自组织机器人网络拓扑可恢复性预测:一种数据驱动的容错方法

IF 3 3区计算机科学 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Signal and Information Processing over Networks Pub Date : 2023-10-30 DOI:10.1109/TSIPN.2023.3328275

Matin Macktoobian;Zhan Shu;Qing Zhao

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引用次数: 0

摘要

在自组织机器人网络中发生的故障可能会对其拓扑结构造成致命的扰动，从而导致网络子集的断开。对于大型自组织机器人网络，实时进行最优拓扑综合通常需要耗费大量资源和时间。只有当任何故障发生后拓扑可恢复的概率超过其不可恢复的概率时，才应该进行拓扑重新计算。我们把这个问题表述为一个二元分类问题。在此基础上，建立了基于贝叶斯高斯混合模型的双路径数据驱动模型，该模型通过两种不同的故障前和故障后预测路径来预测典型问题的解。通过整合这些路径的预测得到的结果清楚地表明，与目前文献中发现的最佳策略相比，我们的模型在解决拓扑(ir)可恢复性预测问题方面取得了成功。

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Topology Recoverability Prediction for Ad-Hoc Robot Networks: A Data-Driven Fault-Tolerant Approach

Faults occurring in ad-hoc robot networks may fatally perturb their topologies leading to disconnection of subsets of those networks. Optimal topology synthesis is generally resource-intensive and time-consuming to be done in real time for large ad-hoc robot networks. One should only perform topology re-computations if the probability of topology recoverability after the occurrence of any fault surpasses that of its irrecoverability. We formulate this problem as a binary classification problem. Then, we develop a two-pathway data-driven model based on Bayesian Gaussian mixture models that predicts the solution to a typical problem by two different pre-fault and post-fault prediction pathways. The results, obtained by the integration of the predictions of those pathways, clearly indicate the success of our model in solving the topology (ir)recoverability prediction problem compared to the best of current strategies found in the literature.

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来源期刊

IEEE Transactions on Signal and Information Processing over Networks Computer Science-Computer Networks and Communications

CiteScore

5.80

自引率

12.50%

发文量

期刊介绍： The IEEE Transactions on Signal and Information Processing over Networks publishes high-quality papers that extend the classical notions of processing of signals defined over vector spaces (e.g. time and space) to processing of signals and information (data) defined over networks, potentially dynamically varying. In signal processing over networks, the topology of the network may define structural relationships in the data, or may constrain processing of the data. Topics include distributed algorithms for filtering, detection, estimation, adaptation and learning, model selection, data fusion, and diffusion or evolution of information over such networks, and applications of distributed signal processing.