Novel Detection of Atmospheric Turbulence Profile Using Mie-Scattering Lidar Based on Non-Kolmogorov Turbulence Theory

Mao, Jiandong; Zhang, Yingnan; Li, Juan; Gong, Xin; Zhao, Hu; Rao, Zhimin

doi:10.3390/e25030477

Cited by 3 publications

(5 citation statements)

References 40 publications

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“…Figure 13 demonstrates averaged daytime profiles of optical turbulence at the BAO site. The profile shown by the orange line is obtained from the well-known Hufnagel-Valley model, which is determined by the average surface value of C 2 n and by pseudovelocity calculated for the atmospheric layer from 5 km to 20 km [36,37]. To estimate the surface values of C 2 n , we used data from mast measurements of turbulent characteristics (sonic anemometers).…”

Section: Modified Model For Estimation Of C 2 N Parameter At the Site...mentioning

confidence: 99%

Simulating Atmospheric Characteristics and Daytime Astronomical Seeing Using Weather Research and Forecasting Model

Shikhovtsev,

Kovadlo,

Lezhenin

et al. 2023

Applied Sciences

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The present study is aimed at the development of a novel empirical base for application to ground-based astronomical telescopes. A Weather Research and Forecasting (WRF) model is used for description of atmospheric flow structure with a high spatial resolution within the Baikal Astrophysical Observatory (BAO) region. Mesoscale vortex structures are found within the atmospheric boundary layer, which affect the quality of astronomical images. The results of simulations show that upward air motions in the lower atmosphere are suppressed both above the cold surface of Lake Baikal and inside mesoscale eddy structures. A model of the outer scale of turbulence for BAO is developed. In this work, we consider the seeing parameter that represents the full width at half-maximum of the point spread function. Optical turbulence profiles are obtained and daytime variations of seeing are estimated. Vertical profiles of optical turbulence are optimized taking into account data from direct optical observations of solar images.

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Section: Modified Model For Estimation Of C 2 N Parameter At the Site...mentioning

confidence: 99%

Simulating Atmospheric Characteristics and Daytime Astronomical Seeing Using Weather Research and Forecasting Model

Shikhovtsev,

Kovadlo,

Lezhenin

et al. 2023

Applied Sciences

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“…15,23,27,28 And LiDAR can detect atmospheric transmittance, turbulence, and wind data along any designated path on the target path. 3,10,15,22,27 For laser atmospheric transmission, it is possible to accurately obtain the attenuation characteristics and intensity distribution characteristics of the specified direction laser, as well as the information of wind which affects atmospheric transmittance and thermal blooming. 27,29 Due to the transition zone and blind zone of LiDAR, the detection of turbulence in the near field is limited, and real-time detection of turbulence in any direction also faces enormous challenges.…”

Section: Introductionmentioning

confidence: 99%

“…With the development and progress of computer technology, laser technology, sensors, and other related technologies, there has been significant progress in the methods of obtaining atmospheric transmittance, turbulence, and wind 3 , 10 , 12 – 16 Atmospheric transmittance can be obtained by simulation with atmospheric transport modeling software, but for a real-time changing atmospheric system, there is always a discrepancy between model calculations and actual conditions, so accurate real-time measurements are needed to obtain atmospheric transmittance 14 , 17 – 19 The commonly used direct measurement method is usually to find a star with constant radiation (such as the Sun) and observe this radiation source by optical means (spectrometer, filter, grating, etc.)…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

“…LiDAR detection belongs to remote sensing detection and has the advantages of high spatial and temporal resolution, real-time detection, etc., and is widely used 15 , 23 , 27 , 28 . And LiDAR can detect atmospheric transmittance, turbulence, and wind data along any designated path on the target path 3 , 10 , 15 , 22 , 27 . For laser atmospheric transmission, it is possible to accurately obtain the attenuation characteristics and intensity distribution characteristics of the specified direction laser, as well as the information of wind which affects atmospheric transmittance and thermal blooming 27 , 29 .…”

Section: Introductionmentioning

confidence: 99%

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LiDAR technology and experimental research for comprehensive measurement of atmospheric transmittance, turbulence, and wind

Yang,

Qiu,

Fang

et al. 2023

J. Appl. Rem. Sens.

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Atmospheric transmittance, turbulence, and wind play a crucial role in the field of laser atmospheric transmission. In response to the demand for comprehensive detection of atmospheric optical parameters, a LiDAR system for comprehensive measurement of atmospheric transmittance, turbulence, and wind (ACW-LiDAR) has been developed through integrated optical and mechanical design. The remote sensing measurement of atmospheric transmittance, turbulence, and wind simultaneously and along a common path has been realized by the ACW-LiDAR. By proposing a limb scanning algorithm, the problem of preference for atmospheric transmittance estimation has been overcome, and the problem of inconvenient turbulence measurement at near-surface has been effectively solved. It is also possible to obtain wind information on the laser transmission route. The experimental results based on the ACW-LiDAR system indicate that the detection distance of atmospheric transmittance is greater than 10 km @ 1064 nm. The detection distance of turbulence is greater than 10 km @ 532 nm. The detection distance of wind is greater than 4 km @ 1550 nm. The comparison between the ACW-LiDAR system and the ground meteorological automatic observation system shows that the variation trend in extinction coefficient, turbulence, and radial wind velocity is consistent, with a correlation better than 0.69, verifying the accuracy of the developed ACW-LiDAR system. The analysis of comprehensive scanning detection indicates that the three key atmospheric parameters mentioned above are interrelated and mutually influencing. So the measurement of the same time and common path of atmospheric transmittance, turbulence, and wind is of great significance. These can provide a theoretical and experimental basis for long-term observation and accumulation of atmospheric parameters, as well as the correction of atmospheric parameters.

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A portable S-DIMM developed for preliminary measurement of seeing for Solar Site Survey: Theory and one case study

Duan,

Liu,

Song

et al. 2024

New Astronomy

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Novel Detection of Atmospheric Turbulence Profile Using Mie-Scattering Lidar Based on Non-Kolmogorov Turbulence Theory

Cited by 3 publications

References 40 publications

Simulating Atmospheric Characteristics and Daytime Astronomical Seeing Using Weather Research and Forecasting Model

Simulating Atmospheric Characteristics and Daytime Astronomical Seeing Using Weather Research and Forecasting Model

LiDAR technology and experimental research for comprehensive measurement of atmospheric transmittance, turbulence, and wind

A portable S-DIMM developed for preliminary measurement of seeing for Solar Site Survey: Theory and one case study

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