optimum Filter Schematic 319 -- 9.3.2 Layout Synthesis 325 -- 9.3.2.1 Resonator Synthesis 325 -- 9.3.2.2 Determination of the Line Width 327 -- 9.3.2.3 Optimization of the Line Length (Filter Cell Synthesis) 327 -- 9.3.3 A Seventh-Order Filter Example 330 -- 9.3.4 Comparison with Other Approaches 334 -- 9.4 Compact Ultra-Wideband (UWB) Balanced Bandpass Filters Based on 5-Section Mirrored SIRs and Patch Capacitors 336 -- 9.4.1 Topology and Circuit Model of the Series Resonators 337. 9.4.2 Filter Design 341 -- 9.4.3 Comparison with Other Approaches 345 -- 9.5 Summary 346 -- Appendix 9.A: General Formulation of Aggressive Space Mapping (ASM) 347 -- References 349 -- 10 METAMATERIAL-INSPIRED BALANCED FILTERS 353 /Ferran Martín, Paris Vélez, Ali Karami-Horestani, Francisco Medina, and Christophe Fumeaux -- 10.1 Introduction 353 -- 10.2 Balanced Bandpass Filters Based on Open Split Ring ResonatorS (OSRRS) and Open Complementary Split Ring Resonators (OCSRRS) 354 -- 10.2.1 Topology of the OSRR and OCSRR 354 -- 10.2.2 Filter Design and Illustrative Example 356 -- 10.3 Balanced Filters Based on S-Shaped Complementary Split Ring Resonators (S-CSRRs) 363 -- 10.3.1 Principle for Balanced Bandpass Filter Design and Modeling 365 -- 10.3.2 Illustrative Example 367 -- 10.4 Summary 369 -- References 369 -- 11 WIDEBAND BALANCED FILTERS ON SLOTLINE RESONATOR WITH INTRINSIC COMMON-MODE REJECTION 373 /Xin Guo, Lei Zhu, and Wen Wu -- 11.1 Introduction 373 -- 11.2 Wideband Balanced Bandpass Filter on Slotline MMR 375 -- 11.2.1 Working Mechanism 375 -- 11.2.2 Synthesis Method 378 -- 11.2.3 Geometry and Layout 382 -- 11.2.4 Fabrication and Experimental Verification 388 -- 11.3 Wideband Balanced BPF on Strip-Loaded Slotline Resonator 392 -- 11.3.1 Strip-Loaded Slotline Resonator 392 -- 11.3.2 Wideband Balanced Bandpass Filters 396 -- 11.3.2.1 Wideband Balanced BPF on Strip-Loaded Triple-Mode Slotline Resonator 397 -- 11.3.2.2 Wideband Balanced BPF on Strip-Loaded Quadruple-Mode Slotline Resonator 403 -- 11.4 Wideband Balanced Bandpass Filter on Hybrid MMR 408 -- 11.4.1 Hybrid MMR 408 -- 11.4.2 Wideband Balanced Bandpass Filters 416 -- 11.5 Summary 420 -- References 420 -- PART 4 NARROWBAND AND DUAL-BAND BALANCED BANDPASS FILTERS WITH INTRINSIC COMMON-MODE SUPPRESSION 423 -- 12 NARROWBAND COUPLED-RESONATOR BALANCED BANDPASS FILTERS AND DIPLEXERS 425 /Armando Fernández-Prieto, Francisco Medina, and Jesús Martel -- 12.1 Introduction 425 -- 12.2 Coupled-Resonator Balanced Filters with Intrinsic Common-Mode Rejection 426. 12.2.1 Loop and SIR Resonator Filters with Mixed Coupling 427 -- 12.2.1.1 Quasi-elliptic Response BPF: First Example 428 -- 12.2.1.2 Quasi-elliptic Response BPF: Second Example 434 -- 12.2.2 Magnetically Coupled Open-Loop and FSIR Balanced Filters 439 -- 12.2.2.1 Filters with Magnetic Coupling: First Example 439 -- 12.2.2.2 Filters with Magnetic Coupling: Second Example 447 -- 12.2.3 Interdigital Line Resonators Filters 449 -- 12.2.3.1 ILR Filter Design Example 450 -- 12.2.4 Dual-Mode and Dual-Behavior Resonators for Balanced Filter Design 451 -- 12.2.4.1 Dual-Mode Square Patch Resonator Filters 453 -- 12.2.4.2 Filters Based on Dual-Behavior Resonators 458 -- 12.2.5 LTCC-Based Multilayer Balanced Filter 464 -- 12.2.6 Balanced Bandpass Filters Based on Dielectric Resonators 466 -- 12.3 Loaded Resonators for Common-Mode Suppression Improvement 469 -- 12.3.1 Capacitively, Inductively, and Resistively Center-Loaded Resonators 470 -- 12.3.1.1 Open-Loop UIR-Loaded Filter 470 -- 12.3.1.2 Folded SIR Loaded Filter 476 -- 12.3.2 Filters with Defected Ground Structures (DGS) 484 -- 12.3.2.1 Control of the Transmission Zeros 488 -- 12.3.3 Multilayer Loaded Resonators 490 -- 12.3.3.1 Design Example 492 -- 12.4 Coupled Line Balanced Bandpass Filter 493 -- 12.4.1 Type-II Design Example 495 -- 12.5 Balanced Diplexers 499 -- 12.5.1 Unbalanced-to-Balanced Diplexer Based on Uniform Impedance Stub-Loaded Coupled Resonators 500 -- 12.5.1.1 Resonator Geometry 500 -- 12.5.1.2 Unbalanced-to-Balanced Diplexer Design 502 -- 12.5.2 Example Two: Balanced-to-Balanced Diplexer Based on UIRs and Short-Ended Parallel-Coupled Lines 505 -- 12.6 Summary 508 -- References 510 -- 13 DUAL-BAND BALANCED FILTERS BASED ON LOADED AND COUPLED RESONATORS 515 /Jin Shi and Quan Xue -- 13.1 Dual-Band Balanced Filter with Loaded Uniform Impedance Resonators 516 -- 13.1.1 Center-Loaded Uniform Impedance Resonator 516 -- 13.1.2 Dual-Band Balanced Filter Using the Uniform Impedance Resonator with Center-Loaded Lumped Elements 520. 13.1.3 Dual-Band Balanced Filter Using Stub-Loaded Uniform Impedance Resonators 526 -- 13.2 Dual-Band Balanced Filter with Loaded Stepped-Impedance Resonators 528 -- 13.2.1 Center-Loaded Stepped-Impedance Resonator 528 -- 13.2.2 Dual-Band Balanced Filter Using Stepped-Impedance Resonators with Center-Loaded Lumped Elements 531 -- 13.2.3 Dual-Band Balanced Filter Using Stub-Loaded Stepped-Impedance Resonators 535 -- 13.3 Dual-Band Balanced Filter Based on Coupled Resonators 538 -- 13.3.1 Dual-Band Balanced Filter with Coupled Stepped-Impedance Resonators 538 -- 13.3.2 Dual-Band Balanced Filter with Coupled Stub-Loaded Short-Ended Resonators 542 -- 13.4 Summary 546 -- References 547 -- 14 DUAL-BAND BALANCED FILTERS IMPLEMENTED IN SUBSTRATE INTEGRATED WAVEGUIDE (SIW) TECHNOLOGY 549 /Wen Wu, Jianpeng Wang, and Chunxia Zhou -- 14.1 Substrate Integrated Waveguide (SIW) Cavity 550 -- 14.2 Closely Proximate Dual-Band Balanced Filter Design 551 -- 14.3 Dual-Band Balanced Filter Design Utilizing High-Order Modes in SIW Cavities 555 -- 14.4 Summary 563 -- References 563 -- PART 5 OTHER BALANCED CIRCUITS 565 -- 15 BALANCED POWER DIVIDERS/COMBINERS 567 /Lin-Sheng Wu, Bin Xia, and Jun-Fa Mao -- 15.1 Introduction 567 -- 15.2 Balanced-to-Balanced Wilkinson Power Divider with Microstrip Line 569 -- 15.2.1 Mixed-Mode Analysis 569 -- 15.2.1.1 Mixed-Mode Scattering Matrix of a Balanced-to-Balanced Power Divider 569 -- 15.2.1.2 Constraint Rules of Balanced-to-Balanced Power Divider 571 -- 15.2.1.3 Odd- and Even-Mode Scattering Matrices of Balanced-to-Balanced Power Divider 572 -- 15.2.2 A Transmission-Line Balanced-to-Balanced Power Divider 572 -- 15.2.2.1 Even-Mode Circuit Model 572 -- 15.2.2.2 Odd-Mode Circuit Model 573 -- 15.2.2.3 Scattering Matrix of the Balanced-to-Balanced Power Divider 575 -- 15.2.3 Theoretical Result 575 -- 15.2.4 Simulated and Measured Results 576 -- 15.3 Balanced-to-Balanced Gysel Power Divider with Half-Mode Substrate Integrated Waveguide (SIW) 580 -- 15.3.1 Conversion from Single-Ended Circuit to Balanced Form 580. 15.3.2 Half-Mode SIW Ring Structure 581 -- 15.3.3 Results and Discussion 583 -- 15.4 Balanced-to-Balanced Gysel Power Divider with Arbitrary Power Division 585 -- 15.4.1 Analysis and Design 585 -- 15.4.2 Results and Discussion 587 -- 15.5 Balanced-to-Balanced Gysel Power Divider with Bandpass Filtering Response 590 -- 15.5.1 Coupled-Resonator Circuit Model 590 -- 15.5.2 Realization in Transmission Lines 591 -- 15.5.2.1 Internal Coupling Coefficient 592 -- 15.5.2.2 External Q Factor 594 -- 15.5.3 Results and Discussion 595 -- 15.6 Filtering Balanced-to-Balanced Power Divider with Unequal Power Division 598 -- 15.7 Dual-Band Balanced-to-Balanced Power Divider 599 -- 15.7.1 Analysis and Design 599 -- 15.7.2 Results and Discussion 601 -- 15.8 Summary 603 -- References 603 -- 16 DIFFERENTIAL-MODE EQUALIZERS WITH COMMON-MODE FILTERING 607 /Tzong-Lin Wu and Chiu-Chih Chou -- 16.1 Introduction 607 -- 16.2 Design Considerations 610 -- 16.2.1 Equalizer Design 610 -- 16.2.2 Common-Mode Filter Design 612 -- 16.3 First Design 613 -- 16.3.1 Proposed Topology 613 -- 16.3.2 Odd-Mode Analysis 616 -- 16.3.2.1 Equalizer Optimization in Time Domain 617 -- 16.3.3 Even-Mode Analysis 623 -- 16.3.4 Measurement Validation 628 -- 16.4 Second Design 633 -- 16.4.1 Proposed Circuit and Analysis 633 -- 16.4.2 Realization and Measurement 637 -- 16.4.2.1 Realization 637 -- 16.4.2.2 Common-Mode Noise Suppression 638 -- 16.4.2.3 Differential-Mode Equalization 640 -- 16.5 Summary 641 -- References 641 -- INDEX 645. |
| Record Nr. | UNINA-9910828163803321 |
| Hoboken, New Jersey : , : John Wiley & Sons, , 2018 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Correlation of electric field and critical design parameters for ferroelectric tunable microwave filters / / Guru Subramanyam [and six others]
| Correlation of electric field and critical design parameters for ferroelectric tunable microwave filters / / Guru Subramanyam [and six others] |
| Autore | Subramanyam Guru |
| Pubbl/distr/stampa | Cleveland, Ohio : , : National Aeronautics and Space Administration, Glenn Research Center, , November 2000 |
| Descrizione fisica | 1 online resource (13 pages) : illustrations |
| Collana | NASA/TM |
| Soggetto topico |
Correlation
Electric fields Ferroelectricity Tunable filters Microwave filters |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910706239303321 |
|
Subramanyam Guru
|
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| Cleveland, Ohio : , : National Aeronautics and Space Administration, Glenn Research Center, , November 2000 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Electromagnetic Propagation and Waveguides in Photonics and Microwave Engineering / / edited by Patrick Steglich
| Electromagnetic Propagation and Waveguides in Photonics and Microwave Engineering / / edited by Patrick Steglich |
| Pubbl/distr/stampa | London : , : IntechOpen, , 2020 |
| Descrizione fisica | 1 online resource (192 pages) : illustrations |
| Disciplina | 621.3 |
| Soggetto topico |
Microwave filters
Optical wave guides Wave-motion, Theory of |
| ISBN | 1-83968-189-6 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910424647003321 |
| London : , : IntechOpen, , 2020 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Electromagnetic Propagation and Waveguides in Photonics and Microwave Engineering / / edited by Patrick Steglich
| Electromagnetic Propagation and Waveguides in Photonics and Microwave Engineering / / edited by Patrick Steglich |
| Pubbl/distr/stampa | London : , : IntechOpen, , 2020 |
| Descrizione fisica | 1 online resource (xi, 192 pages) : illustrations |
| Disciplina | 621.3813224 |
| Soggetto topico |
Optical wave guides
Wave-motion, Theory of Microwave filters |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910688355003321 |
| London : , : IntechOpen, , 2020 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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