Efficient network exploration by means of resetting self-avoiding random walkers

IF 2.6 Q1 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS
Gaia Colombani, Giulia Bertagnolli, Oriol Artime
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Abstract

Abstract The self-avoiding random walk (SARW) is a stochastic process whose state variable avoids returning to previously visited states. This non-Markovian feature has turned SARWs a powerful tool for modeling a plethora of relevant aspects in network science, such as network navigability, robustness and resilience. We analytically characterize self-avoiding random walkers that evolve on complex networks and whose memory suffers stochastic resetting, that is, at each step, with a certain probability, they forget their previous trajectory and start free diffusion anew. Several out-of-equilibrium properties are addressed, such as the time-dependent position of the walker, the time-dependent degree distribution of the non-visited network and the first-passage time distribution, and its moments, to target nodes. We examine these metrics for different resetting parameters and network topologies, both synthetic and empirical, and find a good agreement with simulations in all cases. We also explore the role of resetting on network exploration and report a non-monotonic behavior of the cover time: frequent memory resets induce a global minimum in the cover time, significantly outperforming the well-known case of the pure random walk, while reset events that are too spaced apart become detrimental for the network discovery. Our results provide new insights into the profound interplay between topology and dynamics in complex networks, and shed light on the fundamental properties of SARWs in nontrivial environments.
通过重置自回避随机漫步者的有效网络探索
自回避随机漫步(SARW)是一种状态变量避免返回到先前访问状态的随机过程。这种非马尔可夫特征使sarw成为网络科学中大量相关方面建模的强大工具,例如网络可导航性、鲁棒性和弹性。我们分析描述了在复杂网络上进化的自我回避随机行走者,其记忆遭受随机重置,即在每一步,以一定的概率,他们忘记了之前的轨迹并重新开始自由扩散。讨论了几种非平衡特性,如步行者的时间依赖位置、非访问网络的时间依赖度分布和第一次通过时间分布及其到目标节点的矩。我们针对不同的重置参数和网络拓扑(综合的和经验的)检查了这些指标,并在所有情况下发现了与模拟的良好一致。我们还探讨了重置在网络探索中的作用,并报告了覆盖时间的非单调行为:频繁的内存重置会导致覆盖时间的全局最小值,显著优于众所周知的纯随机漫步的情况,而重置事件间隔太长对网络发现有害。我们的研究结果为复杂网络中拓扑和动力学之间的深刻相互作用提供了新的见解,并揭示了非平凡环境中sarw的基本特性。
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 Physics Complexity
Journal of Physics Complexity Computer Science-Information Systems
CiteScore
4.30
自引率
11.10%
发文量
45
审稿时长
14 weeks
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