IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing (Jan 2021)

TanDEM-X:Deriving InSAR Height Changes and Velocity Dynamics of Great Aletsch Glacier

  • Silvan Leinss,
  • Philipp Bernhard

DOI
https://doi.org/10.1109/JSTARS.2021.3078084
Journal volume & issue
Vol. 14
pp. 4798 – 4815

Abstract

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Great Aletsch Glacier (Grosser Aletschgletscher), the largest glacier in the European Alps, contains 20% of the entire Swiss ice mass. Therefore, it has been selected as a super-testsite for the TanDEM-X satellite mission. Dense time series with a repeat interval down to 11 d were acquired between 2011 and 2019 using two polarizations (HH and VV) and across-track baselines of 0–1 km. To evaluate the use of interferometric single-pass synthetic aperture radar mission for glaciological applications, we implemented a processing pipeline in interactive data language (IDL) and computed 130 digital elevation models (DEMs) from bistatic radar interferograms. We present a method to circumvent a common pitfall during orthorectification of radar DEM differences. Regression analysis of DEM time series shows a height loss of up to 8 m a$^{-1}$ on the tongue and 1.5 m a$^{-1}$ when averaged over the whole glacier area. In spring 2013, we observed X-band penetration depths of 4$\pm$2 m in the accumulation area. For strongly crevassed areas, the coherence drops already to 0.5 for across-track baselines $\mathbf {B_\perp }>$ 200 m. With patch-based incoherent offset tracking, we obtained an almost complete 200 m resolution velocity map. Velocities reach up to 0.8 m d$^{-1}$, show a seasonal variability of $\pm$0.05 m d$^{-1}$, and agree within 0.04 m d$^{-1}$(root mean square error) with field measurements. Copolar phase differences suggest an approximation of snow accumulation. We demonstrate orthorectification of the backscatter intensity using simultaneously acquired TanDEM-X interferograms, which allows for the decoupling of horizontal velocity estimates from phase-center height changes due to penetration and ice melt.

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