Analysing region of attraction of load balancing on complex network

IF 2.2 4区数学 Q2 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS

Journal of complex networks Pub Date : 2022-07-01 DOI:10.1093/comnet/cnac025

Mengbang Zou;Weisi Guo

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引用次数: 2

Abstract

Many complex engineering systems network together functional elements to balance demand spikes but suffer from stability issues due to cascades. The research challenge is to prove the stability conditions for any arbitrarily large and dynamic network topology with any complex balancing function. Most current analyses linearize the system around fixed equilibrium solutions. This approach is insufficient for dynamic networks with multiple equilibria, for example, with different initial conditions or perturbations. Region of attraction (ROA) estimation is needed in order to ensure that the desirable equilibria are reached. This is challenging because a networked system of non-linear dynamics requires compression to obtain a tractable ROA analysis. Here, we employ master stability-inspired method to reveal that the extreme eigenvalues of the Laplacian are explicitly linked to the ROA. This novel relationship between the ROA and the largest eigenvalue in turn provides a pathway to augmenting the network structure to improve stability. We demonstrate using a case study on how the network with multiple equilibria can be optimized to ensure stability.

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复杂网络负载均衡的吸引域分析

许多复杂的工程系统将功能元件连接在一起，以平衡需求峰值，但由于级联而存在稳定性问题。研究的挑战是证明任何具有复杂平衡函数的任意大的动态网络拓扑的稳定性条件。大多数电流分析将系统线性化为固定平衡解。这种方法不适用于具有多重平衡的动态网络，例如，具有不同初始条件或扰动的动态网络。为了确保达到理想的平衡，需要进行吸引区域（ROA）估计。这是具有挑战性的，因为非线性动力学的网络化系统需要压缩以获得易于处理的ROA分析。在这里，我们采用主稳定性启发的方法来揭示拉普拉斯算子的极端特征值与ROA是明确联系的。ROA和最大特征值之间的这种新关系反过来提供了一种增强网络结构以提高稳定性的途径。我们通过案例研究证明了如何优化具有多重平衡的网络以确保稳定性。

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

Journal of complex networks MATHEMATICS, INTERDISCIPLINARY APPLICATIONS-

CiteScore

4.20

自引率

9.50%

发文量

期刊介绍： Journal of Complex Networks publishes original articles and reviews with a significant contribution to the analysis and understanding of complex networks and its applications in diverse fields. Complex networks are loosely defined as networks with nontrivial topology and dynamics, which appear as the skeletons of complex systems in the real-world. The journal covers everything from the basic mathematical, physical and computational principles needed for studying complex networks to their applications leading to predictive models in molecular, biological, ecological, informational, engineering, social, technological and other systems. It includes, but is not limited to, the following topics: - Mathematical and numerical analysis of networks - Network theory and computer sciences - Structural analysis of networks - Dynamics on networks - Physical models on networks - Networks and epidemiology - Social, socio-economic and political networks - Ecological networks - Technological and infrastructural networks - Brain and tissue networks - Biological and molecular networks - Spatial networks - Techno-social networks i.e. online social networks, social networking sites, social media - Other applications of networks - Evolving networks - Multilayer networks - Game theory on networks - Biomedicine related networks - Animal social networks - Climate networks - Cognitive, language and informational network