| Literature DB >> 25580055 |
Christopher Barrett1, Keith Bisset1, Shridhar Chandan1, Jiangzhuo Chen1, Youngyun Chungbaek1, Stephen Eubank1, Yaman Evrenosoğlu1, Bryan Lewis1, Kristian Lum1, Achla Marathe1, Madhav Marathe1, Henning Mortveit1, Nidhi Parikh1, Arun Phadke1, Jeffrey Reed1, Caitlin Rivers1, Sudip Saha1, Paula Stretz1, Samarth Swarup1, James Thorp1, Anil Vullikanti1, Dawen Xie1.
Abstract
We present a synthetic information and modeling environment that can allow policy makers to study various counter-factual experiments in the event of a large human-initiated crisis. The specific scenario we consider is a ground detonation caused by an improvised nuclear device in a large urban region. In contrast to earlier work in this area that focuses largely on the prompt effects on human health and injury, we focus on co-evolution of individual and collective behavior and its interaction with the differentially damaged infrastructure. This allows us to study short term secondary and tertiary effects. The present environment is suitable for studying the dynamical outcomes over a two week period after the initial blast. A novel computing and data processing architecture is described; the architecture allows us to represent multiple co-evolving infrastructures and social networks at a highly resolved temporal, spatial, and individual scale. The representation allows us to study the emergent behavior of individuals as well as specific strategies to reduce casualties and injuries that exploit the spatial and temporal nature of the secondary and tertiary effects. A number of important conclusions are obtained using the modeling environment. For example, the studies decisively show that deploying ad hoc communication networks to reach individuals in the affected area is likely to have a significant impact on the overall casualties and injuries.Entities:
Year: 2013 PMID: 25580055 PMCID: PMC4287985 DOI: 10.1109/wsc.2013.6721535
Source DB: PubMed Journal: Proc Winter Simul Conf ISSN: 0891-7736