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High-Speed Neuromorphic Reservoir Computing Based on a Semiconductor Nanolaser With Optical Feedback Under Electrical Modulation

Xing Guo, Shui Ying Xiang, Ya Hui Zhang, Lin Lin, Ai Jun Wen, Yue Hao

2020IEEE Journal of Selected Topics in Quantum Electronics33 citationsDOI

Abstract

A high-speed neuromorphic reservoir computing system based on a semiconductor nanolaser with optical feedback (SNL-based RC) under electrical modulation is proposed for the first time and demonstrated numerically. A Santa-Fe chaotic time series prediction task is employed to quantify the prediction performance of the SNL-based RC system. The effects of the Purcell cavity-enhanced spontaneous emission factor F and the spontaneous emission coupling factor β on the proposed RC system are analyzed extensively. It is found that, in general, increased F and β extend the range of good prediction performance of the SNL-based RC system. Moreover, the influences of bias current and feedback phase are also considered. Due to the ultra-short photon lifetime in SNL, the information processing rate of the SNL-based RC system reaches 10Gpbs. The proposed high-speed SNL-based RC system in this paper provides theoretical guidelines for the design of RC-based integrated neuromorphic photonic systems.

Topics & Concepts

Neuromorphic engineeringNanolaserPhotonicsComputer scienceModulation (music)Coupling (piping)Electronic engineeringOptoelectronicsPhysicsMaterials scienceEngineeringArtificial neural networkLasing thresholdArtificial intelligenceWavelengthMetallurgyAcousticsNeural Networks and Reservoir ComputingOptical Network TechnologiesAdvanced Memory and Neural Computing
High-Speed Neuromorphic Reservoir Computing Based on a Semiconductor Nanolaser With Optical Feedback Under Electrical Modulation | Litcius