Chen Ming, Gao Taichang, Liu Lei, et al. Influence of non-Kolmogorov turbulence phase screen based on equivalent structure constant on beam quality in transmission[J]. High Power Laser and Particle Beams, 2017, 29: 091008. doi: 10.11884/HPLPB201729.170052
Citation: Chen Ming, Gao Taichang, Liu Lei, et al. Influence of non-Kolmogorov turbulence phase screen based on equivalent structure constant on beam quality in transmission[J]. High Power Laser and Particle Beams, 2017, 29: 091008. doi: 10.11884/HPLPB201729.170052

Influence of non-Kolmogorov turbulence phase screen based on equivalent structure constant on beam quality in transmission

doi: 10.11884/HPLPB201729.170052
  • Received Date: 2017-02-20
  • Rev Recd Date: 2017-04-20
  • Publish Date: 2017-09-15
  • The paper uses Gaussian distribution to describe the non-uniformity of the power spectrums power law along the propagation path. It presents the simulation of the non-Kolmogorov turbulence phase screens based on equivalent structure constant by power spectrum inversion method, and the simulation of the transmissions of laser beam through isotropous and non-Kolmogorov turbulence. By analyzing the light intensity uniformity, drift and scintillation indices of the beam propagating through single phase screen and multiple screens respectively, the influences can be found. When beam propagates through single phase screen, the maximum and uniformity of light intensity increase first and then decrease with power law. And beam drift is affected randomly in single screen and regularly in average data. When beam propagates through multiple phase screens, the scintillation indices of beams are affected by the number of phase screens. When the number is large, the scintillation indices through the isotropous turbulence is much larger than that in non-Kolmogorov turbulence, and the relative errors of beam drift in two models is close to 0. It is necessary to verify the influence by experiments and divide the scope of Kolmogorov turbulence and non-Kolmogorov turbulence.
  • Relative Articles

    [1]Ge Xiaolu, Wang Benyi, Guo Liping, Man Zhongsheng. Behavior of phase singularities for laser beam propagating through uplink and downlink atmospheric turbulence paths[J]. High Power Laser and Particle Beams, 2018, 30(12): 121001. doi: 10.11884/HPLPB201830.180228
    [2]Chen Xiaowen, Li Xiaoqing, Li Binzhong, Tang Mingyue. Turbulence distance of partially coherent flat-topped beams in non-Kolmogorov turbulence[J]. High Power Laser and Particle Beams, 2015, 27(01): 011004. doi: 10.11884/HPLPB201527.011004
    [3]Zhou Guoquan, Chu Xiuxiang. Far-field divergent properties of linearly polarized Gaussian beam diffracted at circular aperture[J]. High Power Laser and Particle Beams, 2012, 24(09): 2047-2052. doi: 10.3788/HPLPB20122409.2047
    [4]zhao yang, li dehua, zhou wei, ma jianjun, yao xiangjun, tian youliang. Diffractive properties of terahertz zone plates with Gaussian beam incidence[J]. High Power Laser and Particle Beams, 2011, 23(08): 0- .
    [5]ma zairu. Analytical solution of carrier-envelope phase drift of linearly chirped pulsed Gaussian beam[J]. High Power Laser and Particle Beams, 2011, 23(04): 0- .
    [6]wang jiabin, liu yongxin, pu jixiong. Measuring scintillation index of laser beams propagating in turbulent atmosphere[J]. High Power Laser and Particle Beams, 2011, 23(04): 0- .
    [7]li jinsong, gao xiumin, zhang shuqin. Gradient force pattern of Gaussian beam adjusted by an annular phase plate[J]. High Power Laser and Particle Beams, 2009, 21(02): 0- .
    [8]dong hongcheng, tao chunxian, zhao yuanan, huang jianbing, shao jianda. Combination characteristics analysis of Gaussian beams[J]. High Power Laser and Particle Beams, 2009, 21(02): 0- .
    [9]shen xue-ju, shen hong-bin, zhou sheng-guo, wang long. Propagation properties of Gaussian beam passing through a misaligned optical system with misaligned narrow slot aperture[J]. High Power Laser and Particle Beams, 2008, 20(09): 0- .
    [10]meng xiang-long, zhao bao-yin, nie yi-you, lu bai-da. Parameter changes of Gaussian beams after passing through astigmatic lens[J]. High Power Laser and Particle Beams, 2007, 19(01): 0- .
    [11]gao chong, ma jing, tan li-ying. Angle-of-arrival fluctuation of light beam propagation in strong turbulence regime[J]. High Power Laser and Particle Beams, 2006, 18(06): 0- .
    [12]mei hai-ping, wu xiao-qing, rao rui-zhong. Measurement and analysis of temperature power spectrum scaling exponent in non-Kolmogorov turbulent atmosphere[J]. High Power Laser and Particle Beams, 2006, 18(09): 0- .
    [13]zhou tie-zhong, deng luo-gen. Gaussian beam Z-scan diffraction theory model for the strong nonlinear absorption materials[J]. High Power Laser and Particle Beams, 2004, 16(06): 0- .
    [14]he kun-na, deng luo-gen. Far-field diffraction patterns formation of gaussian beam transmitted through thin nonlinear medium[J]. High Power Laser and Particle Beams, 2003, 15(10): 0- .
    [15]zhou nan-run, tao xiang-yang, lü bai-da. Focusing properties of Gaussian beams through a compound optical system[J]. High Power Laser and Particle Beams, 2002, 14(04): 0- .
    [16]ji xiao-ling, lü bai-da. Focusing properties of Gaussian beams passing through a bifocal lens[J]. High Power Laser and Particle Beams, 2001, 13(06): 0- .
    [17]wang xi-qing, liang guo-dong, lü bai-da. Approximate close-form expression for Gaussian beams passing through an ABCD optical system with hard-edge aperture[J]. High Power Laser and Particle Beams, 2001, 13(04): 0- .
  • Cited by

    Periodical cited type(4)

    1. 李思瑶,丁洲林,侯春雨,王玮君,马佳欣,于永吉. 完美涡旋光束在大气湍流传输中的螺旋相位谱分析. 光学学报. 2024(06): 42-49 .
    2. 汪航,汪玉琴,张蓉竹. 完美涡旋光束在大气湍流中的斜程传输特性. 强激光与粒子束. 2023(10): 44-50 . 本站查看
    3. 卜洋,杨志,赵丽娟,徐志钮. 大气湍流对基于轨道角动量的自由空间光通信影响及解决方案综述. 半导体光电. 2022(06): 1099-1108 .
    4. 蔡敏,荣嵘. 基于数学模型的低衍射光束结构参数优化方法. 激光杂志. 2020(11): 15-19 .

    Other cited types(10)

  • Created with Highcharts 5.0.7Amount of accessChart context menuAbstract Views, HTML Views, PDF Downloads StatisticsAbstract ViewsHTML ViewsPDF Downloads2024-052024-062024-072024-082024-092024-102024-112024-122025-012025-022025-032025-04010203040
    Created with Highcharts 5.0.7Chart context menuAccess Class DistributionFULLTEXT: 21.2 %FULLTEXT: 21.2 %META: 74.6 %META: 74.6 %PDF: 4.2 %PDF: 4.2 %FULLTEXTMETAPDF
    Created with Highcharts 5.0.7Chart context menuAccess Area Distribution其他: 3.5 %其他: 3.5 %China: 0.1 %China: 0.1 %India: 0.1 %India: 0.1 %Osaka: 0.1 %Osaka: 0.1 %United States: 0.2 %United States: 0.2 %上海: 1.5 %上海: 1.5 %东莞: 0.7 %东莞: 0.7 %中山: 0.1 %中山: 0.1 %临汾: 0.1 %临汾: 0.1 %丹东: 0.1 %丹东: 0.1 %保定: 0.2 %保定: 0.2 %六安: 0.1 %六安: 0.1 %北京: 20.1 %北京: 20.1 %十堰: 0.2 %十堰: 0.2 %南京: 0.1 %南京: 0.1 %南宁: 0.2 %南宁: 0.2 %南昌: 0.2 %南昌: 0.2 %厦门: 0.1 %厦门: 0.1 %台北: 0.1 %台北: 0.1 %台州: 0.1 %台州: 0.1 %合肥: 0.2 %合肥: 0.2 %吉林: 0.2 %吉林: 0.2 %哈尔滨: 0.5 %哈尔滨: 0.5 %哥伦布: 0.1 %哥伦布: 0.1 %唐山: 0.1 %唐山: 0.1 %嘉兴: 0.1 %嘉兴: 0.1 %大庆: 0.3 %大庆: 0.3 %大连: 0.1 %大连: 0.1 %天津: 1.2 %天津: 1.2 %太原: 0.4 %太原: 0.4 %安康: 0.1 %安康: 0.1 %宜春: 0.1 %宜春: 0.1 %宣城: 0.4 %宣城: 0.4 %平顶山: 0.1 %平顶山: 0.1 %广州: 0.7 %广州: 0.7 %张家口: 0.5 %张家口: 0.5 %成都: 0.8 %成都: 0.8 %扬州: 0.8 %扬州: 0.8 %新乡: 0.1 %新乡: 0.1 %无锡: 0.1 %无锡: 0.1 %昆明: 0.1 %昆明: 0.1 %晋城: 0.1 %晋城: 0.1 %普洱: 0.1 %普洱: 0.1 %朝阳: 0.1 %朝阳: 0.1 %杭州: 1.0 %杭州: 1.0 %松原: 0.2 %松原: 0.2 %桂林: 0.1 %桂林: 0.1 %桃园: 0.1 %桃园: 0.1 %梅州: 0.1 %梅州: 0.1 %武汉: 0.7 %武汉: 0.7 %沈阳: 0.1 %沈阳: 0.1 %济南: 0.1 %济南: 0.1 %深圳: 0.1 %深圳: 0.1 %温州: 0.2 %温州: 0.2 %湖州: 0.3 %湖州: 0.3 %漯河: 1.5 %漯河: 1.5 %石家庄: 0.8 %石家庄: 0.8 %福州: 0.1 %福州: 0.1 %秦皇岛: 0.9 %秦皇岛: 0.9 %绵阳: 0.2 %绵阳: 0.2 %芒廷维尤: 13.3 %芒廷维尤: 13.3 %芝加哥: 0.2 %芝加哥: 0.2 %衡水: 0.1 %衡水: 0.1 %衡阳: 0.1 %衡阳: 0.1 %衢州: 0.6 %衢州: 0.6 %西宁: 37.8 %西宁: 37.8 %西安: 1.5 %西安: 1.5 %贵阳: 0.1 %贵阳: 0.1 %运城: 0.3 %运城: 0.3 %邯郸: 0.2 %邯郸: 0.2 %郑州: 0.6 %郑州: 0.6 %重庆: 0.1 %重庆: 0.1 %金华: 0.2 %金华: 0.2 %铁岭: 0.1 %铁岭: 0.1 %长春: 1.2 %长春: 1.2 %长沙: 1.2 %长沙: 1.2 %长治: 0.1 %长治: 0.1 %青岛: 0.4 %青岛: 0.4 %香港: 0.1 %香港: 0.1 %其他ChinaIndiaOsakaUnited States上海东莞中山临汾丹东保定六安北京十堰南京南宁南昌厦门台北台州合肥吉林哈尔滨哥伦布唐山嘉兴大庆大连天津太原安康宜春宣城平顶山广州张家口成都扬州新乡无锡昆明晋城普洱朝阳杭州松原桂林桃园梅州武汉沈阳济南深圳温州湖州漯河石家庄福州秦皇岛绵阳芒廷维尤芝加哥衡水衡阳衢州西宁西安贵阳运城邯郸郑州重庆金华铁岭长春长沙长治青岛香港

Catalog

    通讯作者: 陈斌, bchen63@163.com
    • 1. 

      沈阳化工大学材料科学与工程学院 沈阳 110142

    1. 本站搜索
    2. 百度学术搜索
    3. 万方数据库搜索
    4. CNKI搜索
    Article views (1358) PDF downloads(252) Cited by(14)
    Proportional views
    Related

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return