The SOLNET (self-organized lightwave network) enables self-aligned optical coupling between misaligned optical devices with different core sizes, optical wiring in 3-D free spaces, and targeting lightwaves onto specific objects. These features make fabrication processes of optical networks within systems simpler to reduce the system cost. By reading this book, the readers can learn SOLNETs, their applications, and future challenges systematically. The readers can get hints to reduce the system cost by implementing optical solder and 3-D optical wiring of SOLNET into the systems.
The SOLNET (self-organized lightwave network) enables self-aligned optical coupling between misaligned optical devices with different core sizes, optical wiring in 3-D free spaces, and targeting lightwaves onto specific objects. These features make fabrication processes of optical networks within systems simpler to reduce the system cost. By reading this book, the readers can learn SOLNETs, their applications, and future challenges systematically. The readers can get hints to reduce the system cost by implementing optical solder and 3-D optical wiring of SOLNET into the systems.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
1. Introduction. 2. Related Technologies. 2.1 Self Focusing of Lightwaves in Nonlinear Optical Media. 2.2 Photosensitive Materials. Photopolymers, Photosensitive glass, Photorefractive crystals. Self Written Waveguides. 3. Self Organized Optical Waveguides Self Organized Lightwave Network (SOLNET). 3.1 Concept. Two Beam Writing SOLNET (TB SOLNET), Reflective SOLNET (R SOLNET), Luminescence Writing SOLNET (L SOLNET), Phosphor SOLNET (P SOLNET), SOLNETs utilizing One Photon and Two Photon photochemistry. 3.2 Features Self aligned optical coupling, 3 D optical wiring, Targeting lightwaves onto specific objects. 4. Proof of Concept by Computer Simulations. 4.1 TB SOLNET/P SOLNET. 4.2 R SOLNET. 4.3 L SOLNET. 4.4 SOLNET between Microscale and Nanoscale Waveguides. 4.5 Parallel and Branching SOLNET. 4.6 Vertical SOLNET for Optical Z Connections. 5. Experimental Demonstrations 5.1 TB SOLNET. Fiber and Fiber. 5.2 R SOLNET. Fiber and Mirror, Fiber and Luminescent target. 5.3 SOLNET between Microscale and Nanoscale Waveguides. Fiber and LD. 5.4 Branching SOLNET. Fiber and Two luminescent targets. 5.5 Vertical SOLNET. Mask window and Mirror, From 45o mirror in waveguide film. 6. Expected Applications. 6.1 Optical Solder. Self aligned optical coupling. 6.2 Integrated Optical Interconnects. Self aligned optical coupling/3 D optical wiring. 6.3 3 D Micro Optical Switching Systems. Self aligned optical coupling/3 D optical wiring. 6.4 Solar Energy Conversion Systems. Self aligned optical coupling/3 D optical wiring. 6.5 Cancer therapy. Targeting lightwaves onto specific objects. 7. Future Challenges. Re writable photosensitive materials for dynamic SOLNET. High Rn photosensitive materials for high index contrast SOLNET. Control of gamma characteristics of photosensitive materials for optimized SOLNET. Interference pattern with SOLNET. 8. Summary. Appendix: Methods for Computer Simulations of SOLNET. Beam propagation method, Finite difference time domain method
1. Introduction. 2. Related Technologies. 2.1 Self Focusing of Lightwaves in Nonlinear Optical Media. 2.2 Photosensitive Materials. Photopolymers, Photosensitive glass, Photorefractive crystals. Self Written Waveguides. 3. Self Organized Optical Waveguides Self Organized Lightwave Network (SOLNET). 3.1 Concept. Two Beam Writing SOLNET (TB SOLNET), Reflective SOLNET (R SOLNET), Luminescence Writing SOLNET (L SOLNET), Phosphor SOLNET (P SOLNET), SOLNETs utilizing One Photon and Two Photon photochemistry. 3.2 Features Self aligned optical coupling, 3 D optical wiring, Targeting lightwaves onto specific objects. 4. Proof of Concept by Computer Simulations. 4.1 TB SOLNET/P SOLNET. 4.2 R SOLNET. 4.3 L SOLNET. 4.4 SOLNET between Microscale and Nanoscale Waveguides. 4.5 Parallel and Branching SOLNET. 4.6 Vertical SOLNET for Optical Z Connections. 5. Experimental Demonstrations 5.1 TB SOLNET. Fiber and Fiber. 5.2 R SOLNET. Fiber and Mirror, Fiber and Luminescent target. 5.3 SOLNET between Microscale and Nanoscale Waveguides. Fiber and LD. 5.4 Branching SOLNET. Fiber and Two luminescent targets. 5.5 Vertical SOLNET. Mask window and Mirror, From 45o mirror in waveguide film. 6. Expected Applications. 6.1 Optical Solder. Self aligned optical coupling. 6.2 Integrated Optical Interconnects. Self aligned optical coupling/3 D optical wiring. 6.3 3 D Micro Optical Switching Systems. Self aligned optical coupling/3 D optical wiring. 6.4 Solar Energy Conversion Systems. Self aligned optical coupling/3 D optical wiring. 6.5 Cancer therapy. Targeting lightwaves onto specific objects. 7. Future Challenges. Re writable photosensitive materials for dynamic SOLNET. High Rn photosensitive materials for high index contrast SOLNET. Control of gamma characteristics of photosensitive materials for optimized SOLNET. Interference pattern with SOLNET. 8. Summary. Appendix: Methods for Computer Simulations of SOLNET. Beam propagation method, Finite difference time domain method
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