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从纯转动和振动转动拉曼激光雷达信号中反演得到的气溶胶光学系数及其相关误差的对比分析。

A Comparative Analysis of Aerosol Optical Coefficients and Their Associated Errors Retrieved from Pure-Rotational and Vibro-Rotational Raman Lidar Signals.

作者信息

Zenteno-Hernández José Alex, Comerón Adolfo, Rodríguez-Gómez Alejandro, Muñoz-Porcar Constantino, D'Amico Giuseppe, Sicard Michaël

机构信息

CommSensLab, Deptment of Signal Theory and Communications, Universitat Politècnica de Catalunya (UPC), 08034 Barcelona, Spain.

Instituto Nacional de Astrofísica, Óptica y Electrónica (INAOE), 72840 Puebla, Mexico.

出版信息

Sensors (Basel). 2021 Feb 11;21(4):1277. doi: 10.3390/s21041277.

DOI:10.3390/s21041277
PMID:33670104
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7916889/
Abstract

This paper aims to quantify the improvement obtained with a purely rotational Raman (PRR) channel over a vibro-rotational Raman (VRR) channel, used in an aerosol lidar with elastic and Raman channels, in terms of signal-to-noise ratio (SNR), effective vertical resolution, and absolute and relative uncertainties associated to the retrieved aerosol optical (extinction and backscatter) coefficients. Measurements were made with the European Aerosol Research Lidar Network/Universitat Politècnica de Catalunya (EARLINET/UPC) multi-wavelength lidar system enabling a PRR channel at 353.9 nm, together with an already existing VRR (386.7 nm) and an elastic (354.7 nm) channels. Inversions were performed with the EARLINET Single Calculus Chain (SCC). When using PRR instead of VRR, the measurements show a gain in SNR of a factor 2.8 and about 7.6 for 3-h nighttime and daytime measurements, respectively. For 3-h nighttime (daytime) measurements the effective vertical resolution is reduced by 17% (20%), the absolute uncertainty (associated to the extinction) is divided by 2 (10) and the relative uncertainty is divided by 3 (7). During daytime, VRR extinction coefficient is retrieved in a limited height range (<2.2 km) preventing the SCC from finding a suitable calibration range in the search height range. So the advantage of using PRR instead of VRR is particularly evidenced in daytime conditions. For nighttime measurements, decreasing the time resolution from 3 to 1 h has nearly no effect on the relative performances of PRR vs. VRR.

摘要

本文旨在量化在配备弹性通道和拉曼通道的气溶胶激光雷达中,纯转动拉曼(PRR)通道相对于振动转动拉曼(VRR)通道在信噪比(SNR)、有效垂直分辨率以及与反演得到的气溶胶光学(消光和后向散射)系数相关的绝对和相对不确定性方面所取得的改进。测量是使用欧洲气溶胶研究激光雷达网络/加泰罗尼亚理工大学(EARLINET/UPC)多波长激光雷达系统进行的,该系统在353.9 nm处启用了一个PRR通道,以及一个已有的VRR(386.7 nm)通道和一个弹性(354.7 nm)通道。反演是使用EARLINET单计算链(SCC)进行的。当使用PRR而非VRR时,测量结果表明,对于3小时的夜间和白天测量,SNR分别提高了2.8倍和约7.6倍。对于3小时的夜间(白天)测量,有效垂直分辨率降低了17%(20%),绝对不确定性(与消光相关)除以2(10),相对不确定性除以3(7)。在白天,VRR消光系数仅在有限的高度范围内(<2.2 km)被反演出来,这使得SCC无法在搜索高度范围内找到合适的校准范围。因此,在白天条件下,使用PRR而非VRR的优势尤为明显。对于夜间测量,将时间分辨率从3小时降低到1小时对PRR与VRR的相对性能几乎没有影响。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4c2c/7916889/0e681caf524d/sensors-21-01277-g010.jpg
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本文引用的文献

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An Architecture Providing Depolarization Ratio Capability for a Multi-Wavelength Raman Lidar: Implementation and First Measurements.一种为多波长拉曼激光雷达提供退偏振比能力的架构:实现与首次测量
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Current Research in Lidar Technology Used for the Remote Sensing of Atmospheric Aerosols.用于大气气溶胶遥感的激光雷达技术的当前研究
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Lidar-measured atmospheric N₂ vibrational-rotational Raman spectra and consequent temperature retrieval.激光雷达测量的大气N₂振动-转动拉曼光谱及由此进行的温度反演。
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Atmospheric temperature profiling in the presence of clouds with a pure rotational Raman lidar by use of an interference-filter-based polychromator.利用基于干涉滤光片的多色仪,通过纯转动拉曼激光雷达在有云情况下进行大气温度剖面测量。
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