دانلود کتاب Terahertz Dielectric Resonator Antennas for High Speed Communication and Sensing: From theory to design and implementation

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Cover
Contents
About the author
Preface
1 Dielectric resonator antennas (DRAs) and its synthesis
1.1 Introduction
1.2 CDRA (cylindrical DRA): design and modeling using silicon-radiating element
1.3 Terahertz or quantum devices characteristics
1.3.1 Theory of TDRA
1.3.2 Terahertz DRA or quantum DRA near fields/far fields
1.3.3 Radiation parameters
1.3.4 Drude’s model theory
1.4 Terahertz MIMO DRA parameters
1.4.1 Microwave DRAs vs optical DRA parameters
1.4.2 Optical DRAs
1.4.3 Radiated fields
1.5 Main functions of terahertz DRA
1.5.1 Some important parameters of microwave and terahertz DRA
1.6 THz DRA model design parameters
1.7 Rectangular nano-DRA design parameters
1.7.1 Design steps
1.8 Conclusion
References
2 Dielectric resonator antennas—a comprehensive review
2.1 Introduction
2.2 Propagation of light
2.3 Design of a terahertz dielectric resonator antenna
2.4 Fabrication and testing
2.5 Terahertz antenna far-field radiations: flowchart
2.6 Mathematical analysis of terahertz RDRA
2.7 Approximate analysis of a rectangular quantum antenna
2.8 Terahertz DRA simulation results
2.9 Conclusion
References
3 Light–matter interaction in terahertz dielectric resonator antennas (DRA)
3.1 Introduction
3.2 Light–matter interaction theory in a quantum antenna
3.3 Theory of quantum entanglement
3.4 Conclusion
Reference
4 Terahertz dielectric resonator antennas design and modeling
4.1 Introduction to terahertz DRA
4.2 Mathematical formulations used to describe working of quantum DRA
4.3 Cylindrical terahertz DRA
4.4 Conical terahertz DRA
4.5 Conclusion
References
5 Surface plasmon polytrons (SPP) into terahertz DRA
5.1 Introduction
5.2 Working principle of TDRA
5.3 Terahertz CDRA design and simulations
5.4 Terahertz DRA main features
5.5 Mathematical formulations used in TDRA
5.6 Terahertz DRA applications
5.7 Conclusion
References
6 Terahertz conical dielectric resonator antenna—design, simulation and implementations
6.1 Introduction
6.2 Design structure of conical THz DRAs
6.3 Model-1 multiband conical TDRA
6.4 Mathematical modeling of terahertz conical DRA
6.5 Equivalent electrical circuit of conical terahertz DRA
6.6 Conclusion
References
7 Cylindrical terahertz and optical DRA—design and analysis
7.1 Introduction
7.2 Model 2 TCDRA at 10-THz resonant frequency
7.2.1 Design computations
7.3 Terahertz antennas detailed description
7.4 Theory of terahertz cylindrical DRA and mathematical formulations
7.5 Optical CDRA description
7.6 Conclusion
References
8 Spherical terahertz and optical DRA—design and implementations
Abstract
8.1 Introduction
8.2 Design of terahertz spherical DRA at 511 THz
8.3 Mathematical formulations of terahertz spherical DRA
8.4 Results and discussions
8.4.1 Super directivity in spherical DRA
8.5 MIMO (multi-input–multi-output) spherical DRA
8.6 Conclusion
References
9 Rectangular terahertz DRA—design, simulation and implementations
9.1 Introduction
9.2 Propagation of light
9.3 Design and simulation of terahertz dielectric resonator antenna
9.4 Synthesis of a terahertz rectangular DRA at optical frequency and its radiation theory
9.5 Mathematical analysis of resonant modes excited into a terahertz rectangular DRA
9.6 Terahertz optical RDRA at 484 THz
9.6.1 Approximate analysis of a rectangular terahertz DRA and its controlled electromagnetic fields
9.7 Conclusion
References
10 Equivalent circuit analysis on terahertz and optical dielectric resonator antennas (DRAs)
10.1 Introduction
10.2 Quantum DRA-equivalent circuit mathematical analysis for mixed circuits
10.2.1 Impedance (Zin)
10.2.2 The frequency-dependent resistance is also called dynamic resistance of the circuit
10.2.3 Two resonant modes, i.e. fundamental and higher order
10.2.4 Second resonant mode
10.3 Higher order resonant modes
10.4 Bandwidth (BW) of terahertz DRA
10.5 Simulated results based on MATLAB
10.6 Design development and evaluation of NDRA
10.6.1 Resonant frequency of TRDRA formulations
10.7 Synthesis of NDRA radiation theory
10.8 Drude’s model
10.9 MATLAB program
10.10 Conclusion
References
11 Optical DRA for retinal applications—next generation DRAs
11.1 Introduction
11.2 Optical antenna arrays basic requirements
11.3 Optical antenna design
11.4 Entanglement
11.5 Modeling of optical antennas
11.6 Light–matter interaction
11.7 Theory of coupled resonant modes
11.8 Designs of terahertz DRAs simulation results for various shapes
11.9 Conclusion and applications
References
12 Conclusion and futuristic vision
12.1 Introduction
12.2 Patient-centric healthcare system outline
12.3 Thumb DRA sensors integrated with patient-centric healthcare system
12.4 Thumb DRA design and implementations
12.5 Conclusion
Appendix A: Case studies
Appendix B: Terahertz absorbers
B.1 Absorber characteristics
B.2 Absorbers mathematical analysis
B.3 Optical absorbers applications
Appendix C: Antenna measured values in anechoic chamber
Appendix D: Dielectric materials and resources
Appendix E: Dual-band graphene antenna design and implementation
Appendix F: Miniaturization design techniques
F.1 Introduction
F.2 Conclusion
Appendix G: Gaussian beam feed process
Appendix H: Silicon dielectric resonator antenna at 5-THz frequency
H.1 THz DRA fabrication process
Appendix I: DRA designing process
I.1 Design process of aperture coupled DRA
Appendix J: DRA design case study
Appendix K: Vector network analyzer process for calibration
Glossary
Index
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