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Physical secure optical communication based on private chaotic spectral phase encryption/decryption

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Physical secure optical communication based on private chaotic spectral phase encryption/decryption. / Jiang, Ning; Zhao, Anke; Xue, Chenpeng et al.
In: Optics Letters, Vol. 44, No. 7, 01.04.2019, p. 1536-1539.

Research output: Contribution to journalArticlepeer-review

HarvardHarvard

Jiang, N, Zhao, A, Xue, C, Tang, J & Qiu, K 2019, 'Physical secure optical communication based on private chaotic spectral phase encryption/decryption', Optics Letters, vol. 44, no. 7, pp. 1536-1539. https://doi.org/10.1364/OL.44.001536

APA

Jiang, N., Zhao, A., Xue, C., Tang, J., & Qiu, K. (2019). Physical secure optical communication based on private chaotic spectral phase encryption/decryption. Optics Letters, 44(7), 1536-1539. https://doi.org/10.1364/OL.44.001536

CBE

Jiang N, Zhao A, Xue C, Tang J, Qiu K. 2019. Physical secure optical communication based on private chaotic spectral phase encryption/decryption. Optics Letters. 44(7):1536-1539. https://doi.org/10.1364/OL.44.001536

MLA

Jiang, Ning et al. "Physical secure optical communication based on private chaotic spectral phase encryption/decryption". Optics Letters. 2019, 44(7). 1536-1539. https://doi.org/10.1364/OL.44.001536

VancouverVancouver

Jiang N, Zhao A, Xue C, Tang J, Qiu K. Physical secure optical communication based on private chaotic spectral phase encryption/decryption. Optics Letters. 2019 Apr 1;44(7):1536-1539. Epub 2019 Mar 19. doi: 10.1364/OL.44.001536

Author

Jiang, Ning ; Zhao, Anke ; Xue, Chenpeng et al. / Physical secure optical communication based on private chaotic spectral phase encryption/decryption. In: Optics Letters. 2019 ; Vol. 44, No. 7. pp. 1536-1539.

RIS

TY - JOUR

T1 - Physical secure optical communication based on private chaotic spectral phase encryption/decryption

AU - Jiang, Ning

AU - Zhao, Anke

AU - Xue, Chenpeng

AU - Tang, Jianming

AU - Qiu, Kun

PY - 2019/4/1

Y1 - 2019/4/1

N2 - We propose and demonstrate a novel physical, secure high-speed optical communication scheme based on synchronous chaotic spectral phase encryption (CSPE) and decryption (CSPD). The CSPE is performed by a module composed of two dispersion components and one phase modulator (PM) between them, and the CSPD is carried out by a twin module with reverse dispersions and inverse PM driving signals. The PM driving signals of the CSPE and CSPD modules are privately synchronized chaotic signals that are independently generated by local external-cavity semiconductor lasers subject to common injection. The numerical results indicate that with the CSPE, the original message can be encrypted as a noise-like signal, and the timing clock of the original message is efficiently hidden in the encrypted signal. Based on the private synchronization of the chaotic PM driving signals, only the legal receiver can decrypt the message correctly, while the eavesdropper is not able to intercept a useful message. Moreover, the proposed scheme can also support secure symmetric bidirectional high-speed WDM transmissions. This work shows a prospective way to implement high-speed secure optical communications at the physical layer.

AB - We propose and demonstrate a novel physical, secure high-speed optical communication scheme based on synchronous chaotic spectral phase encryption (CSPE) and decryption (CSPD). The CSPE is performed by a module composed of two dispersion components and one phase modulator (PM) between them, and the CSPD is carried out by a twin module with reverse dispersions and inverse PM driving signals. The PM driving signals of the CSPE and CSPD modules are privately synchronized chaotic signals that are independently generated by local external-cavity semiconductor lasers subject to common injection. The numerical results indicate that with the CSPE, the original message can be encrypted as a noise-like signal, and the timing clock of the original message is efficiently hidden in the encrypted signal. Based on the private synchronization of the chaotic PM driving signals, only the legal receiver can decrypt the message correctly, while the eavesdropper is not able to intercept a useful message. Moreover, the proposed scheme can also support secure symmetric bidirectional high-speed WDM transmissions. This work shows a prospective way to implement high-speed secure optical communications at the physical layer.

U2 - 10.1364/OL.44.001536

DO - 10.1364/OL.44.001536

M3 - Article

VL - 44

SP - 1536

EP - 1539

JO - Optics Letters

JF - Optics Letters

SN - 0146-9592

IS - 7

ER -