Assessing the TanDEM-X elevation bias due to SAR signal penetration for glacier mass balance measurements

The elevation bias due to signal penetration in bistatic InSAR DEMs is recognized as a main error source together with co-registration for estimating glacier mass balance with the DEM differencing method. For TanDEM-X DEMs, the elevation processed from X-band (9.65 GHz) SAR data can lie up to 4-8m l...

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Bibliographic Details
Main Authors: Krieger, Lukas, Ibarrola Subiza, Nerea, Floricioiu, Dana, Fischer, Georg, Abdullahi, Sahra
Format: Conference Object
Language:English
Published: 2025
Subjects:
SAR-Signalverarbeitung
Dynamik der Landoberfläche
Radarkonzepte
Union Glacier
Antarc*
Antarctica
Online Access:https://elib.dlr.de/214183/
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author Krieger, Lukas
Ibarrola Subiza, Nerea
Floricioiu, Dana
Fischer, Georg
Abdullahi, Sahra
author_facet Krieger, Lukas
Ibarrola Subiza, Nerea
Floricioiu, Dana
Fischer, Georg
Abdullahi, Sahra
author_sort Krieger, Lukas
collection Unknown
description The elevation bias due to signal penetration in bistatic InSAR DEMs is recognized as a main error source together with co-registration for estimating glacier mass balance with the DEM differencing method. For TanDEM-X DEMs, the elevation processed from X-band (9.65 GHz) SAR data can lie up to 4-8m lower than the actual snow/ice surface in alpine accumulation areas [1]. However, this bias can often be mitigated by differencing TanDEM-X acquisitions from the same season with unchanged SAR geometry, reducing penetration differences between DEMs. The relative importance of SAR signal penetration for accurate mass balance measurements also reduces with the length of the observation period. Notably, methods have been developed to correct for SAR signal penetration bias, including estimating volumetric coherence and inverting it [2,3]. However, correction methods have rarely been tested and validated across entire TanDEM-X scenes with coincident ground truth measurements of the actual ice surface. [4] calculated signal penetration based on inversion of volumetric coherence on Union Glacier, Antarctica and validated the results against the optical REMA DEM mosaic over temporally stable surfaces. A recent study on Aletsch Glacier has observed the elevation bias due to signal penetration in a time stamped TanDEM-X DEM by comparing it to a coincident DEM acquisition from Pléiades optical imagery [1]. Moreover, during an inter-comparison experiment on glacier elevation changes, airborne lidar validation DEMs were produced for Aletsch Glacier enabling a comparison of volumetric changes with TanDEM-X measurements [5]. We use these results to analyse the circumstances under which a signal penetration correction layer associated to the individual processed TanDEM-X DEMs can be used to generate bistatic X-band DEMs that reflect the actual ice/snow surface. We will assess the impact of a signal penetration correction on mass balance measurements similar to [6]. References [1] Bannwart, Jacqueline, Livia Piermattei, Inés ...
format Conference Object
genre Antarc*
Antarctica
Union Glacier
genre_facet Antarc*
Antarctica
Union Glacier
geographic Union Glacier
geographic_facet Union Glacier
id ftdlr:oai:elib.dlr.de:214183
institution Open Polar
language English
long_lat ENVELOPE(-82.500,-82.500,-79.750,-79.750)
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op_relation https://elib.dlr.de/214183/1/EGU25-16658_presentation.pdf
Krieger, Lukas und Ibarrola Subiza, Nerea und Floricioiu, Dana und Fischer, Georg und Abdullahi, Sahra (2025) Assessing the TanDEM-X elevation bias due to SAR signal penetration for glacier mass balance measurements. EGU General Assembly 2025, 2025-04-27 - 2025-05-02, Vienna, Austria.
op_rights cc_by_nc_nd
publishDate 2025
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spelling ftdlr:oai:elib.dlr.de:214183 2025-06-15T14:13:24+00:00 Assessing the TanDEM-X elevation bias due to SAR signal penetration for glacier mass balance measurements Krieger, Lukas Ibarrola Subiza, Nerea Floricioiu, Dana Fischer, Georg Abdullahi, Sahra 2025 application/pdf https://elib.dlr.de/214183/ en eng https://elib.dlr.de/214183/1/EGU25-16658_presentation.pdf Krieger, Lukas und Ibarrola Subiza, Nerea und Floricioiu, Dana und Fischer, Georg und Abdullahi, Sahra (2025) Assessing the TanDEM-X elevation bias due to SAR signal penetration for glacier mass balance measurements. EGU General Assembly 2025, 2025-04-27 - 2025-05-02, Vienna, Austria. cc_by_nc_nd SAR-Signalverarbeitung Dynamik der Landoberfläche Radarkonzepte Konferenzbeitrag NonPeerReviewed 2025 ftdlr 2025-06-04T04:58:10Z The elevation bias due to signal penetration in bistatic InSAR DEMs is recognized as a main error source together with co-registration for estimating glacier mass balance with the DEM differencing method. For TanDEM-X DEMs, the elevation processed from X-band (9.65 GHz) SAR data can lie up to 4-8m lower than the actual snow/ice surface in alpine accumulation areas [1]. However, this bias can often be mitigated by differencing TanDEM-X acquisitions from the same season with unchanged SAR geometry, reducing penetration differences between DEMs. The relative importance of SAR signal penetration for accurate mass balance measurements also reduces with the length of the observation period. Notably, methods have been developed to correct for SAR signal penetration bias, including estimating volumetric coherence and inverting it [2,3]. However, correction methods have rarely been tested and validated across entire TanDEM-X scenes with coincident ground truth measurements of the actual ice surface. [4] calculated signal penetration based on inversion of volumetric coherence on Union Glacier, Antarctica and validated the results against the optical REMA DEM mosaic over temporally stable surfaces. A recent study on Aletsch Glacier has observed the elevation bias due to signal penetration in a time stamped TanDEM-X DEM by comparing it to a coincident DEM acquisition from Pléiades optical imagery [1]. Moreover, during an inter-comparison experiment on glacier elevation changes, airborne lidar validation DEMs were produced for Aletsch Glacier enabling a comparison of volumetric changes with TanDEM-X measurements [5]. We use these results to analyse the circumstances under which a signal penetration correction layer associated to the individual processed TanDEM-X DEMs can be used to generate bistatic X-band DEMs that reflect the actual ice/snow surface. We will assess the impact of a signal penetration correction on mass balance measurements similar to [6]. References [1] Bannwart, Jacqueline, Livia Piermattei, Inés ... Conference Object Antarc* Antarctica Union Glacier Unknown Union Glacier ENVELOPE(-82.500,-82.500,-79.750,-79.750)
spellingShingle SAR-Signalverarbeitung
Dynamik der Landoberfläche
Radarkonzepte
Krieger, Lukas
Ibarrola Subiza, Nerea
Floricioiu, Dana
Fischer, Georg
Abdullahi, Sahra
Assessing the TanDEM-X elevation bias due to SAR signal penetration for glacier mass balance measurements
title Assessing the TanDEM-X elevation bias due to SAR signal penetration for glacier mass balance measurements
title_full Assessing the TanDEM-X elevation bias due to SAR signal penetration for glacier mass balance measurements
title_fullStr Assessing the TanDEM-X elevation bias due to SAR signal penetration for glacier mass balance measurements
title_full_unstemmed Assessing the TanDEM-X elevation bias due to SAR signal penetration for glacier mass balance measurements
title_short Assessing the TanDEM-X elevation bias due to SAR signal penetration for glacier mass balance measurements
title_sort assessing the tandem-x elevation bias due to sar signal penetration for glacier mass balance measurements
topic SAR-Signalverarbeitung
Dynamik der Landoberfläche
Radarkonzepte
topic_facet SAR-Signalverarbeitung
Dynamik der Landoberfläche
Radarkonzepte
url https://elib.dlr.de/214183/

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