2020
DOI: 10.1029/2019jc015944
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Reassessing the Quality of Sea‐Ice Deformation Estimates Derived From the RADARSAT Geophysical Processor System and Its Impact on the Spatiotemporal Scaling Statistics

Abstract: We reassess the trajectory errors inherent to sea‐ice deformation estimates with a new propagation of uncertainty derivation and show that previous formulations applied to deformation estimates from the RADARSAT Geophysical Processor System (RGPS) are either too high due to incorrect assumptions or too low due to neglected terms in certain cases. We show that when the resulting signal‐to‐noise ratios are used to discriminate the deformation estimates based on their quality, as done for buoy records, the spatio… Show more

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Cited by 8 publications
(24 citation statements)
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References 45 publications
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“…( 15) and ( 16) provided above indicate that statistical uncertainties are not only influenced by geolocation and tracking errors but also depend on the shape and size of grid cells and buoy arrays. In the following discussion we consider magnitudes of geolocation and tracking errors reported in the literature and selected squares and triangles as examples for grid cells in SAR images (Lindsay, 2002;Bouillon and Rampal, 2015) and for splitting large buoy arrays into smaller units (Hutchings et al, 2012;Itkin et al, 2017). The effect of combining several cells is investigated.…”
Section: Discussionmentioning
confidence: 99%
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“…( 15) and ( 16) provided above indicate that statistical uncertainties are not only influenced by geolocation and tracking errors but also depend on the shape and size of grid cells and buoy arrays. In the following discussion we consider magnitudes of geolocation and tracking errors reported in the literature and selected squares and triangles as examples for grid cells in SAR images (Lindsay, 2002;Bouillon and Rampal, 2015) and for splitting large buoy arrays into smaller units (Hutchings et al, 2012;Itkin et al, 2017). The effect of combining several cells is investigated.…”
Section: Discussionmentioning
confidence: 99%
“…Also triangles are used for calculations of deformation parameters in SAR images (e.g., Bouillon and Rampal, 2015;Griebel and Dierking, 2018), and they form the smallest units of buoy arrays (e.g., Hutchings et al, 2011;Hutchings et al, 2012). Using the same approach as for the square above, we obtain the following for a triangle with its base a parallel to…”
Section: Deformation Retrievals From Triangular Grid Cells or Buoy Arraysmentioning
confidence: 99%
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“…To ensure temporal consistency of the RGPS deformation field, we use the Weighted‐Average pre‐processing method (Bouchat & Tremblay, 2020; Hutter & Losch, 2020), which consists in keeping only trajectories forming cells that have (a) simultaneous (±3 hr) start and end times for all fours corners, (b) an average time resolution for all corners that corresponds to the nominal temporal resolution of T * = 3 days, and (c) an area corresponding to the nominal spatial resolution of L * = 10 km. We also require that all corner positions remain at least 100 km away from land for the present analysis.…”
Section: Methodsmentioning
confidence: 99%