Tensor and Minimum Connected Dominating Set Based Confident Information Coverage Reliability Evaluation for IoT

IF 3 3区计算机科学 Q2 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

IEEE Transactions on Sustainable Computing Pub Date : 2024-11-25 DOI:10.1109/TSUSC.2024.3503712

Ziheng Xiao;Chenlu Zhu;Wei Feng;Shenghao Liu;Xianjun Deng;Hongwei Lu;Laurence T. Yang;Jong Hyuk Park

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引用次数: 0

Abstract

Internet of Things (IoT) reliability evaluation contributes to the sustainable computing and enhanced stability of the network. Previous algorithms usually evaluate the reliability of IoT by enumenating the states of nodes and networks, which are difficult to handle IoT with hundreds of nodes because the computational cost. In this paper, a novel algorithm, TMCRA, is proposed to evaluate the reliability of IoT in complex network environment, which consider both coverage and connectivity. For coverage, TMCRA employs the Confident Information Coverage (CIC) model to divide the target area into independent grids and calculates the coverage rate. In terms of connectivity, TMCRA forming the Virtual Backbone Network (VBN) based on two proposed methods: TMA and MGIN, and evaluate connectivity by analyzing the VBN rather than the whole network. The TMA and MGIN are two algorithms for constructing Minimum Connected Dominant Sets (MCDS), which are suitable for different scale networks. Finally, based on the data of coverage and connectivity, TMCRA utilizes tensors for the unified modeling and representation of network structure, and calculates IoT reliability based on the tensors. Simulations are carried out for various sizes of IoT to show the advantages and effectiveness of the proposed approach in reliability evaluation.

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基于张量和最小连通支配集的物联网可信信息覆盖可靠性评估

物联网可靠性评估有助于实现网络的持续计算，增强网络的稳定性。以前的算法通常通过枚举节点和网络的状态来评估物联网的可靠性，由于计算成本的原因，难以处理数百个节点的物联网。本文提出了一种新的TMCRA算法来评估复杂网络环境下物联网的可靠性，同时考虑了覆盖和连通性。在覆盖方面，TMCRA采用CIC （confidence Information coverage）模型将目标区域划分为独立的网格并计算覆盖率。在连通性方面，TMCRA基于TMA和MGIN两种提出的方法组成虚拟骨干网（VBN），并通过分析VBN而不是整个网络来评估连通性。TMA和MGIN是构造最小连通优势集（MCDS）的两种算法，适用于不同规模的网络。最后，TMCRA基于覆盖和连通性数据，利用张量对网络结构进行统一建模和表示，并基于张量计算物联网可靠性。对不同规模的物联网进行了仿真，以证明该方法在可靠性评估中的优势和有效性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE Transactions on Sustainable Computing Mathematics-Control and Optimization

CiteScore

7.70

自引率

2.60%

发文量