RAPID: Collaborative Research: Quarantined Networks and the Spread of COVID-19

RAPID：协作研究：隔离网络和 COVID-19 的传播

• 批准号: 2028892
• 负责人: Matthew Junge
• 金额: $ 5.95万
• 依托单位: Bard College
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2020
• 资助国家: 美国
• 起止时间: 2020-05-01 至 2021-04-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2028892&HistoricalAwards=false
• 关键词: RAPID; Collaborative; Research; Quarantined; Networks

As the global community weighs the necessary extent of quarantine and social distancing to fight the spread of COVID-19, the critical question is how disease transmission is mitigated by these measures. Recent predictions suggest that without serious interventions, a large portion of the world population will become infected, resulting in millions of deaths. To mitigate this worst-case scenario, key policy decisions are being guided by mathematical models. However, several prominent models make unrealistic assumptions about human contacts i.e., that an individual is equally likely to infect a close family member as a complete stranger on the other side of the country. Such assumptions are useful for calculations, but fail to take into account the full geographic complexity of the outbreak. Furthermore, many models do not consider the consequences of the quarantine of healthy individuals. This project will use rigorous analysis and simulation to address these shortcomings by describing a more realistic structure of quarantined networks and how disease spreads in them. The proposed research will use real-world data about contact networks to make predictions and recommendations for controlling the COVID-19 outbreak, improving our understanding of how best to contain the current as well as future pandemics. The project will involve the training of undergraduate students.This research will describe the effect of quarantine on connectivity and disease transmission on more realistic networks than have previously been considered. Of particular importance will be locating critical thresholds which, when exceeded, allow large epidemics to occur. There is recent study of these thresholds, but for networks that model digital infrastructure and social networks. The first objective of the research will be to determine the effect of biased site percolation on graph structure, especially how different percolation rules influence the size of the largest component of a given graph. The second part will then focus on how the critical threshold and size of the epidemic for an SIR model change after percolation. This will be explored rigorously on graphs generated from the configuration model as well as random spatial networks such as Gilbert graphs. Additionally, these questions will be investigated on real world face-to-face networks using data specific to the current COVID-19 pandemic. Answering them will help test robustness of previous models, while also exploring the effectiveness of stronger preemptive distancing.This grant is being awarded using funds made available by the Coronavirus Aid, Relief, and Economic Security (CARES) Act supplemental funds allocated to MPS.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

随着全球社会权衡隔离和社交距离的必要程度以对抗COVID-19的传播，关键问题是这些措施如何减轻疾病传播。最近的预测表明，如果不采取认真的干预措施，世界上很大一部分人口将被感染，导致数百万人死亡。为了缓解这种最坏的情况，关键的政策决定都是以数学模型为指导的。然而，一些著名的模型对人类接触做出了不切实际的假设，即，一个人感染一个亲密的家庭成员的可能性和一个在国家另一边的完全陌生的人一样。这种假设对计算是有用的，但没有考虑到疫情的全部地理复杂性。此外，许多模型没有考虑健康个体隔离的后果。该项目将使用严格的分析和模拟来解决这些缺点，描述一个更现实的隔离网络结构和疾病如何在其中传播。拟议中的研究将使用有关接触网络的真实数据，为控制COVID-19疫情做出预测和建议，提高我们对如何最好地控制当前和未来流行病的理解。该项目将涉及对本科生的培训。这项研究将描述隔离对连通性和疾病传播的影响，这些影响比以前考虑的更现实。特别重要的是确定临界阈值，一旦超过阈值，就会发生大规模流行病。最近对这些阈值进行了研究，但针对的是对数字基础设施和社交网络进行建模的网络。该研究的第一个目标将是确定有偏站点渗流对图结构的影响，特别是不同的渗流规则如何影响给定图的最大分量的大小。第二部分将重点讨论SIR模型的临界阈值和传染病规模在渗流后如何变化。这将严格探讨从配置模型以及随机空间网络，如吉尔伯特图生成的图形。此外，这些问题将在真实的世界面对面网络上使用当前COVID-19大流行的特定数据进行调查。对它们进行验证将有助于测试以前模型的稳健性，同时也有助于探索更强的先发制人距离的有效性。经济安全（CARES）该奖项反映了NSF的法定使命，并通过使用基金会的知识价值和更广泛的影响审查进行评估，被认为值得支持的搜索.