Study on the Perturbation Characteristics of Two-Channel Laser Propagation in Atmospheric Turbulence
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摘要
In order to study the influence factors of acquisition detection target information by lidar and understand the influence degree of each factor, the two-channel phase perturbation model and the two-channel eikonal variance model are derived in detail by using the geometrical optics method in this paper, and each factor is discussed in detail. The results show that the transmission distance is the main factor to affect the two-channel perturbation. With the increase of the transmission distance, the disturbing degree will gradually weaken. With the increase of transverse coordinates,the disturbing of two channels will also be weakened. In order to further weaken the disturbing degree, the feature dimension should be far larger than the wavelength, but far less than the transmission distance.
In order to study the influence factors of acquisition detection target information by lidar and understand the influence degree of each factor, the two-channel phase perturbation model and the two-channel eikonal variance model are derived in detail by using the geometrical optics method in this paper, and each factor is discussed in detail. The results show that the transmission distance is the main factor to affect the two-channel perturbation. With the increase of the transmission distance, the disturbing degree will gradually weaken. With the increase of transverse coordinates,the disturbing of two channels will also be weakened. In order to further weaken the disturbing degree, the feature dimension should be far larger than the wavelength, but far less than the transmission distance.
In order to study the influence factors of acquisition detection target information by lidar and understand the influence degree of each factor, the two-channel phase perturbation model and the two-channel eikonal variance model are derived in detail by using the geometrical optics method in this paper, and each factor is discussed in detail. The results show that the transmission distance is the main factor to affect the two-channel perturbation. With the increase of the transmission distance, the disturbing degree will gradually weaken. With the increase of transverse coordinates,the disturbing of two channels will also be weakened. In order to further weaken the disturbing degree, the feature dimension should be far larger than the wavelength, but far less than the transmission distance.
引文
[1]Z.Chen,N.Chen,K.Shi,et al.,EURASIP Journal on Image and Video Processing 1(2018)78.
[2]X.Wang,S.Liang,S.Fan,et al.,International Conference on Optical Instruments and Technology 2017:Optoelectronic Imaging/Spectroscopy and Signal Processing Technology,Beijing(2018).
[3]C.Zhang,H.Zhou,X.Chen,et al.,Infrared Phys.Tech.77(2016)73.
[4]D.D.Ellis,Y.Jie,J.R.Preston,et al.,IEEE Journal of Oceanic Engineering 2(2017)344.
[5]Y.Wang,Y.Hu,W.Lei,et al.,Acta Optica Sinica.37(2017)1128004.
[6]H.Hao,H.Wang,and C.Liang,World Congress on Intelligent Control&Automation 12(2016)312.
[7]T.Nakamura,T.Miyata,S.Sako,et al.,Spie Astronomical Telescopes+Instrumentation(2016).
[8]M.B.T.Venkatesh and R.I.Srinivasa,Microwave Opt.Tech.Lett.7(2016)1618.
[9]Y.Yu,Y.H.Hu,S.L.Xu,et al.,Journal of Optoelectronics·Laser 9(2016)973.
[10]P.Lu,X.S.Yang,and B.Z.Wang,IEEE Transactions on Antennas&Propagation 12(2017)6976.
[11]G.C.Mccormick,Radio Science 1(2016)67.
[12]H.Li and X.Sang,Sensors&Actuators A Physical 258(2017)156.
[13]M.T.A.Khan,E.A.Alkhazraji,A.Ragheb,et al.,IEEEPhotonics Technology Letters 6(2017)543.
[14]S.Swain,Optica Acta:International Journal of Optics10(1990)1.
[15]V.I.Klyatskin and V.I.Tatarskii,Radiophysics&Quantum Electronics 7(1977)720.
[16]M.J.Beran,J.Stat.Phys.3(1990)957.
[17]A.Ishimaru,Wave Propagation and Scattering in Random Media 10(1991)1359.
[18]T.Huang,H.U.Yi-Hua,G.Zhao,et al.,Journal of Infrared&Millimeter Waves 2(2011)179.
[19]R.Wang,J.Bach,and F.P.Ferrie,Applications of Computer Vision(2011).
[2]X.Wang,S.Liang,S.Fan,et al.,International Conference on Optical Instruments and Technology 2017:Optoelectronic Imaging/Spectroscopy and Signal Processing Technology,Beijing(2018).
[3]C.Zhang,H.Zhou,X.Chen,et al.,Infrared Phys.Tech.77(2016)73.
[4]D.D.Ellis,Y.Jie,J.R.Preston,et al.,IEEE Journal of Oceanic Engineering 2(2017)344.
[5]Y.Wang,Y.Hu,W.Lei,et al.,Acta Optica Sinica.37(2017)1128004.
[6]H.Hao,H.Wang,and C.Liang,World Congress on Intelligent Control&Automation 12(2016)312.
[7]T.Nakamura,T.Miyata,S.Sako,et al.,Spie Astronomical Telescopes+Instrumentation(2016).
[8]M.B.T.Venkatesh and R.I.Srinivasa,Microwave Opt.Tech.Lett.7(2016)1618.
[9]Y.Yu,Y.H.Hu,S.L.Xu,et al.,Journal of Optoelectronics·Laser 9(2016)973.
[10]P.Lu,X.S.Yang,and B.Z.Wang,IEEE Transactions on Antennas&Propagation 12(2017)6976.
[11]G.C.Mccormick,Radio Science 1(2016)67.
[12]H.Li and X.Sang,Sensors&Actuators A Physical 258(2017)156.
[13]M.T.A.Khan,E.A.Alkhazraji,A.Ragheb,et al.,IEEEPhotonics Technology Letters 6(2017)543.
[14]S.Swain,Optica Acta:International Journal of Optics10(1990)1.
[15]V.I.Klyatskin and V.I.Tatarskii,Radiophysics&Quantum Electronics 7(1977)720.
[16]M.J.Beran,J.Stat.Phys.3(1990)957.
[17]A.Ishimaru,Wave Propagation and Scattering in Random Media 10(1991)1359.
[18]T.Huang,H.U.Yi-Hua,G.Zhao,et al.,Journal of Infrared&Millimeter Waves 2(2011)179.
[19]R.Wang,J.Bach,and F.P.Ferrie,Applications of Computer Vision(2011).