Interferometric SAR coherence arising from the vertically-polarized electromagnetic interrogation of layered, penetrable dielectric media

K. Sainath, F. Teixeira, S. Hensley
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引用次数: 4

Abstract

We model coherence trends in vv-polarized Interferometric Synthetic Aperture Radar (InSAR) images arising specifically from the penetration of electromagnetic (EM) waves into geophysical media. Departing from previous InSAR coherence models, we simultaneously incorporate the interacting effects (on coherence) of (i) “multi-bounce” (wave guidance) within an arbitrary number of dielectric layers, (ii) azimuthal deviation in antenna pointing, (iii) local topography, and (iv) subsurface interface and volume scatter mechanisms. Including multi-bounce phenomena, in particular, allows better understanding of chief mechanisms behind backscatter enhancement, and the resultant strong corruption of InSAR observables, arising from interrogation of strongly guiding geophysical medium layers. Moreover, modeling the subsurface guidance behavior's influence from terrain topography expands upon many previous InSAR models that assumed simpler terrain and sensor geometries. As the two key results of this paper then, we quantitatively elucidate (i) how guidance behavior in dielectric slabs can engender unbounded, diverging interferometric phase bias, as well as (ii) how terrain sloping can render sub-sections of InSAR coherence images, generated by otherwise terrain-robust sensor geometries, susceptible to guidance-related phase bias and correlation degradation.
由层状可穿透介质的垂直极化电磁干扰引起的干涉SAR相干性
我们模拟了v偏振干涉合成孔径雷达(InSAR)图像中的相干趋势,特别是由电磁波穿透地球物理介质引起的相干趋势。与以前的InSAR相干模型不同,我们同时考虑了(i)任意数量介电层内的“多重反弹”(波制导),(ii)天线指向的方位偏差,(iii)局部地形,以及(iv)地下界面和体积散射机制的相互作用(对相干性)。特别是包括多重反弹现象,可以更好地理解后向散射增强背后的主要机制,以及由强导向地球物理介质层引起的InSAR观测结果的强烈破坏。此外,地形地形对地下制导行为影响的建模扩展了许多以前的InSAR模型,这些模型假设了更简单的地形和传感器几何形状。作为本文的两个关键结果,我们定量地阐明了(i)介电板中的制导行为如何产生无界的、发散的干涉相位偏差,以及(ii)地形倾斜如何使InSAR相干图像的子截面容易受到制导相关相位偏差和相关退化的影响,这些图像是由地形鲁棒传感器几何形状生成的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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