Global estimation of range resolved thermodynamic profiles from micropulse differential absorption lidar | Earth Observing Laboratory

Global estimation of range resolved thermodynamic profiles from micropulse differential absorption lidar

Hayman, M., Stillwell, R. A., Karboski, A., Marais, W. J., Spuler, S. M.. (2024). Global estimation of range resolved thermodynamic profiles from micropulse differential absorption lidar. Optics Express, doi:https://doi.org/10.1364/OE.521178

Title	Global estimation of range resolved thermodynamic profiles from micropulse differential absorption lidar
Genre	Article
Author(s)	Matthew Hayman, Robert A. Stillwell, Adam Karboski, W. J. Marais, Scott M. Spuler
Abstract	We demonstrate thermodynamic profile estimation with data obtained using the MicroPulse DIAL such that the retrieval is entirely self contained. The only external input is surface meteorological variables obtained from a weather station installed on the instrument. The estimator provides products of temperature, absolute humidity and backscatter ratio such that cross dependencies between the lidar data products and raw observations are accounted for and the final products are self consistent. The method described here is applied to a combined oxygen DIAL, potassium HSRL, water vapor DIAL system operating at two pairs of wavelengths (nominally centered at 770 and 828 nm). We perform regularized maximum likelihood estimation through the Poisson Total Variation technique to suppress noise and improve the range of the observations. A comparison to 119 radiosondes indicates that this new processing method produces improved temperature retrievals, reducing total errors to less than 2 K below 3 km altitude and extending the maximum altitude of temperature retrievals to 5 km with less than 3 K error. The results of this work definitively demonstrates the potential for measuring temperature through the oxygen DIAL technique and furthermore that this can be accomplished with low -power semiconductor -based lidar sensors.
Publication Title	Optics Express
Publication Date	Apr 8, 2024
Publisher's Version of Record	https://doi.org/10.1364/OE.521178
OpenSky Citable URL	https://n2t.org/ark:/85065/d7nv9pf5
OpenSky Listing	View on OpenSky
EOL Affiliations	RSF

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