Hopf bifurcation and optimal control of a delayed malware propagation model on mobile wireless sensor networks
Hu Zhang, Ranjit Kumar Upadhyay, Guiyun Liu, Zizhen Zhang
Abstract
In present paper, a delayed SEIR model of malware propagation on mobile wireless sensor networks is formulated. Basic reproduction number of the model is calculated by employing the next generation matrix method and impact of the time delay due to incubation period of malware is discussed with the help of eigenvalue method. What is more, properties of the Hopf bifurcation are derived by using center manifold method. To minimize number of the infectious nodes and the cost related with detoxication, an optimal control strategy is presented by constructing a suitable Hamiltonian function. Numerical calculations are performed to justify the obtained theoretical findings.
Topics & Concepts
Hopf bifurcationMalwareEigenvalues and eigenvectorsComputer scienceCenter manifoldBifurcationBasic reproduction numberControl theory (sociology)WirelessWireless sensor networkOptimal controlMathematical optimizationApplied mathematicsMathematicsControl (management)PhysicsComputer networkArtificial intelligenceNonlinear systemTelecommunicationsOperating systemQuantum mechanicsPopulationDemographySociologyMathematical and Theoretical Epidemiology and Ecology ModelsOpinion Dynamics and Social Influencestochastic dynamics and bifurcation