Yunting Song, Riccardo Fellegara, F. Iuricich, Leila De Floriani
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引用次数: 0
摘要
我们要解决的问题是,如何在三角形网格的紧凑分布式数据结构--地形树上执行拓扑感知简化算法。拓扑感知算子已被定义为在不影响底层地形拓扑的情况下粗化三角形不规则网络(TIN),即不修改地形的关键特征,如坑、鞍、峰及其连接性。然而,对于大规模网格,它们的可扩展性是有限的。我们提出的算法采用分批处理策略,减少了简化过程对内存和时间的要求,而且由于基于地形树的空间分解,该算法可以轻松实现并行化。此外,由于简化过程后的地形树变得不那么紧凑和高效,我们提出了一种高效的后处理步骤,用于更新分层空间分解。我们在真实世界的 TIN 上进行了实验,这些 TIN 来源于地形和测深 LiDAR 数据,证明了我们方法的可扩展性和高效性。具体来说,与最紧凑、最高效的基于连接性的 TIN 数据结构相比,在地形树上进行拓扑感知简化可节省 40% 的内存和一半的时间。此外,采用 OpenMP 实现的 Terrain 树并行简化算法的速度提高了 12 倍。Terrain 树的分布式并行简化策略对输出网格的质量影响不大,与全局基准方法相比,我们获得了相似的质量水平。
Parallel Topology-aware Mesh Simplification on Terrain Trees
We address the problem of performing a topology-aware simplification algorithm on a compact and distributed data structure for triangle meshes, the Terrain trees. Topology-aware operators have been defined to coarsen a Triangulated Irregular Network (TIN) without affecting the topology of its underlying terrain, i.e., without modifying critical features of the terrain, such as pits, saddles, peaks, and their connectivity. However, their scalability is limited for large-scale meshes. Our proposed algorithm uses a batched processing strategy to reduce both the memory and time requirements of the simplification process and thanks to the spatial decomposition on the basis of Terrain trees, it can be easily parallelized. Also, since a Terrain tree after the simplification process becomes less compact and efficient, we propose an efficient post-processing step for updating hierarchical spatial decomposition. Our experiments on real-world TINs, derived from topographic and bathymetric LiDAR data, demonstrate the scalability and efficiency of our approach. Specifically, topology-aware simplification on Terrain trees uses 40% less memory and half the time compared to the most compact and efficient connectivity-based data structure for TINs. Furthermore, the parallel simplification algorithm on the Terrain trees exhibits a 12x speedup with an OpenMP implementation. The quality of the output mesh is not significantly affected by the distributed and parallel simplification strategy of Terrain trees, and we obtain similar quality levels compared to the global baseline method.
期刊介绍:
ACM Transactions on Spatial Algorithms and Systems (TSAS) is a scholarly journal that publishes the highest quality papers on all aspects of spatial algorithms and systems and closely related disciplines. It has a multi-disciplinary perspective in that it spans a large number of areas where spatial data is manipulated or visualized (regardless of how it is specified - i.e., geometrically or textually) such as geography, geographic information systems (GIS), geospatial and spatiotemporal databases, spatial and metric indexing, location-based services, web-based spatial applications, geographic information retrieval (GIR), spatial reasoning and mining, security and privacy, as well as the related visual computing areas of computer graphics, computer vision, geometric modeling, and visualization where the spatial, geospatial, and spatiotemporal data is central.