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024 7 $a10.1007/978-3-319-24566-9
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100   $a20151016d2016      u|         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aSymmetry Properties in Transmission Lines Loaded with Electrically Small Resonators $eCircuit Modeling and Applications /$fby Jordi Naqui
205   $a1st ed. 2016.
210  1$aCham :$cSpringer International Publishing :$cImprint: Springer,$d2016.
215   $a1 online resource (223 p.)
225 1 $aSpringer Theses, Recognizing Outstanding Ph.D. Research,$x2190-5053
300   $a"Doctoral Thesis accepted by Universitat Auto?noma de Barcelona, Spain."
311   $a3-319-24564-3 
327   $aParts of this thesis have been published in the following articles:; Journals; Conferences; Workshops; Supervisor's Foreword; Acknowledgments; Contents; About the Author; Acronyms; 1 Introduction; 1.1 Motivations; 1.2 Organization; 1.3 Funding; 2 Fundamentals of Planar Metamaterials  and Subwavelength Resonators; 2.1 Electromagnetic Metamaterials; 2.1.1 Material Classification; 2.1.2 Left-Handed Media; 2.2 Transmission-Line Metamaterials; 2.2.1 Application of the Transmission-Line Theory  to Metamaterials; 2.2.2 Composite Right-/Left-Handed (CRLH) Transmission Lines
327   $a2.2.3 CL-Loaded and Resonant-Type Approaches2.2.4 Resonant-Type Single-Negative Transmission Lines; 2.2.5 Discussion About Homogeneity and Periodicity; 2.3 Metamaterial-Based Resonators; 2.3.1 Split-Ring Resonator (SRR); 2.3.2 Double-Slit Split-Ring Resonator (DS-SRR); 2.3.3 Folded Stepped-Impedance Resonator (FSIR); 2.3.4 Electric Inductive-Capacitive (ELC) Resonator ; 2.3.5 Complementary Resonators; 2.4 Magneto- and Electro-Inductive Waves; 2.4.1 Magneto-Inductive Waves in Arrays  of Magnetically-Coupled Resonators; 2.4.2 Electro-Inductive Waves in Arrays  of Electrically-Coupled Resonators
327   $aReferences3 Advances in Equivalent Circuit Models  of Resonator-Loaded Transmission Lines; 3.1 Line-to-Resonator Magnetoelectric Coupling; 3.1.1 Coplanar Waveguides Loaded with Pairs of SRRs  and CSRR-Loaded Microstrip Lines; 3.2 Inter-Unit-Cell Inter-Resonator Coupling; 3.2.1 Coplanar Waveguides Loaded with Pairs of SRRs  and CSRR-Loaded Microstrip Lines; 3.3 Limits on the Synthesis of Electrically Small Resonators; 3.3.1 Microstrip Stepped-Impedance Shunt-Stubs (SISSs); References; 4 On the Symmetry Properties  of Resonator-Loaded Transmission  Lines
327   $a4.1 On the Symmetry Properties of Transmission Lines4.2 On the Alignment of Symmetry Planes; 4.2.1 SRR- and CSRR-Loaded Coplanar Waveguides; 4.2.2 SRR- and CSRR-Loaded Differential Microstrip Lines; 4.2.3 ELC- and MLC-Loaded Differential Microstrip Lines; 4.3 On the Misalignment of Symmetry Planes; 4.3.1 SRR- and FSIR-Loaded Coplanar Waveguides; 4.3.2 SIR-Loaded Microstrip Lines; 4.3.3 ELC-Loaded Coplanar Waveguides; 4.3.4 MLC-Loaded Microstrip Lines; 4.4 On the Generalization of Symmetry Rupture; 4.4.1 Microstrip Lines Loaded with Pairs of SISSs
327   $a4.4.2 Coplanar Waveguides Loaded with Pairs of SRRsReferences; 5 Application of Symmetry Properties  to Common-Mode Suppressed Differential Transmission Lines; 5.1 Introduction; 5.2 Symmetry-Based Selective Mode Suppression; 5.3 Common-Mode Suppressed Differential Microstrip Lines; 5.3.1 CSRR- and DS-CSRR-Loaded Differential Microstrip Lines; 5.3.2 ELC- and MLC-Loaded Differential Microstrip Lines; References; 6 Application of Symmetry Properties  to Microwave Sensors; 6.1 Introduction; 6.2 Symmetry-Based Sensing; 6.2.1 Coupling-Modulated Resonance
327   $a6.2.2 Resonance Frequency Splitting/Shifting
330   $aThis book discusses the analysis, circuit modeling, and applications of transmission lines loaded with electrically small resonators (mostly resonators inspired by metamaterials), focusing on the study of the symmetry-related electromagnetic properties of these loaded lines. It shows that the stopband functionality (resonance) that these lines exhibit can be controlled by the relative orientation between the line and the resonator, which determines their mutual coupling. Such resonance controllability, closely related to symmetry, is essential for the design of several microwave components, such as common-mode suppressed differential lines, novel microwave sensors based on symmetry disruption, and spectral signature radio-frequency barcodes. Other interesting aspects, such as stopband bandwidth enhancement (due to inter-resonator coupling, and related to complex modes) and magnetoelectric coupling between the transmission lines and split-ring resonators, are also included in the book.  .
410  0$aSpringer Theses, Recognizing Outstanding Ph.D. Research,$x2190-5053
606   $aMicrowaves
606   $aOptical engineering
606   $aOptical materials
606   $aElectronic materials
606   $aElectrical engineering
606   $aMicrowaves, RF and Optical Engineering$3https://scigraph.springernature.com/ontologies/product-market-codes/T24019
606   $aOptical and Electronic Materials$3https://scigraph.springernature.com/ontologies/product-market-codes/Z12000
606   $aCommunications Engineering, Networks$3https://scigraph.springernature.com/ontologies/product-market-codes/T24035
615  0$aMicrowaves.
615  0$aOptical engineering.
615  0$aOptical materials.
615  0$aElectronic materials.
615  0$aElectrical engineering.
615 14$aMicrowaves, RF and Optical Engineering.
615 24$aOptical and Electronic Materials.
615 24$aCommunications Engineering, Networks.
676   $a621.38132
700   $aNaqui$b Jordi$4aut$4http://id.loc.gov/vocabulary/relators/aut$0763794
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910254212303321
996   $aSymmetry Properties in Transmission Lines Loaded with Electrically Small Resonators$91550041
997   $aUNINA