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Summary
Microring/nanoring resonator is an interesting device that has been widely studied and investigated by researchers from a variety of specializations. This book begins with the basic background of linear and nonlinear ring resonators. A novel design of nano device known as a PANDA ring resonator is proposed. The use of the device in the form of a PANDA in applications such as nanoelectronics, measurement, communication, sensors, optical and quantum computing, drug delivery, hybrid transistor and a new concept of electron-hole pair is discussed in detail.
Table of Contents
| Linear and Nonlinear Ring Resonators | p. 1 |
| Introduction | p. 1 |
| A Linear Microring Resonator | p. 3 |
| A Linear Add/Drop Filter | p. 4 |
| Characteristics of Complementary Ring-resonator Add/drop | p. 4 |
| Graphical Representation of Photonic Circuits | p. 5 |
| Photonic Transfer Functions | p. 6 |
| Simulation Results | p. 9 |
| Vernier Effect | p. 13 |
| Transfer Function of a Single-ring Resonator Filter | p. 15 |
| Transfer Function of Double-ring Resonator Vernier Filter | p. 16 |
| Transfer Function of a Triple-ring Resonator Vernier Filter | p. 17 |
| Simulation Results | p. 19 |
| All-Pass and Add/Drop Filter | p. 24 |
| A Nonlinear Microring Resonator | p. 31 |
| A Nonlinear Add/Drop Filter | p. 35 |
| The effect of TPA | p. 39 |
| The Impact of Coupling Coefficient | p. 40 |
| The Impact of Wavelength | p. 41 |
| The Impact of TOE | p. 41 |
| The Impact of Photon Lifetime | p. 42 |
| Conclusion | p. 43 |
| References | p. 44 |
| A PANDA Ring Resonator | p. 53 |
| Introduction | p. 53 |
| Theory and Modeling | p. 54 |
| Dynamic Pulse Propagation | p. 60 |
| Symmetry and Asymmetry PANDA Ring Resonators | p. 67 |
| Random Binary Code Generation | p. 70 |
| Binary Code Suppression and Recovery | p. 77 |
| Conclusion | p. 80 |
| References | p. 80 |
| Dark-Bright Soliton Conversion | p. 83 |
| Introduction | p. 83 |
| Operating Principle | p. 85 |
| Soliton Nonlinear Behaviors | p. 87 |
| Optical Soliton | p. 90 |
| Dark-Bright Soliton Conversion | p. 93 |
| Dark-Bright Soliton Conversion in Add/Drop Filter | p. 95 |
| Soliton Collision Management in a Microring Resonator | p. 99 |
| Soliton Collision Management | p. 102 |
| Conclusion | p. 105 |
| References | p. 107 |
| Dynamic Optical Tweezers | p. 111 |
| Introduction | p. 111 |
| The Add/Drop Optical Filter | p. 113 |
| Storage Trapping Tool | p. 115 |
| Dynamic Potential Well Generation | p. 117 |
| Dynamic Optical Tweezers via a Wavelength Router | p. 122 |
| Trapping Forces | p. 123 |
| Trapping Stability | p. 124 |
| Trapping and Transportation Mechanism | p. 126 |
| Atom/Molecule Transmission and Transportation via Wavelength Router | p. 128 |
| Conclusion | p. 129 |
| References | p. 130 |
| Hybrid Interferometer | p. 133 |
| Introduction | p. 133 |
| Theoretical Background | p. 134 |
| Hybrid Interferometer | p. 138 |
| Conclusions | p. 144 |
| References | p. 144 |
| Hybrid Transceiver | p. 147 |
| Introduction | p. 147 |
| Theory | p. 148 |
| Hybrid Transceiver and Repeater | p. 153 |
| Hybrid Transceiver | p. 154 |
| Hybrid Repeater | p. 157 |
| Conclusion | p. 157 |
| References | p. 158 |
| Nanocommunication | p. 161 |
| Introduction | p. 161 |
| Multi Variable Quantum Tweezers Generation and Modulation | p. 162 |
| Molecular Transporter Generation for Quantum-Molecular Transmission | p. 169 |
| Transporter Generation | p. 170 |
| Transporter Quantum State | p. 174 |
| Multi Quantum-Molecular Transportation | p. 176 |
| Conclusion | p. 177 |
| References | p. 178 |
| Nanosensors | p. 183 |
| Introduction | p. 183 |
| Operating Principle | p. 184 |
| Distributed Spatial Sensors | p. 285 |
| Distributed Quantum Sensors | p. 189 |
| Network Sensors using a PANDA Ring Resonator Type | p. 192 |
| General Review | p. 192 |
| Principle and Method | p. 193 |
| Distributed Network Sensors Using a Microring Sensing Transducer | p. 196 |
| Self-calibration in a Fiber Optic Sensing System | p. 199 |
| General Review | p. 199 |
| Operation Principle | p. 200 |
| Entangled Photon States Walk-off Compensation | p. 203 |
| Conclusion | p. 207 |
| References | p. 208 |
| Optical and Quantum Computing | p. 213 |
| Introduction | p. 213 |
| Quantum Controlled-NOT (CNOT) Gate | p. 214 |
| Quantum SWAP Gate | p. 217 |
| All-optical Logic Gate | p. 218 |
| Dark-Bright Soliton Conversion Mechanism | p. 220 |
| Optical XOR/XNOR Logic Gate Operation | p. 221 |
| Operation Principle of Simultaneous All-optical Logic Gates | p. 225 |
| OOK Generation | p. 227 |
| Conclusion | p. 237 |
| References | p. 238 |
| Drug Delivery | p. 245 |
| Introduction | p. 245 |
| Optical Vortex Generation | p. 247 |
| Drug Trapping and Delivery | p. 252 |
| Conclusion | p. 255 |
| References | p. 255 |
| Hybrid Transistor | p. 259 |
| Introduction | p. 259 |
| All-Optical Photonic Transistor | p. 260 |
| Single-Photon Transistor | p. 268 |
| Single-Photon Transistor using Microtoroidal Resonators | p. 268 |
| Single-Photon Transistor using Nanoscale Surface Plasmons | p. 268 |
| Single-Atom Transistor | p. 273 |
| Single-Electron Transistor | p. 275 |
| Single-Molecule Transistor | p. 277 |
| Photonic Transistor using PANDA Ring | p. 279 |
| Conclusion | p. 285 |
| References | p. 285 |
| Electron-Hole Pair Manipulation | p. 291 |
| Introduction | p. 292 |
| Single Electron-Hole Pair Generation | p. 292 |
| Multi Electron-Hole Pair Generation | p. 296 |
| Conclusion | p. 299 |
| References | p. 299 |
| Index | p. 301 |
| Table of Contents provided by Ingram. All Rights Reserved. |
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