Abstract
Synthetic aperture radar tomography (TomoSAR) is an important 3D mapping method. Traditional TomoSAR requires a large number of observation orbits however, it is hard to meet the requirement of massive orbits. While on the one hand, this is due to funding constraints, on the other hand, because the target scene is changing over time and each observation orbit consumes lots of time, the number of orbits can be fewer as required within a narrow time window. When the number of observation orbits is insufficient, the signal-to-noise ratio (SNR), peak-to-sidelobe ratio (PSR), and resolution of 3D reconstruction results will decline severely, which seriously limits the practical application of TomoSAR. In order to solve this problem, we propose to use a deep learning network to improve the resolution and SNR of 3D reconstruction results under the condition of very few observation orbits by learning the prior distribution of targets. We use all available orbits to reconstruct a high resolution target, while only very few (around 3) orbits to reconstruct a low resolution input. The low-res and high-res 3D voxel-grid pairs are used to train a 3D super-resolution (SR) CNN (convolutional neural network) model, just like ordinary 2D image SR tasks. Experiments on the Civilian Vehicle Radar dataset show that the proposed deep learning algorithm can effectively improve the reconstruction both in quality and in quantity. In addition, the model also shows good generalization performance for targets not shown in the training set.
Highlights
Synthetic aperture radar tomography (TomoSAR) is an advanced SAR interferemetric technique that is able to reconstruct the 3D information of a target scene [1,2,3,4,5]
Different from the above work, our goal focuses on using deep learning algorithm to reconstruct high resolution 3D images of cars, which have more complex and meticulous structures, from low resolution 3D images generated with a small number of observations in cross-track direction
In order to figure out the value inprovement in details, the dominant points are divided into four groups according to the rank of their strength
Summary
Synthetic aperture radar tomography (TomoSAR) is an advanced SAR interferemetric technique that is able to reconstruct the 3D information of a target scene [1,2,3,4,5]. SAR tomography requires at least 20 interferometric tracks to build high resolution results [6]. TomoSAR has many advantages, there is only a limited number of acquisitions accessible in most cases [7], which degrades the cross-track spatial resolution and worsens the image quality because of the decrease of signal-tonoise ratio (SNR) and peak-to-sidelobe ratio (PSR). Reconstructing 3D information from a small number of cross-track samples has been an important research topic in the SAR 3D reconstruction field [9,10,11]. The SAR sensor travels along a flight path such that the antenna phase center has a three-dimensional spatial location as:
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