Reservoir computing is a brain-inspired approach for information processing, well suited to analog implementations. We report a photonic implementation of a reservoir computer that exploits frequency domain multiplexing to encode neuron states. The system processes 25 comb lines simultaneously (i.e. 25 neurons), at a rate of 20 MHz. We illustrate performances on two standard benchmark tasks: channel equalization and time series forecasting. We also demonstrate that frequency multiplexing allows output weights to be implemented in the optical domain, through optical attenuation. We discuss the perspectives for high-speed, high-performance, low-footprint implementations.info:eu-repo/semantics/publishe
Despite ever increasing computational power, recognition and classification problems remain challeng...
In this thesis we study photonic computation within the framework of reservoir computing. Inspired b...
Reservoir computing (RC), a computational paradigm inspired on neural systems, has become increasing...
Photonic reservoir computing uses recent advances in machine learning, and in particular the reservo...
Reservoir computers (RCs) are randomized recurrent neural networks well adapted to process time seri...
Reservoir Computing[1] is a new approach to study and use Neural Networks, which try to mimic a brai...
International audienceWe review a novel paradigm that has emerged in analogue neuromorphic optical c...
Reservoir computing is a recent bio-inspired approach for processing time-dependent signals. It has ...
The recent progress in artificial intelligence has spurred renewed interest in hardware implementati...
International audienceReservoir computing, originally referred to as an echo state network or a liqu...
International audienceMany information processing challenges are difficult to solve with traditional...
42th European Conference on Optical Communication Proceedings, September 18 – 22, 2016, Düsseldorf, ...
We study numerically a realistic model of an original autonomous implementation of a photonic neural...
We present our latest results on silicon photonics neuromorphic information processing based a.o. on...
We present our latest results on silicon photonics neuromorphic information processing based on tech...
Despite ever increasing computational power, recognition and classification problems remain challeng...
In this thesis we study photonic computation within the framework of reservoir computing. Inspired b...
Reservoir computing (RC), a computational paradigm inspired on neural systems, has become increasing...
Photonic reservoir computing uses recent advances in machine learning, and in particular the reservo...
Reservoir computers (RCs) are randomized recurrent neural networks well adapted to process time seri...
Reservoir Computing[1] is a new approach to study and use Neural Networks, which try to mimic a brai...
International audienceWe review a novel paradigm that has emerged in analogue neuromorphic optical c...
Reservoir computing is a recent bio-inspired approach for processing time-dependent signals. It has ...
The recent progress in artificial intelligence has spurred renewed interest in hardware implementati...
International audienceReservoir computing, originally referred to as an echo state network or a liqu...
International audienceMany information processing challenges are difficult to solve with traditional...
42th European Conference on Optical Communication Proceedings, September 18 – 22, 2016, Düsseldorf, ...
We study numerically a realistic model of an original autonomous implementation of a photonic neural...
We present our latest results on silicon photonics neuromorphic information processing based a.o. on...
We present our latest results on silicon photonics neuromorphic information processing based on tech...
Despite ever increasing computational power, recognition and classification problems remain challeng...
In this thesis we study photonic computation within the framework of reservoir computing. Inspired b...
Reservoir computing (RC), a computational paradigm inspired on neural systems, has become increasing...