Abstract
Clouds and aerosols play a significant role in determining the overall atmospheric radiation budget, yet remain a key uncertainty in understanding and predicting the future climate system. In addition to their impact on the Earth’s climate system, aerosols from volcanic eruptions, wildfires, man-made pollution events and dust storms are hazardous to aviation safety and human health. Space-based lidar systems provide critical information about the vertical distributions of clouds and aerosols that greatly improve our understanding of the climate system. However, daytime data from backscatter lidars, such as the Cloud-Aerosol Transport System (CATS) on the International Space Station (ISS), must be averaged during science processing at the expense of spatial resolution to obtain sufficient signal-to-noise ratio (SNR) for accurately detecting atmospheric features. For example, 50% of all atmospheric features reported in daytime operational CATS data products require averaging to 60 km for detection. Furthermore, the single-wavelength nature of the CATS primary operation mode makes accurately typing these features challenging in complex scenes. This paper presents machine learning (ML) techniques that, when applied to CATS data, (1) increased the 1064 nm SNR by 75%, (2) increased the number of layers detected (any resolution) by 30%, and (3) enabled detection of 40% more atmospheric features during daytime operations at a horizontal resolution of 5 km compared to the 60 km horizontal resolution often required for daytime CATS operational data products. A Convolutional Neural Network (CNN) trained using CATS standard data products also demonstrated the potential for improved cloud-aerosol discrimination compared to the operational CATS algorithms for cloud edges and complex near-surface scenes during daytime.
Highlights
Atmospheric features such as clouds and aerosols play an important role in Earth’s climate system, air quality and hydrological cycle, with a magnitude that is heavily dependent on the atmospheric feature’s height, thickness and type
The Cloud-Aerosol Transport System (CATS) lidar augmented the Cloud-Aerosol Lidar with Orthogonal Polarization (CALIOP) lidar data record by providing similar data from the International Space Station (ISS) for 33 months with diurnal information. While these systems have limitations, such as degraded daytime signals by noise from solar background light and limited information content for feature typing, machine learning (ML) techniques like the Convolutional Neural Network (CNN) demonstrated in this paper can overcome some issues such as coarse daytime detection resolutions and Planetary Boundary Layer (PBL) cloud-aerosol discrimination but not without limitations for detecting subvisible features during nighttime
The wavelet denoising and CNN techniques presented in this paper increased the CATS 1064 nm signal-to-noise ratio (SNR) by 75%, increased the number of layers detected by 30%, and enabled detection of 40% more atmospheric features during daytime operations at a horizontal resolution of 5 km compared to the 60 km used for daytime CATS operational data products
Summary
Atmospheric features such as clouds and aerosols play an important role in Earth’s climate system, air quality and hydrological cycle, with a magnitude that is heavily dependent on the atmospheric feature’s height, thickness and type. Aerosol particles include windblown dust from deserts, smoke from wildfires, sulfurous particles from volcanic eruptions, and particles produced by fossil fuel combustion Depending upon their size, composition, and location within the atmosphere, aerosols either cool or warm the surface [6,7].
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