GB-InSAR Atmospheric Correction Method Based on Downsampled HQPs and Its Application to Slope Deformation Monitoring

doi:10.11988/ckyyb.20231211

Abstract

Abstract:

Continuous slope monitoring in reservoirs and dams using ground-based synthetic aperture radar interferometry (GB-InSAR) is vulnerable to atmospheric environmental fluctuations. These fluctuations can cause inaccuracies in deformation results derived from interferogram sequences. Moreover, processing large volumes of continuous GB-SAR images is time-consuming, which negatively affects the overall efficiency of GB-InSAR and the feasibility of quasi-real-time deformation analysis applications. To tackle these problems, this paper presents a uniform grid sampling method and interferometric stacking technique based on the phase gradient building on the conventional polynomial atmospheric correction method. A polynomial atmospheric correction method based on downsampled high-quality pixels (HQPs) is then constructed. This method is applied to monitor the deformation of the high slope on the right bank during the construction of the Huangdeng Hydropower Station. Experimental results show that the root mean square error (RMSE) of the binary polynomial model averages 0.039 5 rad, significantly outperforming that of the unitary model and other conventional correction methods. The average RMSE of the proposed method is 0.024 0 rad, comparable to the accuracy before downsampling. However, the overall solution time reduces notably from 2.32 h to 0.80 h. This indicates that the proposed method can significantly improve the efficiency of continuous image atmospheric correction while maintaining modeling accuracy, offering effective technical support for slope safety monitoring.

Key words: atmospheric correction, Ground-based interferometry Synthetic Aperture Radar, downsampled high-quality pixel, binary polynomial, deformation monitoring

CLC Number:

P237测绘遥感技术

WANG Peng, LI Wei-cheng, DUAN Hang, KE Chuan-fang, GE Li-cheng, JIN Xiao. GB-InSAR Atmospheric Correction Method Based on Downsampled HQPs and Its Application to Slope Deformation Monitoring[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(3): 156-163.

Figures/Tables 13

Fig.1 Flowchart of interferogram polynomial atmospheric correction technique based on downsampled HQP

Fig.2 Location of slope and perspectives of radar monitoring

Table 1 Parameters related to IBIS-L equipment

参数	数值	参数	数值
雷达频率	17.05~17.35 GHz	方位分辨率	4.3 mrad
带宽	300 MHz	采样时间间隔	5.6 min
波长	17.6 mm	最大监测距离	1 km
距离分辨率	0.50 m

Fig.3 The original interference phase unwrapped with the HQP phase

Fig.4 Results of three atmospheric modelling methods for the 393rd interferogram

Fig.5 Results of atmospheric modelling with univariate and binary polynomials

Fig.6 Distribution of polynomial model phase difference and residual statistical histogram

Fig.7 HQP distribution before and after downsampling

Fig.8 Deformation rate distribution

Fig.9 A binary polynomial atmospheric phase model based on downsampled HQP

Table 2 Comparison of processing time for different atmospheric correction methods

大气改正方法	相位解缠耗时/h	大气改正耗时/h	总耗时/h
单参考点法	1.45	0.91	2.36
多参考点法		0.96	2.41
空间滤波法		0.90	2.35
一元多项式模型		1.21	2.66
二元多项式模型		0.87	2.32
本文方法	0.48	0.32	0.80

Fig.10 Comparison of goodness-of-fit and RSME accuracy of different atmospheric correction methods

Table 3 Comparison of RMSE mean values of different atmospheric correction methods

大气改正方法	RMSE均值/ rad	大气改正方法	RMSE均值/ rad
单参考点法	1.357 0	一元多项式模型	0.170 4
多参考点法	2.382 9	二元多项式模型	0.039 5
空间滤波法	0.260 6	本文方法	0.024 0

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