部分相干cosh-Gaussian光束通过大气湍流后的聚焦特性

赵琦; 郝红宇; 樊红英; 李建欣; 蒋泽伟; 肖星

doi:10.7510/jgjs.issn.1001-3806.2016.05.028

部分相干cosh-Gaussian光束通过大气湍流后的聚焦特性

1.
西南技术物理研究所, 成都 610064;
2.
南京理工大学电子工程与光电技术学院, 南京 210094

作者简介: 赵琦(1985-),男,硕士,工程师,主要从事高能激光在湍流大气中传输的理论和数值模拟计算研究、激光测量及应用研究。E-mail:zhaoqi2156@163.com.

基金项目:
国家自然科学基金资助项目（61205016）
中图分类号: TN241

Focusing characteristics of partially coherent cosh-Gaussian beams propagating through turbulent atmosphere

1.
Southwest Institute of Technical Physics, Chengdu 610041, China;
2.
School of Electronic and Optical Engineering, Nanjing Uniersity of Science and Technology, Nanjing 210094, China
CLC number: TN241

摘要: 为了研究部分相干双曲余弦高斯光束通过大气湍流中传输后的聚焦特性，采用了ABCD矩阵光学的方法进行分析研究，取得了光强分布、束腰半径以及桶中功率的解析式，并用于描述部分相干双曲余弦高斯光束通过大气湍流的聚焦特性。结果表明，在不同湍流强度下，部分相干双曲余弦高斯光束和双曲余弦高斯光束在经过大气湍流后有不同的聚焦特性；使用桶中功率和束腰半径作为评价参量，大气湍流对完全相干双曲余弦高斯的影响更严重；大气湍流对聚焦部分相干双曲余弦高斯光束的影响要大于准直光束。该结果对部分相干光束聚焦特性的研究有一定的理论指导意义，对合成光束傍轴聚焦系统的设计有工程指导意义。
- 大气光学 /
- 大气湍流 /
- 部分相干 /
- 双曲余弦高斯光束
Abstract: For studying characteristics of partially coherent cosh-Gaussian beams propagating through turbulent atmosphere, analysis was carried out based on ABCD matrix and the expressions of the intensity, beam width and power in bucket were obtained to characterize the focusing characteristics of partially coherent cosh-Gaussian beams propagating through turbulent atmosphere. The results show that under different turbulence intensities, the focusing characteristics of partially coherent cosh-Gaussian beams are different from those of totally coherent cosh-Gaussian beams and that the effect of turbulence is more serious to totally coherent cosh-Gaussian beams characterized with the power in bucket and beam width. However, the influence of turbulence on the focused partially coherent cosh-Gaussian is more serious than the collimated beams. The results are useful to study the focusability of partially coherent cosh-Gaussian beams propagating through turbulent atmosphere and helpful to design applicable optical systems for incoherent combination of paraxial beams.
- atmospheric optics /
- atmospheric turbulence /
- partially coherent /
- cosh-Gaussian beam

[1]	ANDREWS L C,PHILLIPS R L.Laser beam propagation through random media[M].Bellingham,USA:SPIE Press,1998:88-101.
[2]	EYYUBOGLU H T,BAYKAL Y.Reciprocity of cos-Gaussian and cosh-Gaussian laser beams in turbulent atmosphere[J].Optics Express,2004,12(1):4659-4674.
[3]	EYYUBOGLU H T,BAYKAL Y.Average intensity and spreading of cosh-Gaussian laser beams in the turbulent atmosphere[J].Applied Optics,2005,44(6):33-56.
[4]	LI P,KUANG A H.Propagation characteristics of non-paraxial partially coherent Hermite-cosine-Gaussian beams[J].Laser Technology,2014,38(1):141-144(in Chinese).
[5]	EYYUBOGLU H T.Hermite-cosine-Gaussian laser beam and its propagation characteristics in turbulent atmosphere[J].Journal of the Optical Society of America,2005,A22(1):1527-1535.
[6]	WU J.Propagation of a Gaussian-Schell beam through turbulent media[J].Journal of Modern Optics,1990,37(4):671-684.
[7]	WU J,BOARDMAN A D.Coherence length of a gaussian-schell beam and atmospheric turbulence[J].Journal of Modern Optics,1991,38(7):1355-1363.
[8]	DUAN K,L B D.Propagation of Hermite-Laguerre-Gaussian beams through paraxial optical ABCD system with rectangular hard-edged aperture[J].Optics Communications,2005,250(3):1-9.
[9]	LI H M,ZUO J W,XU J,et al.Study on incoherent combining technology of pulsed laser beams[J].Laser Technology,2015,39(2):237-241(in Chinese).
[10]	JI X L,HUANG T,LV B D.Spreading of partially coherent cosh-Gaussian beams propagation through turbulent atmosphere[J].Acta Physica Sinica,2006,55(3):978-982(in Chinese).
[11]	CHEN K,ZHU D X,JIAO H W.Polarization properties of Gaussian-Schell model beams passing through focal optical system[J].Laser Technology,2014,38(2):246-250(in Chinese).
[12]	YURA H T,HANSON S G.Optical beam wave propagation through complex optical system[J].Journal of the Optical Society of America,1987,A4(1):1931-1948.
[13]	TATARSKⅡ V I.Wave propagation in a turbulent medium[M].New York,USA:McGraw-Hill Book Company,1961:27-62.
[14]	BANAKH V A,MIRONOV V L.Phase approximation of the Huygens-Kirhhoff method in problems of laser beam propagation in the turbulent atmosphere[J].Optics Letters,1977,1(5):172-174.
[15]	YURA H T,HANSON S G.Optical beam wave propagation through complex optical system[J].Journal of the Optical Society of America,1987,A4(2):1931-1948.
[16]	CHU X X.Propagation of a cosh-Gaussian beam through an optical system in turbulent atmosphere[J].Optics Express,2007,15(3):17613-17618.
[17]	SIEGMAN A E.New developments in laser resonators[J].Proceedings of the SPIE,1990,1224:2-14.
[18]	SIEGMAN A E.How to (maybe) measure laser beam quality[C]//Optical Society of America Annual Meeting,1997.Washington DC,USA:Optical Society of America,1998:184-199.

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部分相干cosh-Gaussian光束通过大气湍流后的聚焦特性

作者简介: 赵琦(1985-),男,硕士,工程师,主要从事高能激光在湍流大气中传输的理论和数值模拟计算研究、激光测量及应用研究。E-mail:zhaoqi2156@163.com.

Focusing characteristics of partially coherent cosh-Gaussian beams propagating through turbulent atmosphere

计量

部分相干cosh-Gaussian光束通过大气湍流后的聚焦特性

作者简介: 赵琦(1985-),男,硕士,工程师,主要从事高能激光在湍流大气中传输的理论和数值模拟计算研究、激光测量及应用研究。E-mail:zhaoqi2156@163.com

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Focusing characteristics of partially coherent cosh-Gaussian beams propagating through turbulent atmosphere

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部分相干cosh-Gaussian光束通过大气湍流后的聚焦特性

作者简介: 赵琦(1985-),男,硕士,工程师,主要从事高能激光在湍流大气中传输的理论和数值模拟计算研究、激光测量及应用研究。E-mail:zhaoqi2156@163.com.

Focusing characteristics of partially coherent cosh-Gaussian beams propagating through turbulent atmosphere

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部分相干cosh-Gaussian光束通过大气湍流后的聚焦特性

作者简介: 赵琦(1985-),男,硕士,工程师,主要从事高能激光在湍流大气中传输的理论和数值模拟计算研究、激光测量及应用研究。E-mail:zhaoqi2156@163.com

English Abstract

Focusing characteristics of partially coherent cosh-Gaussian beams propagating through turbulent atmosphere

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目录