Tbps parallel random number generation based on a single quarter-wavelength-shifted DFB laser

Qiang Cai; Pu Li; Yuechun Shi; Zhiwei Jia; Li Ma; Bingjie Xu; Xiangfei Chen; K. Alan Shore; Yuncai Wang

doi:10.1016/j.optlastec.2023.109273

Tbps parallel random number generation based on a single quarter-wavelength-shifted DFB laser

Qiang Cai
, Pu Li
, Yuechun Shi
, Zhiwei Jia
, Li Ma
, Bingjie Xu
, Xiangfei Chen
, K. Alan Shore
, Yuncai Wang

School of Computer Science & Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

We propose and experimentally demonstrate a parallel physical random number generator (Ph-RNG) based on a single quarter-wavelength-shifted distributed feedback laser (QWS-DFB LD). Though simply connecting the two output ports of the QWS-DFB LD to form a cross-coupled perturbation, we simultaneously produce two paths of complex optical chaotic signals with a bandwidth above 10 GHz. Furthermore, a dual-channel Ph-RNG with a bit rate of order terabit per second (Tbps) is implemented by combining a multi-bit extraction method. Final results show that our generated physical random numbers can successfully pass standard benchmark tests for randomness.

Original language	English
Pages (from-to)	109273
Number of pages	1
Journal	Optics and Laser Technology
Volume	162
Early online date	17 Feb 2023
DOIs	https://doi.org/10.1016/j.optlastec.2023.109273
Publication status	Published - Jul 2023

Keywords

Laser chaos
Semiconductor laser
Physical random number generator
Secure communication

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10.1016/j.optlastec.2023.109273

https://www.sciencedirect.com/science/article/pii/S0030399223001664

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title = "Tbps parallel random number generation based on a single quarter-wavelength-shifted DFB laser",

abstract = "We propose and experimentally demonstrate a parallel physical random number generator (Ph-RNG) based on a single quarter-wavelength-shifted distributed feedback laser (QWS-DFB LD). Though simply connecting the two output ports of the QWS-DFB LD to form a cross-coupled perturbation, we simultaneously produce two paths of complex optical chaotic signals with a bandwidth above 10 GHz. Furthermore, a dual-channel Ph-RNG with a bit rate of order terabit per second (Tbps) is implemented by combining a multi-bit extraction method. Final results show that our generated physical random numbers can successfully pass standard benchmark tests for randomness.",

keywords = "Laser chaos, Semiconductor laser, Physical random number generator, Secure communication",

author = "Qiang Cai and Pu Li and Yuechun Shi and Zhiwei Jia and Li Ma and Bingjie Xu and Xiangfei Chen and Shore, \{K. Alan\} and Yuncai Wang",

year = "2023",

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doi = "10.1016/j.optlastec.2023.109273",

language = "English",

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pages = "109273",

journal = "Optics and Laser Technology",

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T1 - Tbps parallel random number generation based on a single quarter-wavelength-shifted DFB laser

AU - Cai, Qiang

AU - Li, Pu

AU - Shi, Yuechun

AU - Jia, Zhiwei

AU - Ma, Li

AU - Xu, Bingjie

AU - Chen, Xiangfei

AU - Shore, K. Alan

AU - Wang, Yuncai

PY - 2023/7

Y1 - 2023/7

N2 - We propose and experimentally demonstrate a parallel physical random number generator (Ph-RNG) based on a single quarter-wavelength-shifted distributed feedback laser (QWS-DFB LD). Though simply connecting the two output ports of the QWS-DFB LD to form a cross-coupled perturbation, we simultaneously produce two paths of complex optical chaotic signals with a bandwidth above 10 GHz. Furthermore, a dual-channel Ph-RNG with a bit rate of order terabit per second (Tbps) is implemented by combining a multi-bit extraction method. Final results show that our generated physical random numbers can successfully pass standard benchmark tests for randomness.

AB - We propose and experimentally demonstrate a parallel physical random number generator (Ph-RNG) based on a single quarter-wavelength-shifted distributed feedback laser (QWS-DFB LD). Though simply connecting the two output ports of the QWS-DFB LD to form a cross-coupled perturbation, we simultaneously produce two paths of complex optical chaotic signals with a bandwidth above 10 GHz. Furthermore, a dual-channel Ph-RNG with a bit rate of order terabit per second (Tbps) is implemented by combining a multi-bit extraction method. Final results show that our generated physical random numbers can successfully pass standard benchmark tests for randomness.

KW - Laser chaos

KW - Semiconductor laser

KW - Physical random number generator

KW - Secure communication

U2 - 10.1016/j.optlastec.2023.109273

DO - 10.1016/j.optlastec.2023.109273

M3 - Article

SN - 0030-3992

VL - 162

SP - 109273

JO - Optics and Laser Technology

JF - Optics and Laser Technology

ER -

Tbps parallel random number generation based on a single quarter-wavelength-shifted DFB laser

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