Abstract
The interferometric synthetic aperture radar (InSAR) technique is widely utilized to measure ground-surface displacement. One of the main limitations of the measurements is the atmospheric phase delay effects. For satellites with shorter wavelengths, the atmospheric delay mainly consists of the tropospheric delay influenced by temperature, pressure, and water vapor. Tropospheric delay can be calculated using numerical weather prediction (NWP) model at the same moment as synthetic aperture radar (SAR) acquisition. Scientific researchers mainly use ensemble forecasting to produce better forecasts and analyze the uncertainties caused by physic parameterizations. In this study, we simulated the relevant meteorological parameters using the ensemble scheme of the stochastic physic perturbation tendency (SPPT) based on the weather research forecasting (WRF) model, which is one of the most broadly used NWP models. We selected an area in Foshan, Guangdong Province, in the southeast of China, and calculated the corresponding atmospheric delay. InSAR images were computed through data from the Sentinel-1A satellite and mitigated by the ensemble mean of the WRF-SPPT results. The WRF-SPPT method improves the mitigating effect more than WRF simulation without ensemble forecasting. The atmospherically corrected InSAR phases were used in the stacking process to estimate the linear deformation rate in the experimental area. The root mean square errors (RMSE) of the deformation rate without correction, with WRF-only correction, and with WRF-SPPT correction were calculated, indicating that ensemble forecasting can significantly reduce the atmospheric delay in stacking. In addition, the ensemble forecasting based on a combination of initial uncertainties and stochastic physic perturbation tendencies showed better correction performance compared with the ensemble forecasting generated by a set of perturbed initial conditions without considering the model’s uncertainties.
Highlights
IntroductionInterferometric synthetic aperture radar (InSAR) is a modern technique that has been utilized to identify displacement [1,2], volcano activity, etc
We compared the ensemble mean of integrated water vapor (IWV) with the value of the weather research forecasting (WRF) simulation without stochastic physic perturbation tendency (SPPT) on each date, as shown in WRF-only results varied from −0.5615 to 0.4223 cm, equaling −3.4813 to 2.6183 cm for the ZWD considering the factor of Π−1
This paper proposes the use of the SPPT scheme based on ensemble forecasting with a physical tendency to correct for atmospheric effects in interferogram stacking
Summary
Interferometric synthetic aperture radar (InSAR) is a modern technique that has been utilized to identify displacement [1,2], volcano activity, etc. Measurements from InSAR are usually influenced by the phase delay in the atmosphere, which could reduce the accuracy of subsidence information. A change in humidity of around 20 percent can exist in some extreme cases. Such a change can severely influence the accuracy of the InSAR technique and can even result in errors of up to 10 cm when measuring displacement [5]. When we require a high level of accuracy under some specific circumstances, it is necessary to mitigate the undesirable atmospheric effects
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