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دانلود کتاب Plasma Antennas
دانلود کتاب آنتنای پلاسما
مشخصات کتاب
Plasma Antennas
ویرایش: [2 ed.]
نویسندگان: Theodore R. Anderson
سری: Artech House Antennas and Electromagnetics Analysis Library
ISBN (شابک) : 9781630817510, 1630817511
ناشر: Artech House
سال نشر: 2021
تعداد صفحات: [390]
زبان: English
فرمت فایل : PDF (درصورت درخواست کاربر به PDF، EPUB یا AZW3 تبدیل می شود)
حجم فایل: 96 Mb
قیمت کتاب (تومان) : 63,000
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فهرست مطالب
Plasma Antennas Second Edition Contents Foreword Foreword to the Second Edition Preface Preface to the Second Edition Acknowledgments Acknowledgments to the Second Edition 1 Introduction References 2 Plasma Physics for Plasma Antennas 2.1 Mathematical Models of Plasma Physics 2.2 Man-Made Plasmas and Some Applications 2.3 Basic Physics of Reflection and Transmission from a Plasma Slab Barrier 2.4 Experiments of Scattering Off of a Plasma Cylinder 2.5 Governing Plasma Fluid Equations for Applications to Plasma Antennas 2.6 Incident Signal on a Cylindrical Plasma 2.7 Fourier Expansion of the Plasma Antenna Current Density 2.8 Plasma Antenna Poynting Vector 2.9 Some Finite Element Solution Techniques for Plasma Antennas 2.9.1 Barrier Penetration 2.9.2 Calculation of Scaling Function References 3 Fundamental Plasma Antenna Theory 3.1 Net Radiated Power from a Center-Fed Dipole Plasma Antenna 3.2 Reconfigurable Impedance of a Plasma Antenna 3.3 Thermal Noise in Plasma Antennas References 4 Building a Basic Plasma Antenna 4.1 Introduction 4.2 Electrical Safety Warning 4.3 Building a Basic Plasma Antenna: Design I 4.4 Building a Basic Plasma Antenna: Design II 4.5 Materials 4.6 Building a Basic Plasma Antenna: Design III 5 Plasma Antenna Nesting, Stacking Plasma Antenna Arrays, and Reductionof Cosite Interference 5.1 Introduction 5.2 Physics of Reflection and Transmission of Electromagnetic Waves Through Plasma 5.3 Nested Plasma Antenna Concept 5.3.1 Example of Nested Plasma Antennas 5.4 Cosite Interference Reduction Using Plasma Antennas 5.5 Plasma Antenna Nesting Experiments References 6 Plasma Antenna Windowing: Foundation of the Smart Plasma Antenna Design 6.1 Introduction 6.2 The Smart Plasma Antenna Design: The Windowing Concept 6.2.1 Multiband Plasma Antennas Concept 6.2.2 Multiband and Multilobe or Both Plasma Antennas Concept 6.3 Theoretical Analysis with Numerical Results of Plasma Windows 6.3.1 Geometric Construction 6.3.2 Electromagnetic Boundary Value Problem 6.3.3 Partial Wave Expansion: Addition Theorem for Hankel Functions 6.3.4 Setting Up the Matrix Problem 6.3.5 Exact Solution for the Scattered Fields 6.3.6 Far-Field Radiation Pattern 6.3.7 Eight-Lobe Radiation Patterns for the Plasma Antenna Windowing Device 6.3.8 Dissipation in the Plasma Window Structure: Energy Conservationin an Open Resonant Cavity References 7 Smart Plasma Antennas 7.1 Introduction 7.2 Smart Antennas 7.3 Early Design and Experimental Work for the Smart Plasma Antenna 7.4 Microcontroller for the Smart Plasma Antenna 7.5 Commercial Smart Plasma Antenna Prototype 7.6 Reconfigurable Bandwidth of the Smart Plasma Antenna 7.7 Effect of Polarization on Plasma Tubes in the Smart Plasma Antenna 7.8 Generation of Dense Plasmas at Low Average Power Input by Power Pulsing: An Energy-Efficient Technique to Obtain High-Frequency Plasma Antennas 7.9 Fabry-Perot Resonator for Faster Operation of the Smart Plasma Antenna 7.9.1 Mathematical Model for a Plasma Fabry-Perot Cavity 7.9.2 Slab Plasma 7.9.3 Cylindrical Plasma 7.10 Speculative Applications of the Smart Plasma Antenna in Wireless Technologies 7.10.1 Introduction 7.10.2 GPS-Aided and GPS-Free Positioning 7.10.3 Multihop Meshed Wireless Distribution Network Architecture 7.10.5 Adaptive Directionality 7.10.6 Cell Tower Setting 8 Plasma Frequency Selective Surfaces 8.1 Introduction 8.2.1 Method of Calculation 8.2.2 Scattering from a Partially Conducting Cylinder 8.3 Results 8.3.1 Switchable Bandstop Filter 8.3.2 Switchable Reflector References 9 Experimental Work 9.1 Introduction 9.2 Fundamental Plasma Antenna Experiments 9.3 Suppressing or Eliminating EMI Noise Created by the Spark-Gap Technique 9.4 Conclusions on the Plasma Reflector Antenna 9.5 Plasma Waveguides 9.6 Plasma Frequency Selective Surfaces 9.7 Pulsing Technique 9.8 Plasma Antenna Nesting Experiment 9.9 High-Power Plasma Antennas 9.9.1 Introduction 9.9.2 The High-Power Problem 9.9.3 The High-Power Solution 9.9.4 Experimental Confirmation 9.9.5 Conclusions on High-Power Plasma Antennas 9.10 Basic Plasma Density and Plasma Frequency Measurements 9.11 Plasma Density Plasma Frequency Measurements with a Microwave Interferometer and Preionization 9.11.1 Experiments on the Reflection in the S-Band Waveguide at 3.0 GHz with High Purity Argon Plasma 9.12 Ruggedization and Mechanical Robustness of Plasma Antennas 9.12.1 Embedded Plasma Antenna in Sandstone Slurry 9.12.2 Embedded Plasma Antenna in SynFoam 9.13 Miniaturization of Plasma Antennas References 10 Directional and Electronically Steerable Plasma Antenna Systemsby Reconfigurable Multipole Expansions of Plasma Antennas 10.1 Introduction 10.2 Multipole Plasma Antenna Designs and Far Fields References 11 Satellite Plasma Antenna Concepts 11.1 Introduction 11.2 Data Rates 11.3 Satellite Plasma Antenna Concepts and Designs References 12 Plasma Antenna Thermal Noise 12.1 Introduction 12.2 Modified Nyquist Theorem and Thermal Noise References 13 Steering, Focusing, and Spreading of Antenna Beams Using the Physics of Refraction of EM Waves through a Plasma 13.1 Introduction 13.2 Basic Physics of Refraction Theory of Electromagnetic Waves Propagating Through a Plasma 13.3 Antenna Beam Focusing from Refraction through Plasma Experiments and Simulations 13.3.1 Peak Current versus Average Current Due to Pulsing to Ionize the Gas into a Plasma 13.3.2 Experiments on Focusing Antenna Beams with the Physics of Refraction through a Plasma 13.3.3 Simulation of Plasma Focusing by Refraction through a Plasma 13.3.4 Three-Dimensional Simulation of Plasma Focusing by Refraction through a Plasma with 10-GHz Plasma Frequency and 24-GHz Incident Frequency 13.4 Antenna Beam Steering with Refraction through a Plasma 13.4.1 Experiment with Steering from Refraction through a Plasma with 5-Amp and 8-Amp Peak Current in Pulsing 13.4.2 Experiment with Steering from Refraction through a Plasma with 5-Amp and 8-Amp Peak Current in Pulsing 13.4.3 Simulations of Steering Antenna Beams by Refraction through the Plasma with Incident Frequency of 44 GHz and Various Plasma Frequencies 13.4.4 Experiment with Steering from Refraction through a Plasma with 5-Amp and 8-Amp Peak Current in Pulsing 13.4.5 Simulations of Steering Antenna Beams by Refraction through the Plasma with Frequencies of 35 GHz to 45 GHz and Plasma Frequency Fixed at 22.9 GHz 13.4.6 Experiment with Steering from Refraction through a Plasma with 0-Amp and 8-Amp Peak Current in Pulsing 13.4.7 Simulation with Steering from Refraction through a Plasma with 0-Amp and 8-Amp Peak Current in Pulsing, Plasma Frequency 20 GHz, and Incident Frequency 44 GHz 13.4.8 3-D Simulation with Steering from Refraction through a Plasma with 8-Amp Peak Current in Pulsing, Plasma Frequency 20 GHz, and Incident Frequency 44 GHz 13.5 Simulations of Antenna Beam Steering by Refraction through a Plasma with Variations in Plasma Frequency with Main Lobe and Sidelobe Characteristics 13.6 Basic Plasma Beam-Steering Device 13.7 Antenna Beam Spreading by Refraction of EM Waves through a Plasma 13.8 Summary of Using Plasma to Focus, Steer, and Spread Antenna Beams References 14 Pulsing Circuitry for Ionizing Plasma Antennas with Low-Power and High-Plasma Density Requirements and Surface Wave Excitation withSurfatrons 14.1 Pulsing Circuit to Ionize the Plasma with High Plasma Density and Low Power 14.2 High-Voltage Pulse Forming Network for Faster and More Efficient Pulse Generation 14.3 Ionization of the Gas into a Plasma by Surface Waves 14.3.1 Introduction to Surface Wave Ionization with Surfatrons References 15 Radiation Patterns, S11, and VSWR of the Smart Plasma Antenna 15.1 Introduction 15.2 Basic Smart Plasma Antenna Design 15.2.1 Typical Characteristic Plasma Values in a COTS Tube Used as a Plasma Antenna 15.3 Experimental Setup of Smart Plasma Antenna Measurements 15.3.1 Smart Plasma Antenna Tube Configurations in which Radiation Patterns were Measured 15.4 Resonance Frequency of the Smart Plasma Antenna 15.5 Measurements of S11 and VSWR 15.6 Smart Plasma Antenna Radiation Patterns 15.6.1 Radiation Pattern Measurement in an Open Field 15.6.2 Radiation Pattern Measurements in a Satimo Chamber 15.6.3 Directivity of the Smart Plasma Antenna 15.7 Simulations on the Smart Plasma Antenna with One Tube Off 15.8 VSWR Measurements on the First and Fundamental Resonance of the Smart Plasma Antenna 15.9 Future Design Improvements to Increase Gain 15.10 Wi-Fi Estimations of the Smart Plasma Antenna 15.11 Applications to 5 G and Cellular in General 15.12 Plasma Antenna with Variable Magnetic Field and Plasma Density References 16 Magnetic Resonance Imaging and Positron Emission Tomography Using Plasma Antennas 16.1 Introduction 16.2 The Problem with Metal RF Coils in an MRI Machine 16.3 Basic Plasma Antenna Used in Place of Metal RF Coils 16.4 Plasma Ignition in a Strong Magnetic Field 16.5 Ionizing the Gas with Surface Waves and the Surfatron Matching Circuits 16.6 Imaging Experiments with Basic Plasma Antennas 16.7 Positron Emission Tomography with Plasma Antenna RF Coils References 17 Experiments on Cosite Interference, VSWR, and Noise of Plasma Antennas 17.1 Introduction 17.2 Cosite Interference 17.3 VSWR 17.4 Experimental Measurements of Noise 17.5 Part 2 Experiments of Cosite Interference and VSWR 17.5.1 Impedance Matching 17.5.2 30- to 88-MHz Plasma Antenna 17.5.3 116- to 174-MHz VHF Band References 18 Plasma Metamaterial Antennas and Plasma Metamaterial Frequency Selective Surfaces, Atmospheric Plasma Antennas, Plasma Resonanceson Plasma Dipole Antennas, and Progress on Ruggedization of Plasma Antennas 18.1 Plasma Metamaterials and Plasma Photonic Bandgaps for Plasma Antennas and Plasma Frequency Selective Surfaces 18.2 Experiment in Scattering Electromagnetic Waves Off of Metal Photonic Crystal with a Metal Tube Replaced by a Plasma Column 18.3 Atmospheric Plasma Antennas 18.4 Plasma Resonances on a Cylindrical Plasma 18.4.1 Experiments and Simulations on Plasma Resonances of a Cylindrical Plasma Column 18.4.2 Simulations and Experiments of Resonances in a Plasma Dipole Antenna with a 100-MHz to 5-GHz Sweep 18.4.3 Understanding Some Charateristics of the Plasma by Pulsing the Plasma and Observing the Plasma Recombination or Decay of a Cylindrical Plasma Column 18.4.4 Simulations on a Plasma Dipole Antenna as a Function of Density and Gas Type 18.4.5 Electrically Small Monopole Antennas Using Plasma Physics 18.5 Minimum Ionization Current to Create a Plasma Antenna 18.6 Preionization Current to Make Ionization Faster and withLess Power 18.7 Progress on Ruggedization on Plasma Antennas 18.8 Radio Communication with Hypersonic Aerial Vehicle by Treating Plasma Sheath as an Antenna References About the Author Index
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