Analytical Modelling of the Spread of Disease in Confined and Crowded Spaces

Since 1927 and until recently, most models describing the spread of disease have been of compartmental type, based on the assumption that populations are homogeneous and well-mixed. Recent models have utilised agent-based models and complex networks to explicitly study heterogeneous interaction patterns, but this leads to an increasing computational complexity. Compartmental models are appealing because of their simplicity, but their parameters, especially the transmission rate, are complex and depend on a number of factors, which makes it hard to predict how a change of a single environmental, demographic, or epidemiological factor will affect the population. Therefore, in this contribution we propose a middle ground, utilising crowd-behaviour research to improve compartmental models in crowded situations. We show how both the rate of infection as well as the walking speed depend on the local crowd density around an infected individual. The combined effect is that the rate of infection at a population scale has an analytically tractable non-linear dependency on crowd density. We model the spread of a hypothetical disease in a corridor and compare our new model with a typical compartmental model, which highlights the regime in which current models may not produce credible results.

[1]  W. O. Kermack,et al.  A contribution to the mathematical theory of epidemics , 1927 .

[2]  C. G. Loosli,et al.  The Production of Experimental Influenza in Mice by Inhalation of Atmospheres Containing InfluenzaVirus Dispersed as Fine Droplets , 1943 .

[3]  J. O. Irwin,et al.  MATHEMATICAL EPIDEMIOLOGY , 1958 .

[4]  R. May,et al.  Infectious Diseases of Humans: Dynamics and Control , 1991, Annals of Internal Medicine.

[5]  M. Li,et al.  Global dynamics of a SEIR model with varying total population size. , 1999, Mathematical Biosciences.

[6]  Alessandro Vespignani,et al.  Epidemic dynamics and endemic states in complex networks. , 2001, Physical review. E, Statistical, nonlinear, and soft matter physics.

[7]  Y. Moreno,et al.  Epidemic outbreaks in complex heterogeneous networks , 2001, cond-mat/0107267.

[8]  M. Newman Spread of epidemic disease on networks. , 2002, Physical review. E, Statistical, nonlinear, and soft matter physics.

[9]  Bin Zhao,et al.  Numerical study of the transport of droplets or particles generated by respiratory system indoors , 2004, Building and Environment.

[10]  Lubos Buzna,et al.  Self-Organized Pedestrian Crowd Dynamics: Experiments, Simulations, and Design Solutions , 2005, Transp. Sci..

[11]  S. Kato,et al.  Study on transport characteristics of saliva droplets produced by coughing in a calm indoor environment , 2006 .

[12]  T. Geisel,et al.  The scaling laws of human travel , 2006, Nature.

[13]  Y. Li,et al.  How far droplets can move in indoor environments--revisiting the Wells evaporation-falling curve. , 2007, Indoor air.

[14]  Wenjian Yu,et al.  Modeling crowd turbulence by many-particle simulations. , 2007, Physical review. E, Statistical, nonlinear, and soft matter physics.

[15]  Fred Brauer,et al.  Compartmental Models in Epidemiology , 2008, Mathematical Epidemiology.

[16]  A. Johansson,et al.  Constant-net-time headway as a key mechanism behind pedestrian flow dynamics. , 2009, Physical review. E, Statistical, nonlinear, and soft matter physics.

[17]  K. Nichol,et al.  Modeling Seasonal Influenza Outbreak in a Closed College Campus: Impact of Pre-Season Vaccination, In-Season Vaccination and Holidays/Breaks , 2010, PloS one.

[18]  Ciro Cattuto,et al.  Dynamics of Person-to-Person Interactions from Distributed RFID Sensor Networks , 2010, PloS one.

[19]  Alessandro Vespignani,et al.  Modeling human mobility responses to the large-scale spreading of infectious diseases , 2011, Scientific reports.

[20]  A. Barrat,et al.  Simulation of an SEIR infectious disease model on the dynamic contact network of conference attendees , 2011, BMC medicine.

[21]  Ciro Cattuto,et al.  Empirical temporal networks of face-to-face human interactions , 2013, The European Physical Journal Special Topics.

[22]  A. Barrat,et al.  Estimating Potential Infection Transmission Routes in Hospital Wards Using Wearable Proximity Sensors , 2013, PloS one.

[23]  D. Helbing,et al.  The Hidden Geometry of Complex, Network-Driven Contagion Phenomena , 2013, Science.