Photonic reservoir computer based on frequency multiplexing
Lorenz Butschek, Akram Akrout, Evangelia Dimitriadou, Alessandro Lupo, Marc Haelterman, Serge Massar
2022Optics Letters34 citationsDOIOpen Access PDF Abstract
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.
Topics & Concepts
MultiplexingReservoir computingComputer sciencePhotonicsChannel (broadcasting)Electronic engineeringBenchmark (surveying)ENCODEWavelength-division multiplexingOpticsFrequency domainPhotonic integrated circuitEqualization (audio)Signal processingOrthogonal frequency-division multiplexingSeries (stratigraphy)Optical computingFrequency-division multiplexingOptical communicationModulation (music)Domain (mathematical analysis)Optical fiberGigabitTime-division multiplexingEncoding (memory)Free-space optical communicationPhase modulationTime domainOptical performance monitoringIntegrated opticsExploitOptical filterStatistical time division multiplexingPhysicsElectronic circuitNeural Networks and Reservoir ComputingAdvanced Memory and Neural ComputingFerroelectric and Negative Capacitance Devices