从前视声纳图像重建水下地形

Jinkun Wang, Tixiao Shan, Brendan Englot
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引用次数: 21

摘要

在本文中,我们提出了一种利用多波束成像声纳进行水下同步定位和测绘的新方法,用于三维地形测绘任务。声纳图像中的高噪声和缺乏仰角信息是数据关联和精确3D绘图的主要挑战。我们不再重复地将提取的特征投影到欧几里得空间中,而是在轴承距离图像中应用光流来跟踪提取的特征。为了处理退化情况,例如当跟踪被噪声打断时,我们将海底地形建模为Chow-Liu树上的高斯过程随机场。在因子图中加入地形因子,以平滑地形高程估计。在仿真环境中验证了算法的性能,结果表明地形因素有效地降低了估计误差。我们还展示了在可变高度的坦克环境中进行的ROV实验,在那里我们能够构建一个描述性的和平滑的坦克底部高度估计。
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Underwater Terrain Reconstruction from Forward-Looking Sonar Imagery
In this paper, we propose a novel approach for underwater simultaneous localization and mapping using a multibeam imaging sonar for 3D terrain mapping tasks. The high levels of noise and the absence of elevation angle information in sonar images present major challenges for data association and accurate 3D mapping. Instead of repeatedly projecting extracted features into Euclidean space, we apply optical flow within bearing-range images for tracking extracted features. To deal with degenerate cases, such as when tracking is interrupted by noise, we model the subsea terrain as a Gaussian Process random field on a Chow–Liu tree. Terrain factors are incorporated into the factor graph, aimed at smoothing the terrain elevation estimate. We demonstrate the performance of our proposed algorithm in a simulated environment, which shows that terrain factors effectively reduce estimation error. We also show ROV experiments performed in a variable-elevation tank environment, where we are able to construct a descriptive and smooth height estimate of the tank bottom.
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