Your search keyword '"Kieran J. Sharkey"' showing total 4 results

1. Evolutionary bet-hedging in structured populations

Author

Kieran J. Sharkey and Christopher E. Overton

Subjects

0106 biological sciences, 92-10, Evolution, media_common.quotation_subject, Population, Evolutionary graph theory, 010603 evolutionary biology, 01 natural sciences, Models, Biological, Competition (biology), Article, 03 medical and health sciences, Selection, Genetic, education, Selection (genetic algorithm), Ecosystem, 030304 developmental biology, media_common, Population Density, 0303 health sciences, education.field_of_study, Natural selection, Extinction, Applied Mathematics, Population size, Agricultural and Biological Sciences (miscellaneous), Adaptation, Physiological, Biological Evolution, Stochastic process, 92D15, Geography, Variation (linguistics), Evolutionary biology, Fitness variance, Modeling and Simulation, 92D40, Networks

Abstract

As ecosystems evolve, species can become extinct due to fluctuations in the environment. This leads to the evolutionary adaption known as bet-hedging, where species hedge against these fluctuations to reduce their likelihood of extinction. Environmental variation can be either within or between generations. Previous work has shown that selection for bet-hedging against within-generational variation should not occur in large populations. However, this work has been limited by assumptions of well-mixed populations, whereas real populations usually have some degree of structure. Using the framework of evolutionary graph theory, we show that through adding competition structure to the population, within-generational variation can have a significant impact on the evolutionary process for any population size. This complements research using subdivided populations, which suggests that within-generational variation is important when local population sizes are small. Together, these conclusions provide evidence to support observations by some ecologists that are contrary to the widely held view that only between-generational environmental variation has an impact on natural selection. This provides theoretical justification for further empirical study into this largely unexplored area. Supplementary Information The online version supplementary material available at 10.1007/s00285-021-01597-z.

Published

2020

2. Pair-level approximations to the spatio-temporal dynamics of epidemics on asymmetric contact networks

Author

E.J. Peeler, James F. Turnbull, Kieran J. Sharkey, Roger G. Bowers, Kenton L. Morgan, M.A. Thrush, and Carmen Suárez Fernández

Subjects

Stochastic Processes, Operations research, Spatial structure, Stochastic process, Computer science, Applied Mathematics, Process (computing), Symmetric model, Contact network, Agricultural and Biological Sciences (miscellaneous), Communicable Diseases, Models, Biological, Disease Outbreaks, Differential equation models, Transmission (telecommunications), Modeling and Simulation, Computer Simulation, Statistical physics, Closing (morphology)

Abstract

The process of infection during an epidemic can be envisaged as being transmitted via a network of routes represented by a contact network. Most differential equation models of epidemics are mean-field models. These contain none of the underlying spatial structure of the contact network. By extending the mean-field models to pair-level, some of the spatial structure can be contained in the model. Some networks of transmission such as river or transportation networks are clearly asymmetric, whereas others such as airborne infection can be regarded as symmetric. Pair-level models have been developed to describe symmetric contact networks. Here we report on work to develop a pair-level model that is also applicable to asymmetric contact networks. The procedure for closing the model at the level of pairs is discussed in detail. The model is compared against stochastic simulations of epidemics on asymmetric contact networks and against the predictions of the symmetric model on the same networks.

Published

2005

3. Pair-level approximations to the spatio-temporal dynamics of epidemics on asymmetric contact networks.

Author

Kieran J. Sharkey, Carmen Fernandez, Kenton L. Morgan, Edmund Peeler, Mark Thrush, James F. Turnbull, and Roger G. Bowers

Abstract

The process of infection during an epidemic can be envisaged as being transmitted via a network of routes represented by a contact network. Most differential equation models of epidemics are mean-field models. These contain none of the underlying spatial structure of the contact network. By extending the mean-field models to pair-level, some of the spatial structure can be contained in the model. Some networks of transmission such as river or transportation networks are clearly asymmetric, whereas others such as airborne infection can be regarded as symmetric. Pair-level models have been developed to describe symmetric contact networks. Here we report on work to develop a pair-level model that is also applicable to asymmetric contact networks. The procedure for closing the model at the level of pairs is discussed in detail. The model is compared against stochastic simulations of epidemics on asymmetric contact networks and against the predictions of the symmetric model on the same networks. [ABSTRACT FROM AUTHOR]

Published

2006

4. Deterministic epidemiological models at the individual level

Author

Kieran J. Sharkey

Subjects

Mathematical optimization, Closed set, Population, Population Dynamics, Systems Theory, Context (language use), Communicable Diseases, Disease Outbreaks, Modelling and Simulation, Stochastic simulation, Master equation, Deterministic simulation, Disease Transmission, Infectious, State space, Cluster Analysis, Humans, Quantitative Biology::Populations and Evolution, education, Ecosystem, Mathematics, education.field_of_study, Stochastic Processes, Models, Statistical, Applied Mathematics, Agricultural and Biological Sciences (miscellaneous), Systems Integration, Modeling and Simulation, Carrier State, Neural Networks, Computer, Epidemiologic Methods, Deterministic system

Abstract

In many fields of science including population dynamics, the vast state spaces inhabited by all but the very simplest of systems can preclude a deterministic analysis. Here, a class of approximate deterministic models is introduced into the field of epidemiology that reduces this state space to one that is numerically feasible. However, these reduced state space master equations do not in general form a closed set. To resolve this, the equations are approximated using closure approximations. This process results in a method for constructing deterministic differential equation models with a potentially large scope of application including dynamic directed contact networks and heterogeneous systems using time dependent parameters. The method is exemplified in the case of an SIR (susceptible-infectious-removed) epidemiological model and is numerically evaluated on a range of networks from spatially local to random. In the context of epidemics propagated on contact networks, this work assists in clarifying the link between stochastic simulation and traditional population level deterministic models.