Have a personal or library account? Click to login

An unconditionally positive and global stability preserving NSFD scheme for an epidemic model with vaccination

International Journal of Applied Mathematics and Computer Science
Volume 24 (2014): Issue 3 (September 2014)
By:
Open Access
|Sep 2014

References

  1. Alexander, M.E., Summers, A.R. and Moghadas, S.M. (2006). Neimark-Sacker bifurcations in a non-standard numerical scheme for a class of positivity-preserving ODEs, Proceedings of the Royal Society, A: Mathematical, Physical and Engineering Sciences 462(2074): 3167-3184.10.1098/rspa.2006.1724
    Search in Google Scholar
  2. Anderson, R. and May, R. (1991). Infectious Diseases of Hu- mans: Dynamics and Control, Oxford University Press, Oxford/New York, NY.
    Search in Google Scholar
  3. Anguelo, V.R. and Lubuma, J. (2003). Nonstandard finite difference method by nonlocal approximation, Mathematics and Computers in Simulation 61(3): 465-475.10.1016/S0378-4754(02)00106-4
    Search in Google Scholar
  4. Arenas, A., Morao, J. and Cort´es, J. (2008). Non-standard numerical method for a mathematical model of RSV epidemiological transmission, Computers and Mathematics with Applications 56(3): 670-678.10.1016/j.camwa.2008.01.010
    Search in Google Scholar
  5. Bruggeman, J., Burchard, H., Kooi, B.W. and Sommeijer, B. (2007). A second-order, unconditionally positive, mass-conserving integration scheme for biochemical systems, Applied Numerical Mathematics 57(1): 36-58.10.1016/j.apnum.2005.12.001
    Search in Google Scholar
  6. Chen, M. and Clemence, D. (2006). Stability properties of a nonstandard finite difference scheme for a hantavirus epidemic model, Journal of Difference Equations and Applications 12(12): 1243-1256.10.1080/10236190600986537
    Search in Google Scholar
  7. Chinviriyasit, S. and Chinviriyasit, W. (2010). Numerical modelling of an SIR epidemic model with diffusion, Applied Mathematics and Computation 216(2): 395-409. Dimitrov, D.T. and Kojouharov, H. (2005). Nonstandard finite-difference schemes for general two-dimensional autonomous dynamical systems, Applied Mathematics Letters 18(7): 769-774.
    Search in Google Scholar
  8. Dimitrov, D. and Kojouharov, H. (2007). Stability-preserving finite-difference methods for general multi-dimensional autonomous dynamical systems, International Journal of Numerical Analysis and Modeling 4(2): 280-290.
    Search in Google Scholar
  9. Dimitrov, D. and Kojouharov, H. (2008). Nonstandard finite difference methods for predator-prey models with general functional response, Mathematics and Computers in Simulation 78(1): 1-11.10.1016/j.matcom.2007.05.001
    Search in Google Scholar
  10. Ding, D., Ma, Q. and Ding, X. (2013). A non-standard finite difference scheme for an epidemic model with vaccination, Journal of Difference Equations and Applications 19(2): 179-190.10.1080/10236198.2011.614606
    Search in Google Scholar
  11. Dumont, Y. and Lubuma, J.M.-S. (2005). Non-standard finite-difference methods for vibro-impact problems, Proceedings of the Royal Society, A: Mathematical, Physical and Engineering Sciences 461(2058): 1927-1950. Enatsu, Y., Nakata, Y. and Muroya, Y. (2010). Global stability for a class of discrete SIR epidemic models, Mathematical Biosciences and Engineering 7: 347-361.
    Search in Google Scholar
  12. Enszer, J.A. and Stadtherr, M.A. (2009). Verified solution method for population epidemiology models with uncertainty, International Journal of Applied Mathematics and Computer Science 19(3): 501-512, DOI: 10.2478/v10006-009-0040-4.10.2478/v10006-009-0040-4
    Search in Google Scholar
  13. Gumel, A. (2002). A competitive numerical method for a chemotherapy model of two HIV subtypes, Applied Mathematics and Computation 131(2): 329-337.10.1016/S0096-3003(01)00150-3
    Search in Google Scholar
  14. Hildebrand, F. (1968). Finite Difference Equations and Simulations, Prentice-Hall, Englewood Cliffs, NJ.
    Search in Google Scholar
  15. Jódar, L., Villanueva, R., Arenas, A. and Gonz´alez, G. (2008). Nonstandard numerical methods for a mathematical model for influenza disease, Mathematics and Computers in Simulation 79(3): 622-633.10.1016/j.matcom.2008.04.008
    Search in Google Scholar
  16. Jang, S. (2007). On a discrete west Nile epidemic model, Computational and Applied Mathematics 26(3): 397-414.10.1590/S0101-82052007000300005
    Search in Google Scholar
  17. Jang, S. and Elaydi, S. (2003). Difference equations from discretization of a continuous epidemic model with immigration of infectives, Canadian Applied Mathematics Quarterly 11(1): 93-105. Jansen, H. and Twizell, E. (2002). An unconditionally convergent discretization of the SEIR model, Mathematics and Computers in Simulation 58(2): 147-158.
    Search in Google Scholar
  18. Kouche, M. and Ainseba, B. (2010). A mathematical model of HIV-1 infection including the saturation effect of healthy cell proliferation, International Journal of Applied Mathematics and Computer Science 20(3): 601-612, DOI: 10.2478/v10006-010-0045-z.10.2478/v10006-010-0045-z
    Search in Google Scholar
  19. Lambert, J. (1973). Computational Methods in Ordinary Differential Equations, Wiley, New York, NY.
    Search in Google Scholar
  20. Ma, Z., Zhou, Y., Wang, W. and Jing, Z. (2004). The Mathematical Modeling and Study of the Dynamics of Infectious Diseases, Science Press, Beijing.
    Search in Google Scholar
  21. Mickens, R. (1994). Nonstandard Finite Difference Models of Differential Equations, World Scientific, Singapore.10.1142/2081
    Search in Google Scholar
  22. Mickens, R. (2000). Advances in the Applications of Nonstandard Finite Difference Schemes, World Scientific, Singapore. Mickens, R. (2002). Nonstandard finite difference schemes for differential equations, Journal of Difference Equations and Applications 8(9): 823-847.10.1142/4272
    Search in Google Scholar
  23. Mickens, R. (2005). Dynamic consistency: A fundamental principle for constructing nonstandard finite difference schemes for differential equations, Journal of Difference Equations and Applications 11(7): 645-653.10.1080/10236190412331334527
    Search in Google Scholar
  24. Moghadas, S., Alexander, M. and Corbett, B.D.and Gumel, A. (2003). A positivity preserving Mickens-type discretization of an epidemic model, Journal of Difference Equations and Applications 9(11): 1037-1051.10.1080/1023619031000146913
    Search in Google Scholar
  25. Moghadas, S. and Gumel, A. (2003). A mathematical study of a model for childhood diseases with non-permanent immunity, Journal of Computational and Applied Mathematics 157(2): 347-363.10.1016/S0377-0427(03)00416-3
    Search in Google Scholar
  26. Muroya, Y., Nakata, Y., Izzo, G. and Vecchio, A. (2011). Permanence and global stability of a class of discrete epidemic models, Nonlinear Analysis: Real World Applications 12(4): 2105-2117. Obaid, H., Ouifki, R. and Patidar, K.C. (2013). An unconditionally stable nonstandard finite difference method applied to a mathematical model of HIV infection, International Journal of Applied Mathematics and Computer Science 23(2): 357-372, DOI: 10.2478/amcs-2013-0027.10.2478/amcs-2013-0027
    Search in Google Scholar
  27. Oran, E. and Boris, J. (1987). Numerical Simulation of Reactive Flow, Elsevier, New York, NY.
    Search in Google Scholar
  28. Parra, G.G., Arenas, A. and Charpentier, B.C. (2010). Combination of nonstandard schemes and Richardson’s extrapolation to improve the numerical solution of population models, Mathematical and Computer Modelling 52(7): 1030-1036.10.1016/j.mcm.2010.03.015
    Search in Google Scholar
  29. Potter, D. (1973). Computational Physics, Wiley-Interscience, New York, NY.
    Search in Google Scholar
  30. Sekiguchi, M. (2009). Permanence of some discrete epidemic models, International Journal of Biomathematics 2(4): 443-461. Sekiguchi, M. (2010). Permanence of a discrete SIRS epidemic model with time delays, Applied Mathematics Letters 23(10): 1280-1285.
    Search in Google Scholar
  31. Sekiguchi, M. and Ishiwata, E. (2010). Global dynamics of a discretized SIRS epidemic model with time delay, Journal of Mathematical Analysis and Applications 371(1): 195-202.10.1016/j.jmaa.2010.05.007
    Search in Google Scholar
  32. Stuart, A. and Humphries, A. (1996). Dynamic System and Numerical Analysis, Cambridge University Press, Cambridge.
    Search in Google Scholar
  33. Sundarapandian, V. (2003). An invariance principle for discrete-time nonlinear systems, Applied Mathematics Letters 16(1): 85-91. 10.1016/S0893-9659(02)00148-9
    Search in Google Scholar
DOI: https://doi.org/10.2478/amcs-2014-0046 | Journal eISSN: 2083-8492 | Journal ISSN: 1641-876X
Journal RSS Feed
Language: English
Page range: 635 - 646
Submitted on: May 31, 2013
Published on: Sep 25, 2014
Published by: Sciendo
In partnership with: Paradigm Publishing Services
Publication frequency: 4 times per year
Keywords:
nonstandard finite differences,
unconditional positivity,
stability,
Lyapunov function
Related subjects:
Mathematics,
Applied mathematics

© 2014 Deqiong Ding, Qiang Ma, Xiaohua Ding, published by Sciendo
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.

Previous articleVolume 24 (2014): Issue 3 (September 2014)Next article