Abstract
Phase unwrapping (PU) is a key program in data processing in the interferometric synthetic aperture radar (InSAR) technique, and its accuracy directly affects the quality of final SAR data products. However, PU in regions with large gradient changes and high noise has always been a difficult problem. To overcome the limitation, this article proposes an adaptive square-root unscented Kalman filter PU method. Specifically, a modified phase gradient estimation (PGE) algorithm is proposed, in which a Butterworth low-pass filter is embedded, and the PGE window can be adaptively adjusted according to phase root-mean-square errors of pixels. Furthermore, the outliers of the PGE results are detected and revised to obtain high-precision vertical and horizontal phase gradients. Finally, the unwrapped phase is calculated by the adaptive square-root unscented Kalman filter method. To the best of our knowledge, this article is the first to combine the modified PGE with an adaptive square-root unscented Kalman filter for PU. Two sets of simulated data and a set of TerraSAR-X/TanDEM-X real data were used for experimental verification. The experimental results demonstrated that the various improvement measures proposed in this article were effective. Additionally, compared with the minimum-cost flow algorithm (MCF), statistical-cost network-flow algorithm (SNAPHU) and unscented Kalman filter PU (UKFPU), the proposed method had better accuracy and model robustness.
Highlights
Interferometric synthetic aperture radar (InSAR) has been widely used in detecting crustal deformation [1–3], creating digital elevation models (DEMs) [4,5], etc
The interferograms with the best Phase unwrapping (PU) results of minimum-cost flow algorithm (MCF) were unwrapped by SNAPHU, unscented Kalman filter PU (UKFPU) and ASRUKFPU methods
The PU method based on an adaptive square-root unscented Kalman filter with a modified phase gradient estimation algorithm is proposed
Summary
Interferometric synthetic aperture radar (InSAR) has been widely used in detecting crustal deformation [1–3], creating digital elevation models (DEMs) [4,5], etc. Phase unwrapping (PU) is an imperative step in data processing in the InSAR technique. The error in PU results is relatively great in regions with large gradient changes, and the robustness of PU methods is usually poor in high-noise regions, both of which are the research focus of the PU technique. Classical PU methods are limited by the phase continuity assumption [6], which makes it difficult to obtain ideal results in regions with large gradient changes. Multi-baseline PU methods [7] can eliminate the limitations of the phase continuity assumption, there are still some difficulties in the baseline ratio and the acquisition of multi-baseline data. It is important to develop a PU method that can obtain better PU results in regions with large gradient changes and high noise
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