Temporal Cascade Model for Analyzing Spread in Evolving Networks

IF 1.2 Q4 REMOTE SENSING
Aparajita Haldar, Shuang Wang, G. Demirci, Joe Oakley, H. Ferhatosmanoğlu
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引用次数: 2

Abstract

Current approaches for modeling propagation in networks (e.g., of diseases, computer viruses, rumors) cannot adequately capture temporal properties such as order/duration of evolving connections or dynamic likelihoods of propagation along connections. Temporal models on evolving networks are crucial in applications that need to analyze dynamic spread. For example, a disease spreading virus has varying transmissibility based on interactions between individuals occurring with different frequency, proximity, and venue population density. Similarly, propagation of information having a limited active period, such as rumors, depends on the temporal dynamics of social interactions. To capture such behaviors, we first develop the Temporal Independent Cascade (T-IC) model with a spread function that efficiently utilizes a hypergraph-based sampling strategy and dynamic propagation probabilities. We prove this function to be submodular, with guarantees of approximation quality. This enables scalable analysis on highly granular temporal networks where other models struggle, such as when the spread across connections exhibits arbitrary temporally evolving patterns. We then introduce the notion of “reverse spread” using the proposed T-IC processes, and develop novel solutions to identify both sentinel/detector nodes and highly susceptible nodes. Extensive analysis on real-world datasets shows that the proposed approach significantly outperforms the alternatives in modeling both if and how spread occurs, by considering evolving network topology alongside granular contact/interaction information. Our approach has numerous applications, such as virus/rumor/influence tracking. Utilizing T-IC, we explore vital challenges of monitoring the impact of various intervention strategies over real spatio-temporal contact networks where we show our approach to be highly effective.
用于分析进化网络中扩散的时间级联模型
当前用于建模网络中传播(例如,疾病、计算机病毒、谣言)的方法不能充分捕捉时间特性,例如进化连接的顺序/持续时间或沿连接传播的动态可能性。进化网络上的时间模型在需要分析动态传播的应用程序中至关重要。例如,一种传播疾病的病毒具有不同的传播性,这取决于不同频率、接近度和场所人口密度的个体之间的相互作用。同样,活跃期有限的信息(如谣言)的传播取决于社会互动的时间动态。为了捕捉这种行为,我们首先开发了具有扩散函数的时间独立级联(T-IC)模型,该模型有效地利用了基于超图的采样策略和动态传播概率。我们证明了这个函数是子模的,并保证了近似质量。这使得能够在其他模型难以解决的高度细粒度的时间网络上进行可扩展的分析,例如当跨连接的分布呈现出任意的时间演变模式时。然后,我们使用所提出的T-IC过程引入了“反向传播”的概念,并开发了新的解决方案来识别哨兵/检测器节点和高度敏感节点。对真实世界数据集的广泛分析表明,通过考虑不断演变的网络拓扑以及细粒度的接触/交互信息,所提出的方法在建模传播是否发生以及传播如何发生方面显著优于其他方法。我们的方法有许多应用,例如病毒/谣言/影响跟踪。利用T-IC,我们探索了在真实的时空接触网络上监测各种干预策略的影响的重要挑战,在那里我们展示了我们的方法是非常有效的。
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
CiteScore
4.40
自引率
5.30%
发文量
43
期刊介绍: ACM Transactions on Spatial Algorithms and Systems (TSAS) is a scholarly journal that publishes the highest quality papers on all aspects of spatial algorithms and systems and closely related disciplines. It has a multi-disciplinary perspective in that it spans a large number of areas where spatial data is manipulated or visualized (regardless of how it is specified - i.e., geometrically or textually) such as geography, geographic information systems (GIS), geospatial and spatiotemporal databases, spatial and metric indexing, location-based services, web-based spatial applications, geographic information retrieval (GIR), spatial reasoning and mining, security and privacy, as well as the related visual computing areas of computer graphics, computer vision, geometric modeling, and visualization where the spatial, geospatial, and spatiotemporal data is central.
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