利用成本面分析和流序分析计算最短路径

2023 IEEE/ACM 23rd International Symposium on Cluster, Cloud and Internet Computing (CCGrid) Pub Date : 2023-05-01 DOI:10.1109/CCGrid57682.2023.00067

Yogesh Dasgaonkar

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引用次数: 0

摘要

我们发现当前最先进的最短路径导航系统有一个计算瓶颈，限制了它们的可扩展性。为了解决这个问题，我们的第一个贡献是一个重要的结果，表明环境中的两点通过更多的几何标准而不仅仅是它们之间的距离相互关联。我们的第二个贡献表明，环境的几何结构允许基于在该点相遇的最短路径的长度来唯一地区分环境中的点。利用这个结果，我们对点进行排序，使它们的排序唯一地区分任意源对和目标对之间的最短路径。通过这两个重要的结果，我们提出了一个用更少的处理资源解决计算瓶颈问题的系统，并且具有比目前最优效率更高的系统。

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Use of Cost Surface Analysis and Stream Order Analysis for Computing Shortest Paths

We find that the current state-of-the-art shortest path navigation systems have a computational bottleneck that limits their scalability. To solve this problem, our first contribution is an important result showing that two points in the environment relate to each other by more geometric criteria than just the distances between them. Our second contribution shows that the environment's geometry is such that it allows for the points in the environment to be uniquely distinguishable based on the length of the shortest paths meeting at that point. Using this result, we order the points, so their ordering uniquely distinguishes the shortest path between any source and destination pair. Through these two important results, we propose a system that solves the computational bottleneck problem using lower processing resources and has higher optimal efficiency than the state-of-the-art.

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来源期刊

2023 IEEE/ACM 23rd International Symposium on Cluster, Cloud and Internet Computing (CCGrid)

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