Transcriptional Regulatory Network Topology with Applications to Bio-inspired Networking: A Survey

Satyaki Roy, P. Ghosh, Nirnay Ghosh, Sajal K. Das
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引用次数: 1

Abstract

The advent of the edge computing network paradigm places the computational and storage resources away from the data centers and closer to the edge of the network largely comprising the heterogeneous IoT devices collecting huge volumes of data. This paradigm has led to considerable improvement in network latency and bandwidth usage over the traditional cloud-centric paradigm. However, the next generation networks continue to be stymied by their inability to achieve adaptive, energy-efficient, timely data transfer in a dynamic and failure-prone environment—the very optimization challenges that are dealt with by biological networks as a consequence of millions of years of evolution. The transcriptional regulatory network (TRN) is a biological network whose innate topological robustness is a function of its underlying graph topology. In this article, we survey these properties of TRN and the metrics derived therefrom that lend themselves to the design of smart networking protocols and architectures. We then review a body of literature on bio-inspired networking solutions that leverage the stated properties of TRN. Finally, we present a vision for specific aspects of TRNs that may inspire future research directions in the fields of large-scale social and communication networks.
转录调控网络拓扑在生物启发网络中的应用:综述
边缘计算网络范例的出现使计算和存储资源远离数据中心,更接近网络的边缘,主要由收集大量数据的异构物联网设备组成。与传统的以云为中心的范例相比,这种范例大大改善了网络延迟和带宽使用。然而,下一代网络继续受到其无法在动态和易发生故障的环境中实现自适应、节能、及时的数据传输的阻碍,而这正是生物网络在数百万年的进化过程中所面临的优化挑战。转录调控网络(TRN)是一种生物网络,其固有的拓扑鲁棒性是其底层图拓扑的函数。在本文中,我们调查了TRN的这些属性以及由此得出的指标,这些指标有助于智能网络协议和体系结构的设计。然后,我们回顾了利用TRN所述属性的生物启发网络解决方案的文献。最后,我们对trn的具体方面提出了一个愿景,这可能会激发大规模社会和通信网络领域未来的研究方向。
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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