L 波段 InSAR 时间序列中的电离层补偿:赤道地区缓慢形变背景下的性能评估

IF 5.7 Q1 ENVIRONMENTAL SCIENCES
Léo Marconato , Marie-Pierre Doin , Laurence Audin , Erwan Pathier
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引用次数: 0

摘要

多时合成孔径雷达干涉测量法(MT-InSAR)是唯一一种能够测量连续区域地面变形的大地测量技术,最小可达到毫米/年。赤道地区的植被覆盖有利于使用 L 波段合成孔径雷达数据来提高干涉测量的一致性。然而,影响合成孔径雷达信号传播的电离层电子含量在赤道附近显示出特别强烈的时空变化,而电离层的色散性质使其对低频(如 L 波段信号)的影响更强。为解决这一问题,可采用范围分谱法补偿电离层的相位贡献。在此,我们将这一技术应用于 ALOS-PALSAR 数据的时间序列,并提出了针对低相干区域的优化方案。为了评估这种方法检索赤道地区微妙形变率的效率,我们使用四个 ALOS-PALSAR 数据集计算了中低相干背景下的时间序列,这些数据集显示了缓慢的形变率(毫米/年至厘米/年)。处理过的轨迹位于厄瓜多尔、特立尼达和苏门答腊,有 15 至 19 次采集,其中电离层噪声非常大,占主导地位,相当于等效位移达 2 米。这是由于赤道 TEC 分布经常出现高度非线性的扰动模式。我们使用半变量图来量化校正后时间序列的不确定性,强调其与空间距离的关系。因此,利用类似 ALOS-PALSAR 的档案,我们可以预期视线速度的探测阈值在 3 到 6 毫米/年之间,这取决于要观测的信号的空间波长。这些数值与通过比较重叠区域内两条轨道的速度得出的精确度是一致的。在我们处理的案例研究中,从电离层校正的时间序列可以准确检索断层蠕变和火山信号,但对于检索微小的长波长信号(如缓慢的(毫米/年)震间应变累积)来说,噪声仍然太大。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Ionospheric compensation in L-band InSAR time-series: Performance evaluation for slow deformation contexts in equatorial regions

Multi-temporal Synthetic Aperture Radar Interferometry (MT-InSAR) is the only geodetic technique allowing to measure ground deformation down to mm/yr over continuous areas. Vegetation cover in equatorial regions favors the use of L-band SAR data to improve interferometric coherence. However, the electron content of ionosphere, affecting the propagation of the SAR signal, shows particularly strong spatio-temporal variations near the equator, while the dispersive nature of the ionosphere makes its effect stronger on low-frequencies, such as L-band signals. To tackle this problem, range split-spectrum method can be implemented to compensate the ionospheric phase contribution. Here, we apply this technique for time-series of ALOS-PALSAR data, and propose optimizations for low-coherence areas. To evaluate the efficiency of this method to retrieve subtle deformation rates in equatorial regions, we compute time-series using four ALOS-PALSAR datasets in contexts of low to medium coherence, showing slow deformation rates (mm/yr to cm/yr). The processed tracks are located in Ecuador, Trinidad and Sumatra, and feature 15 to 19 acquisitions including very high, dominating ionospheric noise, corresponding to equivalent displacements of up to 2 m. The correction method performs well and allows to reduce drastically the noise level due to ionosphere, with significant improvement compared with a simple plane fitting method. This is due to frequent highly non-linear patterns of perturbation, characterizing equatorial TEC distribution. We use semivariograms to quantify the uncertainty of the corrected time-series, highlighting its dependence on spatial distance. Thus, using ALOS-PALSAR-like archive, one can expect a detection threshold on the Line-of-Sight velocity ranging between 3 and 6 mm/yr, depending on the spatial wavelength of the signal to be observed. These values are consistent with the accuracy derived from the comparison of velocities between two tracks in their overlapping area. In the case studies that we processed, the time-series corrected from ionosphere allows to retrieve accurately fault creep and volcanic signal but it is still too noisy for retrieving tiny long-wavelength signals such as slow (mm/yr) interseismic strain accumulation.

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