具有成对高斯势能和性能保证的主动 SLAM 拓扑信念空间规划

Andrej Kitanov, V. Indelman
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引用次数: 0

摘要

在高维状态空间中直接确定信念空间规划(BSP)的全局最优解耗资巨大,因为这涉及信念传播和每个候选行动的目标函数评估。然而,许多令人感兴趣的问题(如主动式 SLAM)都呈现出结构性,可以利用这种结构性来加快规划速度。此外,为了选择最优行动,只要行动能以相同的方式排序,就不需要目标函数的精确值。在本文中,我们利用这两个关键方面,提出了拓扑信念空间规划(t-bsp)概念,该概念利用拓扑特征对信息论成本函数进行排序,只考虑与未来后验信念相对应的因子图拓扑。我们特别提出了一种基于冯-诺依曼图熵的高效拓扑签名,它是图节点度的函数,支持增量更新。我们在主动姿态 SLAM 的背景下对其进行了分析,并得出了所提出的拓扑签名与原始信息论成本函数之间的误差界限。然后,我们利用这些界限为 t-bsp 提供性能保证,使其相对于原始信息论 BSP 问题的给定求解器。实际和合成仿真表明,与最先进的方法相比,所提出的方法大大加快了速度,同时还保留了选择接近最优解的能力。t-bsp 的概念在一个小规模的真实世界主动 SLAM 实验中得到了证明。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Topological belief space planning for active SLAM with pairwise Gaussian potentials and performance guarantees
Determining a globally optimal solution of belief space planning (BSP) in high-dimensional state spaces directly is computationally expensive, as it involves belief propagation and objective function evaluation for each candidate action. However, many problems of interest, such as active SLAM, exhibit structure that can be harnessed to expedite planning. Also, in order to choose an optimal action, an exact value of the objective function is not required as long as the actions can be sorted in the same way. In this paper we leverage these two key aspects and present the topological belief space planning (t-bsp) concept that uses topological signatures to perform this ranking for information-theoretic cost functions, considering only topologies of factor graphs that correspond to future posterior beliefs. In particular, we propose a highly efficient topological signature based on the von Neumann graph entropy that is a function of graph node degrees and supports an incremental update. We analyze it in the context of active pose SLAM and derive error bounds between the proposed topological signature and the original information-theoretic cost function. These bounds are then used to provide performance guarantees for t-bsp with respect to a given solver of the original information-theoretic BSP problem. Realistic and synthetic simulations demonstrate drastic speed-up of the proposed method with respect to the state-of-the-art methods while retaining the ability to select a near-optimal solution. A proof of concept of t-bsp is given in a small-scale real-world active SLAM experiment.
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