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Parts 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.
2.2.3 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.
4.1 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.
4.4.2 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.
2.2.3 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.
4.1 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.
4.4.2 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.