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Ultrafast photonic reinforcement learning based on laser chaos
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Optical Communication with Chaotic Lasers: Applications of Nonlinear Dynamics and Synchronization
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Posadas-Castillo, R. Skip to Main Content. Atsushi Uchida. First published: 9 March About this book Starting with an introduction to the fundamental physics in chaotic instabilities in laser systems, this comprehensive and unified reference goes on to present the techniques and technology of synchronization of chaos in coupled lasers, as well as the many applications to lasers and optics, communications, security and information technology.
Optical Communication with Chaotic Lasers | Wiley Online Books
Author Bios Atsushi Uchida received his Ph. He is an associate professor at the Department of Information and Computer Sciences at Saitama University in Saitama, Japan, and is currently working on synchronization of chaotic lasers, its applications for optical communication, secure key generation with chaotic lasers, and random number generation with chaotic lasers. Free Access. In addition to this topic the workshop covers the state of the art research on optical sensing, nonlinear spectro-microscopy, infrared spectroscopy and microscopy, Stimulated Raman SRS and CARS microscopy.
Nanostructured devices and materials offer a way to overcome the conventional light absorption limits. Novel optical spectrum splitting and photon-recycling schemes boost the efficiency of optical energy-conversion platforms. Furthermore, optical design concepts are rapidly expanding into the infrared energy band, offering new approaches to harvest waste heat and to reduce the thermal emission losses in solar-thermal and solar water desalination platforms.
Broadband engineering of the emission properties of optical materials and devices also paves the way to achieving noncontact radiative cooling of solar cells, electronic circuitries, buildings, and vehicles. Light—matter interaction enabled by nanophotonics and plasmonics underlie the performance of the third- and fourth-generation energy-conversion devices, including up- and down-conversion of photon energy, near-field radiative energy transfer, and hot electron generation and harvesting.
Miniaturization of the energy harvesting photonic devices combined with the recent effort in developing optical materials for fully passive thermal regulation via radiation holds the promise to revolutionize wearable technologies. Low-loss optical communication networks help to reduce the growing energy demands and environmental heating effects. This symposium will put in the spotlight these recent advances in photonics and their applications to traditional and emerging applications in energy generation and sustainability.
It seeks contributions offering transformative ideas on photon harvesting, spectral sorting, up- and down-conversion, emission control, and new applications beyond conventional solar cell technologies. Co-Chairs: Sebastian Volz, Tokyo University, Japan and Roberto Li Voti, University Rome, Italy Heat is one of the main forms of energy and its control is of critical importance to efficiently manage the energy resources of nature and global warming issues.
The symposium will bring together scientists, technology developers and young researchers who are interested in the theoretical tools and in the development and investigation of a large variety of new materials and applications.
Participants are encouraged to present their own results in the field. Its specific implementations span a large variety of systems ranging from single electronic spins over atomic systems to solid state structures at the nano- and micrometer scale, and it covers notably novel schemes for computation, communication and sensing.
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The focus of the joint symposium is the latter aspect in its broadest sense including the application of quantum technology tools and protocols for high-resolution scientific investigations.