Tracking Evolving Geometric Data by Local Graph Laplacian Operators

2022 IEEE Western New York Image and Signal Processing Workshop (WNYISPW) Pub Date : 2022-11-04 DOI:10.1109/WNYISPW57858.2022.9983489

Hsun-Hsien Shane Chang

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Abstract

Geometric data are samples on geometric surfaces of physical or abstract objects. When the underlying objects evolve over time, their geometric data change as well. Tracking their evolution is critical to many emerging areas, such as autonomous driving, edge computing networks, and drug interactions. Lacking well-defined grids in geometric data prohibits easy temporal matching for tracking evolution of geometric data. This paper considers the framework of graph signal processing to exploit spectral analysis on geometric surfaces to achieve the tracking task.This paper begins with modeling an underlying geometric surface by a graph, followed by using the spectra of local graph Laplacians to detect graph patches corresponding to regions of high curvatures on the geometric surfaces. The Laplacian spectra of feature graph patches and the structural information of graphs are analyzed together to perform temporal matching across times. Sparse temporal transforms are reconstructed based on the matched feature graph patches, and extrapolating the transforms to the full-scale graph derives the estimation of geometric evolution.

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局部图拉普拉斯算子跟踪几何数据演化

几何数据是物理或抽象物体几何表面上的样本。当底层对象随着时间的推移而变化时，它们的几何数据也会发生变化。跟踪它们的演变对于许多新兴领域至关重要，例如自动驾驶、边缘计算网络和药物相互作用。在几何数据中缺少定义良好的网格，不利于对几何数据的演化进行时间匹配。本文考虑了图形信号处理的框架，利用几何表面的频谱分析来实现跟踪任务。本文首先利用图对底层几何曲面进行建模，然后利用局部图拉普拉斯谱检测几何曲面上高曲率区域对应的图块。将特征图块的拉普拉斯谱和图的结构信息结合起来进行时间匹配。基于匹配的特征图块重构稀疏时间变换，并将变换外推到全尺度图中得到几何演化估计。

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2022 IEEE Western New York Image and Signal Processing Workshop (WNYISPW)

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