| Description |
1 online resource (297 p.) |
| Contents |
Cover -- Title Page -- Copyright Page -- Preface -- Acknowledgements -- Table of Contents -- 1. Metamaterial and Sensing -- 1.1 Introduction -- 1.2 Concept of metamaterial & microwave sensing -- 1.3 Metamaterial based microwave sensor design Principle: resonator structure -- 1.4 Geometry design, fabrication and performances -- 1.5 Measurement method for metamaterial properties assessment -- 1.6 Metamaterial based microwave sensor design Principle: sandwich structure -- 1.7 Unit cell design with circuit modelling and performance |
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1.8 Sensitivity performance with absorption and polarization affects -- 1.9 Stacked DNG metamaterial for biosensing -- 1.10 Stacked DNG MTM scattering parameters and dielectric characteristics -- 1.11 Blood glutamate concentration sensing performance of the MTM unit cell -- 1.12 Summary -- 2. Liquid and Solid Material Sensing Using Metamaterial -- 2.1 Introduction -- 2.2 Metamaterials and microwave sensing -- 2.3 Importance of metamaterial sensor -- 2.4 Tri Circle SRR (TCSRR) shape metamaterial sensor design and analysis -- 2.5 Electric field and surface current distribution investigation |
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2.6 Double negative (DNG) metamaterial characteristics investigation -- 2.7 Parametric study -- 2.8 Mathematical modelling of the TCSRR based metamaterial sensor -- 2.9 Sensing performance evaluation -- 2.9.1 Dielectric constant investigation of oil samples -- 2.9.2 Loss tangent analysis of oil samples -- 2.9.3 Detection and evaluation of different LUTS using TCSRR structure -- 2.10 Design and analysis of complementary square SRR-based metamaterial -- 2.11 Effective parameters extraction methods -- 2.11.1 Metamaterial characteristics of the designed unit cell |
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2.11.2 Surface current, E-field, and H-field analysis -- 2.12 Equivalent circuit analysis -- 2.13 Parametric analysis -- 2.13.1 Effect of change of split gap -- 2.13.2 Effect of change of resonator width -- 2.13.3 Effect of change of substrate material -- 2.13.4 Metamaterial structure fabrication and experimental results analysis -- 2.13.5 Effective medium ratio (EMR) analysis -- 2.14 Materials and thickness sensing using the proposed sensor -- 2.14.1 Quality factor and sensitivity analysis -- 2.15 Summary -- 3. Metamaterial for Future Generation Wireless Communications -- 3.1 Introduction |
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3.2 Metamaterial's background -- 3.3 Metamaterial based mm-wave -- 3.4 Metamaterial particle design -- 3.4.1 Principle of metamaterial working -- 3.4.2 Metamaterial properties extraction -- 3.5 Metamaterial based Sub 6 GHz -- 3.5.1 Metamaterial example -- 3.6 Analysis, design and simulation of 5G metamaterial -- 3.7 Emerging metamaterial applications -- 3.7.1 Antennas -- gain improving -- 3.7.2 Miniaturizing of the size of antennas -- 3.7.3 Antenna's bandwidth enhancement -- 3.7.4 Metamaterials for multiband generation -- 3.7.5 Metasurface |
| Notes |
Description based upon print version of record |
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3.8 Summary of existing research related to DNG metamaterial |
| Subject |
Microwave devices -- Materials
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Microwave detectors -- Materials
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Microwave communication systems -- Materials
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Metamaterials.
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Metamaterials.
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Microwave devices -- Materials.
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| Form |
Electronic book
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| ISBN |
9781000919097 |
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1000919099 |
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