{"title":"Propagation of Laguerre-Gaussian beams through underwater optical turbulence","authors":"Nathaniel Ferlic, A. Laux, Linda J. Mullen","doi":"10.1117/12.3013120","DOIUrl":null,"url":null,"abstract":"In the ocean, underwater currents are driven by various natural effects attributed to heat transfer through water. The movement of heat subsequently affects light propagation due to changes in the water’s refractive index leading to optical phase distortions. Applications implementing laser beams containing structured phase profiles are prone to being distorted by this underwater optical turbulence. Typical distortions of these beams can include beam wander, intensity and phase variations, and beam spreading that can limit their effectiveness for applications including free-space optical communication, imaging, or sensing. Experimental and theoretical studies have shown optical vortices, a form of structured light, propagate differently through optical turbulence compared with Gaussian beams. Changes in propagation are observed by varying the amount of Orbital Angular Momentum (OAM) a vortex beam carries that increases the beam size as OAM increases. This experimental study intends to fairly compare Laguerre-Gaussian (LG) beams to Gaussian beams after propagation through underwater turbulence by normalizing the initial beam size using the RMS radius. The metrics chosen are the mean scintillation, on-axis intensity, and intensity correlation. Results show the scintillation and on-axis intensity, when chosen at locations along the LG beam annuli, are similar for different LG beams. When the initial beam waist is normalized, the speckle field correlation width and peak correlation energy decreases as RMS radius increases. These results show that structured light is not independent of the effects of beam size and divergence, similar to Gaussian beams, to determine propagation effectiveness or robustness.","PeriodicalId":178341,"journal":{"name":"Defense + Commercial Sensing","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-06-06","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Defense + Commercial Sensing","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1117/12.3013120","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
In the ocean, underwater currents are driven by various natural effects attributed to heat transfer through water. The movement of heat subsequently affects light propagation due to changes in the water’s refractive index leading to optical phase distortions. Applications implementing laser beams containing structured phase profiles are prone to being distorted by this underwater optical turbulence. Typical distortions of these beams can include beam wander, intensity and phase variations, and beam spreading that can limit their effectiveness for applications including free-space optical communication, imaging, or sensing. Experimental and theoretical studies have shown optical vortices, a form of structured light, propagate differently through optical turbulence compared with Gaussian beams. Changes in propagation are observed by varying the amount of Orbital Angular Momentum (OAM) a vortex beam carries that increases the beam size as OAM increases. This experimental study intends to fairly compare Laguerre-Gaussian (LG) beams to Gaussian beams after propagation through underwater turbulence by normalizing the initial beam size using the RMS radius. The metrics chosen are the mean scintillation, on-axis intensity, and intensity correlation. Results show the scintillation and on-axis intensity, when chosen at locations along the LG beam annuli, are similar for different LG beams. When the initial beam waist is normalized, the speckle field correlation width and peak correlation energy decreases as RMS radius increases. These results show that structured light is not independent of the effects of beam size and divergence, similar to Gaussian beams, to determine propagation effectiveness or robustness.
在海洋中,水下洋流是由各种自然效应驱动的,这些自然效应归因于水中的热传递。由于水的折射率发生变化,热量的流动随后会影响光的传播,从而导致光学相位失真。应用包含结构相位轮廓的激光束时,很容易受到这种水下光学湍流的影响而发生扭曲。这些光束的典型畸变包括光束漂移、强度和相位变化以及光束扩散,从而限制了它们在自由空间光通信、成像或传感等应用中的有效性。实验和理论研究表明,与高斯光束相比,结构光的一种形式--光漩涡在光湍流中的传播方式有所不同。通过改变旋涡光束所携带的轨道角动量(OAM),可以观察到光束传播的变化。本实验研究旨在通过使用均方根半径对初始光束大小进行归一化,对通过水下湍流传播后的拉盖尔-高斯(LG)光束和高斯光束进行公平比较。选择的指标是平均闪烁、轴向强度和强度相关性。结果表明,不同 LG 光束沿 LG 光束环的位置选择时,闪烁和轴上强度相似。当初始束腰归一化时,斑点场相关宽度和峰值相关能量随着有效值半径的增加而减小。这些结果表明,结构光与高斯光束类似,在决定传播效果或稳健性时,并不独立于光束大小和发散的影响。