各向异性大气湍流中涡旋Lommel光束传输特性

doi:10.3969/j.issn.1001-2400.2018.05.001

Abstract

Abstract:

In order to reduce effectively the turbulence effects of optical wave propagation in the atmosphere and explore methods to mitigate turbulence effects, based on the vortex optical wave and Markov approximation theory for optical wave propagation in atmospheric turbulence and utilizing the method of decomposing the vortex beam into the superposition of the spiral harmonics in cylindrical coordinates, the models of the receiving power and crosstalk power are derived, for a non-diffracting vortex Lommel beam transmitted in non-Kolmogorov turbulence by considering inner and outer scales. The influences of the beam and turbulence parameters on the receiving power and crosstalk power are analyzed for Lommel beams propagating in anisotropic turbulence with different intensities and different degrees. The results show that with the increase of the anisotropic degree of turbulence, the receiving power of each angular momentum mode increases and the crosstalk power decreases, and they are greatly influenced by the power exponent for the non-Kolmogorov spectrum. Moreover, when the shape of the Lommel beam is closer to the circular symmetry mode, the effect of turbulence can be mitigated more. Theoretical analysis shows that the propagation property of the Lommel beam in anisotropic atmospheric turbulence is better than that of the multiple Hankel-Bessel and Laguerre-Gaussian vortex beam.

Key words: vortex beam, non-diffracting Lommel beam, anisotropy, atmospheric turbulence, propagation

YANG Ruike, ZHOU Jing. Properties of vortex Lommel beam propagation in anisotropic atmospheric turbulence[J].Journal of Xidian University, 2018, 45(5): 1-6+31.

References ［16］

［1］	CHENG M J, GUO L X, LI J T, et al. Channel Capacity of the OAM-based Free-space Optical Communication Links with Bessel-Gauss Beams in Turbulent Ocean［J］. IEEE Photonics Journal, 2016, 8(1): 7390163.
［2］	LIU Y D, GAO C, GAO M, et al. Superposition and Detection of Two Helical Beams for Optical Orbital Angular Momentum Communication［J］. Optics Communications, 2008, 281(14): 3636-3639.
［3］	朱云. 轨道角动量通信系统中的湍流效应分析［D］. 无锡: 江南大学, 2016.
［4］	刘丹, 裴昌幸, 权东晓, 等. 一种可提高安全通信距离的诱骗态量子密钥分发方案［J］. 西安电子科技大学学报, 2010, 37(1): 13-17.
	LIU Dan, PEI Changxing, QUAN Dongxiao, et al. New Decoy State Quantum Key Distribution for Increasing the Security Communication Distance［J］. Journal of Xidian University, 2010, 37(1): 13-17.
［5］	姬瑶, 岳鹏, 闫瑞青, 等. 弱湍流下斜程大气激光通信误码率分析［J］. 西安电子科技大学学报, 2016, 43(1): 66-70.
	JI Yao, YUE Peng, YAN Ruiqing, et al. BER Performance Analysis of the Atmospheric Laser Communication System on the Slant Path in Weak Turbulennce［J］. Journal of Xidian University, 2016, 43(1): 66-70.
［6］	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 Atomic Molecular ＆ Optical Physics, 1992, 45(11): 8185-8189.
［7］	ANGUITA J A, NEIFELD M A, VASIC B V. Turbulence-induced Channel Crosstalk in an Orbital Angular Momentum-multiplexed Free-space Optical Link［J］. Applied Optics, 2008, 47(13): 2414-2429.
［8］	XU J, GAO J, ZHU Y, et al. Effects of Atmospheric Turbulence on the Mode Weight of the Laguerre-Gaussian Schell Beams［J］. Optik, 2014, 125(1): 280-284.
［9］	WU G H, TONG C M, CHENG M J, et al. Superimposed Orbital Angular Momentum Mode of Multiple Hankel-Bessel Beam Propagation in Anisotropic Non-Kolmogorov Turbulence［J］. Chinese Optics Letters, 2016, 14(8): 080102.
［10］	BELAFHAL A, EZ-ZARIY L, HRICHA Z. A Study of Nondiffracting Lommel Beams Propagating in a Medium Containing Spherical Scatterers［J］. Journal of Quantitative Spectroscopy and Radiative Transfer, 2016, 184: 1-7.
［11］	ZHI D, TAO R, ZHOU P, et al. Propagation of Ring Airy Gaussian Beams with Optical Vortices through Anisotropic Non-Kolmogorov Turbulence［J］. Optics Communications, 2017, 387: 157-165.
［12］	YU L, HU B, ZHANG Y. Intensity of Vortex Modes Carried by Lommel Beam in Weak-to-strong Non-Kolmogorov Turbulence［J］. Optics Express, 2017, 25(16): 19538-19547.
［13］	KOVALEV A A, KOTLYAR V V. Lommel Modes［J］. Optics Communications, 2015, 338: 117-122.
［14］	ZHANG Y X, CHENG M J, ZHU Y, et al. Influence of Atmospheric Turbulence on the Transmission of Orbital Angular Momentum for Whittaker-Gaussian Laser Beams［J］. Optics Express, 2014, 22(18): 22101-22110.
［15］	ZHANG T, LIU Y D, WANG J, et al. Self-recovery Effect of Orbital Angular Momentum Mode of Circular Beam in Weak Non-Kolmogorov Turbulence［J］. Optics Express, 2016, 24(18): 20507-20514.
［16］	ANGUITA J A, NEIFELD M A, VASIC B V. Turbulence-induced Channel Crosstalk in an Orbital Angular Momentum-multiplexed Free-space Optical Link［J］. Applied Optics, 2008, 47(13): 2414-2429.

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Properties of vortex Lommel beam propagation in anisotropic atmospheric turbulence

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