Abstract
Very high requirement of co-registration accuracy better than 0.001 pixels for Sentinel-1 TOPS (Terrain Observation by Progressive Scan) mode presents a great challenge for application of SAR (synthetic aperture radar) interferometry in Earth Observation. The state-of-the-art techniques have demonstrated that the low coherence scenarios and abrupt loss of coherence between two arbitrary acquisitions are main sources of error to degrade the performance of TOPS time-series co-registration. In this paper, we present a modification to overcome both limitations through the coherence enhancement. The motive behind this is to improve the quality of observations before co-registration and meanwhile avoiding the coherence loss caused by fast decorrelation. To this end, principal components analysis based spatio-temporal filtering is first used to remove the artifacts in burst interferograms over strong noise areas. Rather than heuristically choosing a sub-set of interferograms as a small baseline technique does, we use Dijkstra's shortest path algorithm under graph theory framework to maximize the coherence of a sub-set interferograms. The performance of presented method against the state-of-the-art techniques is fully evaluated by synthetic data and a Sentinel-1A stack over a low coherence scene in Indonesia. Comprehensive comparisons demonstrate 9%–17% uncertainty reduction of time-series co-registration when applying our method.
Highlights
T HE Sentinel-1 satellite constellation has proven its capabilities in geodetic applications of synthetic aperture radar (SAR) by the advantages of the short revisit cycle (6 days for the combination of A and B) and the extensive coverage under the Interferometric Wide swath mode (IW)
We presented a modification for Sentinel-1 Terrain Observations by Progressive Scans (TOPS) time-series co-registration over low coherence scenarios
The primary novelties lie in (1) using principal components analysis (PCA) analysis to enhance signalto-noise ratio (SNR) of the phase series and simultaneously reducing artifacts caused by spatial smoothness over strong noise areas, and (2) employing a single source shortest path algorithm to refine temporal network instead of heuristically choosing a sub-set of interferograms as SBAS does
Summary
T HE Sentinel-1 satellite constellation has proven its capabilities in geodetic applications of synthetic aperture radar (SAR) by the advantages of the short revisit cycle (6 days for the combination of A and B) and the extensive coverage under the Interferometric Wide swath mode (IW). Terrain Observations by Progressive Scans (TOPS) [1], [2], the default SAR imaging mode of IW, can capture three sub-swaths with a width of 250 kilometers and achieve the entire antenna pattern of each observed target on Earth. A co-registration accuracy up to 0.001 pixels is required to remove the phase inconsistence of 3 degrees for orbital error of 5cm in the along-track direction [3]. Such high accuracy can be generally achieved by a two-step strategy: (1) coarse geometrical co-registration [4] based on external Digital Elevation Model (DEM) and precise orbital information; (2) fine co-registration using Enhanced Spectral Diversity (ESD) technique
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