Optimal and sub-optimal quarantine and isolation control in SARS epidemics

Yan, Xiefei; Zou, Yun

doi:10.1016/j.mcm.2007.04.003

Cited by 128 publications

(87 citation statements)

References 23 publications

(53 reference statements)

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“…Optimal control has been used, in the past, to find an optimal schedule for vaccine, treatment and chemotherapy for an infected individual. It has also been used to optimally manage the resources associated to quarantine and isolation programs Yan and Zou (2008).…”

Section: Continuous-time Mathematical Modelmentioning

confidence: 99%

“…Since economic resources are limited, epidemiological models have started taking into consideration the economic constraints imposed by limited resources when analyzing control strategies. Optimal control theory has been applied to the mathematical models of HIV models Zarei et al (2010), Kwon et al (2012), Karrakchou et al (2006), Kwon (2007), Roshanfekr et al (2014), , Zhou et al (2014), Adams et al (2005), Costanza et al (2013), Orellana (2011), Malaria Okosun et al (2013, Okosun et al (2011), Okosun and Makinde (2014), Okosun (2011), Kim (2012), Prosper et al (2014), Tuberculosis Moualeu et al (2015), Silva and Torres (2013), Agusto and Adekunle (2014), Bowong and Aziz Alaoui (2013), Whang et al (2011), Vector borne diseases Lashari (2012), Graesboll et al (2014), Sung Lee and Ali Lashari (2014) and other diseases Yan and Zou (2008), Agusto (2013), Brown andJane White (2011), Zaman et al (2008), Okosun and Makinde (2014), Su and Sun (2015), Buonomo et al (2014), Lowden et al (2014), Roshanfekr et al (2014), Apreutesei et al (2014), Imran et al (2014).…”

Section: Introductionmentioning

confidence: 99%

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Optimal control in epidemiology

2015

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Mathematical modelling of infectious diseases has shown that combinations of isolation, quarantine, vaccine and treatment are often necessary in order to eliminate most infectious diseases. However, if they are not administered at the right time and in the right amount, the disease elimination will remain a difficult task. Optimal control theory has proven to be a successful tool in understanding ways to curtail the spread of infectious diseases by devising the optimal diseases intervention strategies. The method consists of minimizing the cost of infection or the cost of implementing the control, or both. This paper reviews the available literature on mathematical models that use optimal control theory to deduce the optimal strategies aimed at curtailing the spread of an infectious disease.

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Section: Continuous-time Mathematical Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Optimal control in epidemiology

2015

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“…More often the cost of implementing a control would be nonlinear. In this paper, a quadratic function is implemented for measuring the control cost (Blayneh et al 2009;Caetano and Yoneyama 2001;Felippe De Souza et al 2000;Joshi 2002;Karrakchou et al 2006;Kirschner et al 1997;Lenhart and Bhat 1992;Lenhart and Yong 1997;Yan et al 2007;Yan and Zou 2008). Furthermore, A 2 S(t f ), A 3 V(t f ) are respectively the fitness of the susceptible and the vaccinated group at the end of the process as a result of a reduction in the rate at which vaccine wanes, vaccinated and treatment efforts are implemented.…”

Section: The Modelmentioning

confidence: 99%

Optimal Control and Sensitivity Analysis of an Influenza Model with Treatment and Vaccination

Khamis²,

et al. 2010

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We formulate and analyze the dynamics of an influenza pandemic model with vaccination and treatment using two preventive scenarios: increase and decrease in vaccine uptake. Due to the seasonality of the influenza pandemic, the dynamics is studied in a finite time interval. We focus primarily on controlling the disease with a possible minimal cost and side effects using control theory which is therefore applied via the Pontryagin's maximum principle, and it is observed that full treatment effort should be given while increasing vaccination at the onset of the outbreak. Next, sensitivity analysis and simulations (using the fourth order Runge-Kutta scheme) are carried out in order to determine the relative importance of different factors responsible for disease transmission and prevalence. The most sensitive parameter of the various reproductive numbers apart from the death rate is the inflow rate, while the proportion of new recruits and the vaccine efficacy are the most sensitive parameters for the endemic equilibrium point.

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“…Equation (4) is the performance function of system (Σ). In the 1-D case, a quadratic function is implemented for measuring the control cost by reference to many papers in control [36]. When a system is 2-D, we need consider a 2-D quadratic cost function, which also means a generalized energy of the two-indexed motion variables.…”

Section: Problem Formulationmentioning

confidence: 99%

Non-Fragile Robust Guaranteed Cost Control of 2-D Discrete Uncertain Systems Described by the General Models

Wang

Zou

et al. 2011

Circuits Syst Signal Process

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The problem of non-fragile robust guaranteed cost control for a class of two-dimensional (2-D) discrete systems in the general model (GM) with norm-bound uncertainties is investigated. The purpose is to design a non-fragile state feedback controller such that the closed-loop system is asymptotically stable and the cost function value is not more than an upper bound for all admissible uncertainties. The cost function is proposed and an upper bound of the cost function is given. By using a linear matrix inequalities (LMIs) approach, a sufficient condition for the solvability of the problem is obtained. A desired non-fragile state feedback controller can be constructed by solving a set of LMIs. An example is provided to demonstrate the application of the proposed design method.

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Optimal and sub-optimal quarantine and isolation control in SARS epidemics

Cited by 128 publications

References 23 publications

Optimal control in epidemiology

Optimal control in epidemiology

Optimal Control and Sensitivity Analysis of an Influenza Model with Treatment and Vaccination

Non-Fragile Robust Guaranteed Cost Control of 2-D Discrete Uncertain Systems Described by the General Models

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