TanDEM-X elevation data for mass balance estimation

Ongoing global warming leads to dramatic changes in the cryosphere. In view of these rapid changes as well as the large uncertainties regarding forecasts, there is a constantly growing need for reliable and consistent information on the current state and the evolution of the ice sheets, ice caps and...

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Bibliographic Details
Main Authors: Abdullahi, Sahra, Burgess, David, Wessel, Birgit, Roth, Achim
Format: Conference Object
Language:unknown
Published: 2023
Subjects:
Dynamik der Landoberfläche
glacier*
Ice cap
Nunavut
Online Access:https://elib.dlr.de/193888/
id ftdlr:oai:elib.dlr.de:193888
record_format openpolar
spelling ftdlr:oai:elib.dlr.de:193888 2024-05-19T07:40:51+00:00 TanDEM-X elevation data for mass balance estimation Abdullahi, Sahra Burgess, David Wessel, Birgit Roth, Achim 2023-02 https://elib.dlr.de/193888/ unknown Abdullahi, Sahra und Burgess, David und Wessel, Birgit und Roth, Achim (2023) TanDEM-X elevation data for mass balance estimation. EARSeL SIG Land Ice & Snow Workshop 2023, 2023-02-06 - 2023-02-08, Bern, Schweiz. Dynamik der Landoberfläche Konferenzbeitrag NonPeerReviewed 2023 ftdlr 2024-04-25T01:05:25Z Ongoing global warming leads to dramatic changes in the cryosphere. In view of these rapid changes as well as the large uncertainties regarding forecasts, there is a constantly growing need for reliable and consistent information on the current state and the evolution of the ice sheets, ice caps and glaciers worldwide. In this context, satellite-based remote sensing allows cost-effective data collection even for inaccessible areas. Radar altimetry, gravimetry and laser altimetry have been widely used to detect height and mass changes. However, these systems either offer only point-based measurements or acquire at low spatial resolution. Since 2010, the single-pass SAR (Synthetic Aperture Radar) interferometry mission TanDEM-X provides area-wide information with high spatial resolution of 0.4 arcsec (i.e. about 12 m) at a global scale. The huge amount of globally consistent elevation data could contribute to meet the urgent need for information with high spatial resolution to monitor the dynamics of the cryosphere. However, the data suffers from an elevation bias up to several meters due to signal penetration. The penetration bias mainly depends on snow and ice characteristics as well as on the continuously changing acquisition geometry and underlies inter- and intra-annual variations. In this regard, we quantify the impact of X-band InSAR penetration bias on mass balance estimation based on TanDEM-X digital elevation models (DEM). In detail, a multiple regression model based on interferometric coherence and backscatter intensity is used to correct a time series of TanDEM-X DEMs acquired between 2010 and 2018 over the Devon Ice Cap (Nunavut, Canada), from which changes in elevation and mass are derived. For validation, GPS and laser altimeter measurements are used, which show good agreement between predictions and observations, with mean deviations between 0.01 and 0.20 m. The predictions well reflect the inter- and intra-annual variations, with a mean penetration bias varying between 2.44 and 3.40 m. Regarding ... Conference Object glacier* Ice cap Nunavut German Aerospace Center: elib - DLR electronic library
institution Open Polar
collection German Aerospace Center: elib - DLR electronic library
op_collection_id ftdlr
language unknown
topic Dynamik der Landoberfläche
spellingShingle Dynamik der Landoberfläche
Abdullahi, Sahra
Burgess, David
Wessel, Birgit
Roth, Achim
TanDEM-X elevation data for mass balance estimation
topic_facet Dynamik der Landoberfläche
description Ongoing global warming leads to dramatic changes in the cryosphere. In view of these rapid changes as well as the large uncertainties regarding forecasts, there is a constantly growing need for reliable and consistent information on the current state and the evolution of the ice sheets, ice caps and glaciers worldwide. In this context, satellite-based remote sensing allows cost-effective data collection even for inaccessible areas. Radar altimetry, gravimetry and laser altimetry have been widely used to detect height and mass changes. However, these systems either offer only point-based measurements or acquire at low spatial resolution. Since 2010, the single-pass SAR (Synthetic Aperture Radar) interferometry mission TanDEM-X provides area-wide information with high spatial resolution of 0.4 arcsec (i.e. about 12 m) at a global scale. The huge amount of globally consistent elevation data could contribute to meet the urgent need for information with high spatial resolution to monitor the dynamics of the cryosphere. However, the data suffers from an elevation bias up to several meters due to signal penetration. The penetration bias mainly depends on snow and ice characteristics as well as on the continuously changing acquisition geometry and underlies inter- and intra-annual variations. In this regard, we quantify the impact of X-band InSAR penetration bias on mass balance estimation based on TanDEM-X digital elevation models (DEM). In detail, a multiple regression model based on interferometric coherence and backscatter intensity is used to correct a time series of TanDEM-X DEMs acquired between 2010 and 2018 over the Devon Ice Cap (Nunavut, Canada), from which changes in elevation and mass are derived. For validation, GPS and laser altimeter measurements are used, which show good agreement between predictions and observations, with mean deviations between 0.01 and 0.20 m. The predictions well reflect the inter- and intra-annual variations, with a mean penetration bias varying between 2.44 and 3.40 m. Regarding ...
format Conference Object
author Abdullahi, Sahra
Burgess, David
Wessel, Birgit
Roth, Achim
author_facet Abdullahi, Sahra
Burgess, David
Wessel, Birgit
Roth, Achim
author_sort Abdullahi, Sahra
title TanDEM-X elevation data for mass balance estimation
title_short TanDEM-X elevation data for mass balance estimation
title_full TanDEM-X elevation data for mass balance estimation
title_fullStr TanDEM-X elevation data for mass balance estimation
title_full_unstemmed TanDEM-X elevation data for mass balance estimation
title_sort tandem-x elevation data for mass balance estimation
publishDate 2023
url https://elib.dlr.de/193888/
genre glacier*
Ice cap
Nunavut
genre_facet glacier*
Ice cap
Nunavut
op_relation Abdullahi, Sahra und Burgess, David und Wessel, Birgit und Roth, Achim (2023) TanDEM-X elevation data for mass balance estimation. EARSeL SIG Land Ice & Snow Workshop 2023, 2023-02-06 - 2023-02-08, Bern, Schweiz.
_version_ 1799480420071374848

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