Fitting dynamic models to epidemic outbreaks with quantified uncertainty: A primer for parameter uncertainty, identifiability, and forecasts

Fitting dynamic models to epidemic outbreaks with quantified uncertainty: A primer for parameter uncertainty, identifiability, and forecasts

Mathematical models provide a quantitative framework with which scientists can assess hypotheses on the potential underlying mechanisms that explain patterns in observed data at different spatial and temporal scales, generate estimates of key kinetic parameters, assess the impact of interventions, o...

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Main Author: Gerardo Chowell
Format: Article
Language:English
Published: KeAi Communications Co., Ltd. 2017-08-01
Series:Infectious Disease Modelling
Online Access:http://www.sciencedirect.com/science/article/pii/S2468042717300234
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spelling doaj-84e1342ef8eb4cc8be788f349575ba042021-02-02T08:39:30ZengKeAi Communications Co., Ltd.Infectious Disease Modelling2468-04272017-08-0123379398Fitting dynamic models to epidemic outbreaks with quantified uncertainty: A primer for parameter uncertainty, identifiability, and forecastsGerardo Chowell0Division of Epidemiology & Biostatistics, School of Public Health, Georgia State University, Atlanta, GA, USA; Division of International Epidemiology and Population Studies, Fogarty International Center, National Institutes of Health, Bethesda, MD, USA; School of Public Health, Georgia State University, Atlanta, GA, USA.Mathematical models provide a quantitative framework with which scientists can assess hypotheses on the potential underlying mechanisms that explain patterns in observed data at different spatial and temporal scales, generate estimates of key kinetic parameters, assess the impact of interventions, optimize the impact of control strategies, and generate forecasts. We review and illustrate a simple data assimilation framework for calibrating mathematical models based on ordinary differential equation models using time series data describing the temporal progression of case counts relating, for instance, to population growth or infectious disease transmission dynamics. In contrast to Bayesian estimation approaches that always raise the question of how to set priors for the parameters, this frequentist approach relies on modeling the error structure in the data. We discuss issues related to parameter identifiability, uncertainty quantification and propagation as well as model performance and forecasts along examples based on phenomenological and mechanistic models parameterized using simulated and real datasets. Keywords: Parameter estimation, Uncertainty quantification, Bootstrap, Parameter identifiability, Model performance, Forecasts, Uncertainty propagationhttp://www.sciencedirect.com/science/article/pii/S2468042717300234
collection DOAJ
language English
format Article
sources DOAJ
author Gerardo Chowell
spellingShingle Gerardo Chowell
Fitting dynamic models to epidemic outbreaks with quantified uncertainty: A primer for parameter uncertainty, identifiability, and forecasts
Infectious Disease Modelling
author_facet Gerardo Chowell
author_sort Gerardo Chowell
title Fitting dynamic models to epidemic outbreaks with quantified uncertainty: A primer for parameter uncertainty, identifiability, and forecasts
title_short Fitting dynamic models to epidemic outbreaks with quantified uncertainty: A primer for parameter uncertainty, identifiability, and forecasts
title_full Fitting dynamic models to epidemic outbreaks with quantified uncertainty: A primer for parameter uncertainty, identifiability, and forecasts
title_fullStr Fitting dynamic models to epidemic outbreaks with quantified uncertainty: A primer for parameter uncertainty, identifiability, and forecasts
title_full_unstemmed Fitting dynamic models to epidemic outbreaks with quantified uncertainty: A primer for parameter uncertainty, identifiability, and forecasts
title_sort fitting dynamic models to epidemic outbreaks with quantified uncertainty: a primer for parameter uncertainty, identifiability, and forecasts
publisher KeAi Communications Co., Ltd.
series Infectious Disease Modelling
issn 2468-0427
publishDate 2017-08-01
description Mathematical models provide a quantitative framework with which scientists can assess hypotheses on the potential underlying mechanisms that explain patterns in observed data at different spatial and temporal scales, generate estimates of key kinetic parameters, assess the impact of interventions, optimize the impact of control strategies, and generate forecasts. We review and illustrate a simple data assimilation framework for calibrating mathematical models based on ordinary differential equation models using time series data describing the temporal progression of case counts relating, for instance, to population growth or infectious disease transmission dynamics. In contrast to Bayesian estimation approaches that always raise the question of how to set priors for the parameters, this frequentist approach relies on modeling the error structure in the data. We discuss issues related to parameter identifiability, uncertainty quantification and propagation as well as model performance and forecasts along examples based on phenomenological and mechanistic models parameterized using simulated and real datasets. Keywords: Parameter estimation, Uncertainty quantification, Bootstrap, Parameter identifiability, Model performance, Forecasts, Uncertainty propagation
url http://www.sciencedirect.com/science/article/pii/S2468042717300234
work_keys_str_mv AT gerardochowell fittingdynamicmodelstoepidemicoutbreakswithquantifieduncertaintyaprimerforparameteruncertaintyidentifiabilityandforecasts
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