Super Structure Fault-Tolerance Assessment of the Generalized Hypercube

IF 1.5 4区计算机科学 Q4 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

Computer Journal Pub Date : 2023-07-29 DOI:10.1093/comjnl/bxad072

Chang Shu, Yan Wang, Jianxi Fan, Guijuan Wang

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引用次数: 0

Abstract

Abstract Fault-tolerant performance of a network is the prerequisite and guarantee for the normal operation of a network, which is often characterized by connectivity. Let $H$ denote a connected subgraph of $G$ and $H^{*}$ denote the union of the set of all connected subgraphs of $H$ and the set of the trivial graph. Super $H$-connectivity (resp. super $H^{*}$-connectivity) satisfies the conditions of both super connectivity and $H$-structure connectivity (resp. $H$-substructure connectivity). These two kinds of new connectivity provide a new metric to measure the fault-tolerance of the network, that is, the super structure fault-tolerance. The generalized hypercube $G(m_{r}, m_{r-1},..., m_{1})$ is a universal topology of interconnection networks that contains other commonly used topologies and it has been applied in many data center networks because of its excellent qualities. In this paper, we research the super structure fault-tolerance of $G(m_{r}, m_{r-1},..., m_{1})$ by studying super $H$-connectivity $\kappa ^{\prime}(G|H)$ and super $H^{*}$-connectivity $\kappa ^{\prime}(G|H^{*})$ for $H\in \{K_{1,M},\ C_{3},\ C_{4},\ K_{4}\}$.

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广义超立方体的超结构容错性评估

网络的容错性能是网络正常运行的前提和保证，网络的正常运行往往以连通性为特征。设$H$表示$G$的连通子图，$H^{*}$表示$H$的所有连通子图的集合与平凡图的集合的并集。Super $H$-连接(响应)super $H^{*}$-connectivity)同时满足超级连通性和$H$-结构连通性的条件。H子结构美元连接)。这两种新的连通性提供了一种新的度量网络容错性的指标，即超结构容错性。广义超立方体$G(m_{r}， m_{r-1}，…)m_{1})$是一种包含其他常用拓扑结构的互连网络的通用拓扑结构，由于其优异的性能已在许多数据中心网络中得到应用。本文研究了$G(m_{r}， m_{r-1}，…, m_{1})通过研究超级H连接\美元美元kappa ^ {\ '} (G | H)和超级美元H ^{*}连接\美元kappa ^ {\ '} (G | H ^{*})为H美元在\ \ {K_ {1, M}, \ C_ {3}, \ C_ {4}, \ K_{4} \} $。

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

Computer Journal 工程技术-计算机：软件工程

CiteScore

3.60

自引率

7.10%

发文量

164

审稿时长

4.8 months

期刊介绍： The Computer Journal is one of the longest-established journals serving all branches of the academic computer science community. It is currently published in four sections.