Using Deep Learning to Model Elevation Differences between Radar and Laser Altimetry

peer reviewed Satellite and airborne observations of surface elevation are critical in understanding climatic and glaciological processes and quantifying their impact on changes in ice masses and sea level contribution. With the growing number of dedicated airborne campaigns and experimental and ope...

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Bibliographic Details
Published in:Remote Sensing
Main Authors: Horton, Alex, Ewart, Martin, Gourmelen, Noel, Fettweis, Xavier, Storkey, Amos
Other Authors: SPHERES - ULiège
Format: Article in Journal/Newspaper
Language:English
Published: MDPI 2022
Subjects:
altimetry
artificial intelligence (AI)
CryoSat
cryosphere
Greenland
IceBridge
ICESat-2
interferometry
SARIn
swath
Artificial intelligence
Green land
Interferometric radars
Earth and Planetary Sciences (all)
General Earth and Planetary Sciences
Physical
chemical
mathematical & earth Sciences
Earth sciences & physical geography
Physique
chimie
mathématiques & sciences de la terre
Sciences de la terre & géographie physique
Online Access:https://orbi.uliege.be/handle/2268/302676
https://orbi.uliege.be/bitstream/2268/302676/1/remotesensing-14-06210.pdf
https://doi.org/10.3390/rs14246210
Description
Summary:peer reviewed Satellite and airborne observations of surface elevation are critical in understanding climatic and glaciological processes and quantifying their impact on changes in ice masses and sea level contribution. With the growing number of dedicated airborne campaigns and experimental and operational satellite missions, the science community has access to unprecedented and ever-increasing data. Combining elevation datasets allows potentially greater spatial-temporal coverage and improved accuracy; however, combining data from different sensor types and acquisition modes is difficult by differences in intrinsic sensor properties and processing methods. This study focuses on the combination of elevation measurements derived from ICESat-2 and Operation IceBridge LIDAR instruments and from CryoSat-2’s novel interferometric radar altimeter over Greenland. We develop a deep neural network based on sub-waveform information from CryoSat-2, elevation differences between radar and LIDAR, and additional inputs representing local geophysical information. A time series of maps are created showing observed LIDAR-radar differences and neural network model predictions. Mean LIDAR vs. interferometric radar adjustments and the broad spatial and temporal trends thereof are recreated by the neural network. The neural network also predicts radar-LIDAR differences with respect to waveform parameters better than a simple linear model; however, point level adjustments and the magnitudes of the spatial and temporal trends are underestimated.

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