Progress in adaptive optics wavefront correction technology of vortex beam (<i>Invited</i>)

Haichao Zhan; Le Wang; Qin Peng; Wennai Wang; Shengmei Zhao

doi:10.3788/IRLA20210428

Infrared and Laser Engineering, Volume. 50, Issue 9, 20210428(2021)

Progress in adaptive optics wavefront correction technology of vortex beam (Invited)

Haichao Zhan¹, Le Wang¹, Qin Peng¹, Wennai Wang², and Shengmei Zhao^1,2

¹Institute of Signal Processing and Transmission, Nanjing University of Posts and Telecommunications, Nanjing 210003, China

²Key Lab of Broadband Wireless Communication and Sensor Network Technology, Ministry of Education, Nanjing University of Posts and Telecommunications, Nanjing 210003, China

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References(48)

[1] Willner A E, Huang H, Yan Y, et al. Optical communications using orbital angular momentum beams[J]. Advances in Optics and Photonics, 7, 66-106(2015).

[2] Zhu F, Huang S, Shao W, et al. Free-space optical communication link using perfect vortex beams carrying orbital angular momentum[J]. Optics Communications, 396, 50-57(2017).

[3] Yao A M, Padgett M J. Orbital angular momentum: Origins, behavior and applications[J]. Advances in Optics and Photonics, 3, 161-204(2011).

[4] Padgett M J, Bowman R. Tweezers with a twist[J]. Nature Photonics, 5, 343-348(2011).

[5] Franke-Arnold S, Allen L, Padgett M J. Advances in optical angular momentum[J]. Laser and Photonics Reviews, 2, 299-313(2008).

[6] Lu Xuanhui, Chen He, Zhao Chengliang. Research on vortex beams and optical vortices[J]. Infrared and Laser Engineering, S1, 174(2007).

[7] Allen L, Beijersbergen M W, Spreeuw R J C, et al. Orbital angular momentum of light and the transformation of Laguerre-Gaussian laser modes[J]. Physical Review A, 45, 8185(1992).

[8] Wang J, Yang J Y, Fazal I M, et al. Terabit free-space data transmission employing orbital angular momentum multiplexing[J]. Nature Photonics, 6, 488-496(2012).

[9] Nenad B, Yue Y, Ren Y X, et al. Terabit-scale orbital angular momentum mode division multiplexing in fibers[J]. Science, 340, 1545-1548(2013).

[10] Paterson C. Atmospheric turbulence and orbital angular momentum of single photons for optical communication[J]. Physical Review Letters, 94, 153901(1-4)(2005).

[11] Ren Y, Huang H, Xie G, et al. Atmospheric turbulence effects on the performance of a free space optical link employing orbital angular momentum multiplexing[J]. Optics Letters, 38, 4062-4065(2013).

[12] Zhu X L, Guo L, Zhu Q, et al. The propagation properties of a longitudinal orbital angular momentum multiplexing system in atmospheric turbulence[J]. IEEE Photonics Journal, 10, 112-114, 135(2018).

[13] Yu Ce, Wang Tianshu, Zhang Ying, et al. Research on transmission performance on OAM beam and Gaussian beam in atmospheric turbulence channel[J]. Infrared and Laser Engineering, 50, 20200400(2021).

[14] Zhang Y, Wang P, Liu T, et al. Performance analysis of a LDPC coded OAM-based UCA FSO system exploring linear equalization with channel estimation over atmospheric turbulence[J]. Optics Express, 26, 22182-22196(2018).

[15] Li S H, Chen S, Gao C Q, et al. Atmospheric turbulence compensation in orbital angular momentum communications: advances and perspectives[J]. Optics Communications, 408, 68-81(2018).

[16] Zhao S M, Wang L, Zou L, et al. Both channel coding and wavefront correction on the turbulence mitigation of optical communications using orbital angular momentum multiplexing[J]. Optics Communications, 376, 92-98(2016).

[17] Zou Li, Wang Le, Zhang Shibing, et al. Compensation of orbital-angular-momentum multiplexed communication system with wavefront correction[J]. Journal on Communications, 36, 76-84(2015).

[18] Zou L, Wang L, Zhao S M. Turbulence mitigation scheme based on spatial diversity in orbital-angular-momentum multiplexed system[J]. Optics Communications, 400, 123-127(2017).

[19] Gao Chunqing, Zhang Shikun, Fu Shiyao, et al. Adaptive optics wavefront correction techniques of vortex beams[J]. Infrared and Laser Engineering, 46, 0201001(2017).

[20] Aftab M, Choi H J, Liang R G, et al. Adaptive Shack-Hartmann wavefront sensor accommodating large wavefront variations[J]. Optics Express, 26, 34428-34441(2018).

[21] Zhao S M, Leach J, Gong L Y, et al. Aberration corrections for free-space optical communications in atmosphere turbulence using Orbital Angular Momentum states[J]. Optics Express, 20, 452-461(2012).

[22] Hu L J, Hu S W, Gong W, et al. Learning-based Shack-Hartmann wavefront sensor for high-order aberration detection[J]. Optics Express, 27, 33504-33517(2019).

[23] Li M, Li Y, Han J, et al. Gerchberg–Saxton algorithm based phase correction in optical wireless communication[J]. Physical Communication, 25, 323-327(2017).

[24] Fu S, Zhang S, Wang T, et al. Pre-turbulence compensation of orbital angular momentum beams based on a probe and the Gerchberg-Saxton algorithm[J]. Optics Letters, 41, 3185-3188(2016).

[25] Xie G, Ren Y, Huang H, et al. Phase correction for a distorted orbital angular momentum beam using a Zernike polynomials-based stochastic-parallel-gradient-descent algorithm[J]. Optics Letters, 40, 1197-1200(2015).

[26] Xie Z L, Ma H T, He X J, et al. Adaptive piston correction of sparse aperture systems with stochastic parallel gradient descent algorithm[J]. Optics Express, 26, 9541-9551(2018).

[27] Yang Ping, Xu Bing, Jiang Wenhan, et al. Study of a genetic algorithm used in an adaptive optical system[J]. Acta Optica Sinica, 27, 1628-1632(2007).

[28] Yu Zhan, Ma Haotong, Du Shaojun. Adaptive near-field beam shaping based on simulated annealing algorithm[J]. Acta Optica Sinica, 31, 163-167(2011).

[29] Li J, Zhang M, Wang D S, et al. Joint atmospheric turbulence detection and adaptive demodulation technique using the CNN for the OAM-FSO communication[J]. Optics Express, 26, 10494-10508(2018).

[30] Tian Q H, Li Z, Hu K, et al. Turbo-coded 16-ary OAM shift keying FSO communication system combining the CNN-based adaptive demodulator[J]. Optics Express, 26, 27849-27864(2018).

[31] Lane R G, Tallon M. Wave-front reconstruction using a Shack-Hartmann[J]. Applied Optics, 31, 6902-6906(1992).

[32] [32] Zhao S M, Leach J, Zheng B Y. Crection effect of SharkHartmann algithm on turbulence aberrations f free space optical communications using bital angular momentum[C]International Conference on Communication Technology Proceedings, ICCT, 2010: 580583.

[33] Ren Y, Xie G, Huang H, et al. Adaptive optics compensation of multiple orbital angular momentum beams propagating through emulated atmospheric turbulence[J]. Optics Letters, 39, 2845-2848(2014).

[34] Vorontsov M A, Sivokon V P. Stochastic-parallel-gradient-descent technique for high-resolution wave-front phase-distortion correction[J]. Journal of the Optical Society of America A, 15, 2745-2758(1998).

[35] [35] Wang Xiayao. Research on adaptive optics crection technology of vtex beam[D]. Xi''an: Xi''an University of Technology, 2018. (in Chinese)

[36] [36] Yin X L, Lin J L, Chang H, et al. A new version of Stochasticparallelgradientdescent algithm (SPGD) f phase crection of a distted bital angular momentum (OAM) beam[C]Proceedings of the SPIE, 2018: 106973B.

[37] LeCun Y, Bengio Y, Hinton G. Deep learning[J]. Nature, 521, 436-444(2015).

[38] Doster T, Watnik A T. Machine learning approach to OAM beam demultiplexing via convolutional neural networks[J]. Applied Optics, 56, 3386-3396(2017).

[39] Tian Q H, Lu C D, Liu B, et al. DNN-based aberration correction in a wavefront sensorless adaptive optics system[J]. Optics Express, 27, 10765-10776(2019).

[40] Ma H M, Liu H Q, Qiao Y, et al. Numerical study of adaptive optics compensation based on Convolutional Neural Networks[J]. Optics Communications, 433, 283-289(2019).

[41] Liu J M, Wang P P, Zhang X K, et al. Deep learning based atmospheric turbulence compensation for orbital angular momentum beam distortion and communication[J]. Optics Express, 27, 16671-16688(2019).

[42] Zhai Y W, Fu S Y, Zhang J Q, et al. Turbulence aberration correction for vector vortex beams using deep neural networks on experimental data[J]. Optics Express, 28, 7515-7527(2020).

[43] Zhao Y, Wang A, Zhu L, et al. Performance evaluation of underwater optical communications using spatial modes subjected to bubbles and obstructions[J]. Optics Letters, 42, 4699-4702(2017).

[44] Cochenour B, Morgan K, Miller K, et al. Propagation of modulated optical beams carrying orbital angular momentum in turbid water[J]. Applied Optics, 55, C34-C38(2016).

[45] Baghdady J, Miller K, Morgan K, et al. Multi-gigabit/s underwater optical communication link using orbital angular momentum multiplexing[J]. Optics Express, 24, 9794-9805(2016).

[46] Yang Tianxing, Zhao Shengmei. Random phase screen model of ocean turbulence[J]. Acta Optica Sinica, 37, 1201001(2017).

[47] Pan S X, Wang L, Wang W N, et al. An effective way for simulating oceanic turbulence channel on the beam carrying orbital angular momentum[J]. Scientific Reports, 9, 14009(2019).

[48] Zhan H C, Wang L, Wang W N, et al. Experimental analysis of adaptive optics correction methods on the beam carrying orbital angular momentum mode through oceanic turbulence[J]. Optik, 240, 166990(2021).

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Haichao Zhan, Le Wang, Qin Peng, Wennai Wang, Shengmei Zhao. Progress in adaptive optics wavefront correction technology of vortex beam (Invited)[J]. Infrared and Laser Engineering, 2021, 50(9): 20210428

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Paper Information

Category: Special issue-Manipulation on optical vortex and its sensing application

Received: Jun. 28, 2021

Accepted: --

Published Online: Oct. 28, 2021

The Author Email:

DOI:10.3788/IRLA20210428

Topics

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