[1] [1] Toru Y, Isao O, Hiopang Y, et al. Common-chaotic-signal induced synchronization in semiconductor lasers[J].Optics Express, 2007, 15(7): 3974-3980.

[2] [2] Argyris A, Pikasis E, Syvridis D. Gb/ s one-time-pad data encryption with synchronized chaos-based true random bit generators[J]. Journal of Lightwave Technology, 2016, 34(22): 5325-5331.

[3] [3] Yoshimura K, Muramatsu J, Davis P, et al. Secure key distribution using correlated randomness in lasers driven by common random light[J]. Physical Review Letters, 2012,108(7): 070602.

[4] [4] Xue C, Jiang N, Qiu K, et al. Key distribution based on synchronization in bandwidth-enhanced random bit generators with dynamic post - processing [ J]. Optics express,2015, 23(11): 14510-14519.

[5] [5] Jiang N, Zhao X, Zhao A, et al. High-rate secure key distribution based on private chaos synchronization and alternating step algorithms[J]. International Journal of Bifurcation and Chaos, 2020, 30(02): 2050027.

[6] [6] Zhao Z, Cheng M, Luo C, et al. Semiconductor-laserbased hybrid chaos source and its application in secure key distribution[J]. Optics Letters, 2019, 44(10): 2605-2608.

[7] [7] Cheng M, Luo C, Jiang X, et al. An electrooptic chaotic system based on a hybrid feedback loop [J]. Journal of Lightwave Technology, 2018, 36(19): 4259-4266.

[8] [8] Gao H, Wang A, Wang L, et al. 0. 75 Gbit/ s high-speed classical key distribution with mode-shift keying chaos synchronization of Fabry-Perot lasers[J]. Light: Science & Applications, 2021, 10(1): 172.

[10] [10] Sasaki T, Kakesu I, Mitsui Y, et al. Common-signal-induced synchronization in photonic integrated circuits and its application to secure key distribution[J]. Optics Express,2017, 25(21): 26029-26044.

[11] [11] Kanter I, Butkovski M, Peleg Y, et al. Synchronization of random bit generators based on coupled chaotic lasers and application to cryptography[J]. Optics Express, 2010, 18(17): 18292-18302.

[12] [12] Keuninckx L, Soriano M C, Fischer I, et al. Encryption key distribution via chaos synchronization[J]. Scientific reports,2017, 7(1): 1-14.

[13] [13] Aida H, Arahata M, Okumura H, et al. Experiment on synchronization of semiconductor lasers by common injection of constant-amplitude random-phase light[J]. Optics Express,2012, 20(11):11813-11829.

[14] [14] Koizumi H, Morikatsu S, Aida H, et al. Information-theoretic secure key distribution based on common random-signal induced synchronization in unidirectionally - coupled cascades of semiconductor lasers [ J]. Optics Express,2013, 21(15): 17869-17893.

[15] [15] Wang L, Chao M, Wang A, et al. High-speed physical key distribution based on dispersion - shift - keying chaos synchronization in commonly driven semiconductor lasers without external feedback[J]. Optics Express, 2020, 28(25): 37919-37935.

[16] [16] Kravtsov K, Wang Z, Trappe W, et al. Physical layer secret key generation for fiber-optical networks[J]. Optics Express, 2013, 21(20): 23756-23771.

[17] [17] Hajomer A A E, Yang X, Sultan A, et al. Key distribution based on phase fluctuation between polarization modes in optical channel[J]. IEEE Photonics Technology Letters,2018, 30(8): 704-707.

[18] [18] Zhang L, Hajomer A A E, HU W, et al. 2. 7 Gb/ s secure key generation and distribution using bidirectional polarization scrambler in fiber [ J]. IEEE Photonics Technology Letters, 2021, 33(6): 289-292.

[19] [19] Hajomer A A E, Zhang L, Yang X, et al. 284. 8-Mb/ s physical-layer cryptographic key generation and distribution in fiber networks [J]. Journal of Lightwave Technology,2021, 39(6): 1595-1601.