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Fault-Tolerant and Unicast Performances of the Data Center Network HSDC

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Abstract

In order to satisfy the rapidly increasing demand for data volume, large data center networks (DCNs) have been proposed. In 2019, Zhang et al. proposed a new highly scalable DCN architecture named HSDC (Highly Scalable Data Center Network), which can achieve greater incremental scalability. In this paper, we give the definition of the logical graph of HSDC, named \(H_n\), which can be treated as a compound graph of hypercube and complete graph of the same dimension. First, we prove that the connectivity and tightly super connectivity of \(H_n\) are both n. Then, we give an O(n) shortest unicast algorithm to find a shortest path between any two distinct nodes in \(H_n\), and prove the correctness of this algorithm. In fact, we also prove that the  length of the shortest path constructed by this algorithm is no more than \(2d+1\) if \(d<n\) and at most 2d if \(d=n\), where d is the Hamming distance between  the start and end nodes, and the diameter of \(H_n\) is 2n.

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Acknowledgements

This work was supported by the National Natural Science Foundation of China (Nos. U1905211 and 61972272) and the Project Funded by the Priority Academic Program Development of Jiangsu Higher Education Institutions.

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Authors and Affiliations

  1. School of Computer Science and Technology, Soochow University, Suzhou, China

    Hui Dong, Jianxi Fan, Baolei Cheng, Yan Wang & Jingya Zhou

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  1. Hui Dong
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  2. Jianxi Fan
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  3. Baolei Cheng
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  4. Yan Wang
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Correspondence to Jianxi Fan.

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Dong, H., Fan, J., Cheng, B. et al. Fault-Tolerant and Unicast Performances of the Data Center Network HSDC. Int J Parallel Prog 49, 700–714 (2021). https://doi.org/10.1007/s10766-021-00699-x

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