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Backscatter near-end solution in processing of scanning lidar data.

Vladimir Kovalev, Cyle Wold, Alexander Petkov

    Applied Optics
    |September 15, 2015
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    Summary

    This study introduces a new lidar data processing technique to improve atmospheric profiling. It extends reliable measurements to higher altitudes by combining a near-end solution with a constant lidar ratio assumption.

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    Area of Science:

    • Atmospheric Science
    • Remote Sensing
    • Lidar Technology

    Background:

    • Classic multiangle lidar data processing has limited reliable atmospheric profiling height.
    • Existing methods struggle to invert optical profiles from distant or near-zenith signals.

    Purpose of the Study:

    • To develop a data processing technique for extending reliable atmospheric profiling heights with scanning lidar.
    • To address limitations in inverting signals measured at distant ranges and near zenith.

    Main Methods:

    • Utilized an auxiliary backscatter near-end solution.
    • Assumed a constant lidar ratio over high altitudes.
    • Combined these approaches for enhanced data processing.

    Main Results:

    • The developed technique increases the maximum profiling heights achievable with scanning lidar.
    • Demonstrated effectiveness using both simulated and experimental data.
    • Successfully inverted optical profiles from previously challenging signal ranges.

    Conclusions:

    • The combined lidar data processing technique offers a significant improvement for atmospheric profiling.
    • This method enhances the utility of scanning lidar for studying the upper atmosphere.
    • Provides a more comprehensive understanding of atmospheric optical properties.