Discontinuity, Nonlinearity, and Complexity
Applications of Short Memory Fractional Differential Equations with Impulses
Discontinuity, Nonlinearity, and Complexity 12(1) (2023) 167--182 | DOI:10.5890/DNC.2023.03.012
Babak Shiri$^1$, Guo-Cheng Wu$^1$, Dumitru Baleanu$^{2,3}$
Download Full Text PDF
Abstract
Dynamical systems' behavior is sometimes varied with some impulse and sudden changes in process. The dynamics of these systems can not be modeled by previous concepts of derivative or fractional derivatives any longer. The short memory concept is a solution and a better choice for fractional modeling of such processes. We apply short memory fractional differential equations for these systems. We propose collocation methods based on piecewise polynomials to approximate solutions of these equations. We provide various examples to demonstrate the application of the short memory derivative for impulse systems and efficiency of the presented numerical methods.
References
-
[1]  |
Bhatt, H. and Khaliq, A.Q.M. (2016), A Fourth order compact scheme for reaction-diffusion systems with non-smooth data, Journal of Computational and Applied Mathematics, 299, 176-193.
|
-
[2]  |
Dorf, R. and Bishop, R. (1998), Modern Control Systems, 12th ed. Prentice Hall, Upper Saddle River, New Jersey.
|
-
[3]  |
Zarnitsina, V., Ataullakhanov, F., Lobanov, A., and Morozova, O. (2001), Dynamics
of spatially nonuniform patterning in the model of blood coagulation,
Chaos: An Interdisciplinary Journal of Nonlinear Science, 11, 57-70.
|
-
[4]  |
Karamali, G. and Shiri, B. (2018), Numerical solution of higher index DAEs using their IAE's structure: Trajectory-prescribed path control problem and simple pendulum, Caspian Journal of Mathematical Sciences, 7, 1-15.
|
-
[5]  |
Shiri, B. (2014), Numerical solution of higher index nonlinear integral algebraic equations of Hessenberg type using discontinuous collocation methods, Mathematical Modelling and Analysis, 19, 99-117.
|
-
[6]  |
Hajipour, M., Jajarmi, A., and Baleanu, D. (2018), An efficient nonstandard finite difference scheme for a class of fractional chaotic systems, Journal of Computational and Nonlinear Dynamics, 13, 021013.
|
-
[7]  |
Liu, S., Wang, J., Zhou, Y., and Fečkan, M. (2018),
Iterative learning control with pulse compensation for fractional differential systems, Mathematica Slovaca, 68, 563-574.
|
-
[8]  |
Li, C.P. and Ma, Y. (2013), Fractional dynamical system and its linearization theorem, Nonlinear Dynamics, 71, 621-633.
|
-
[9]  |
Chaudhary, N.I., Aslam, M.S., Baleanu, D., and Raja, M.A.Z. (2020), Design of sign fractional optimization paradigms for parameter estimation of nonlinear Hammerstein systems, Neural Computing and Applications, 32, 8381-8399.
|
-
[10]  |
Dassios, I. and Baleanu, D. (2018), Optimal solutions for singular linear systems of Caputo fractional differential equations, Mathematical Methods in the Applied Sciences, 6, 1-13.
|
-
[11]  |
Hilfer, R. (2000), Applications of Fractional Calculus in Physics, world scientific, Singapor.
|
-
[12]  |
Baleanu, D., Shiri, B., Srivastava, H.M., and Al Qurashi, M. (2018), A Chebyshev spectral method based on operational matrix for fractional differential equations involving non-singular Mittag-Leffler kernel, Advances in Difference Equations, 2018(1), 1-23.
|
-
[13]  |
Bhatt, H.P., Khaliq, A.Q.M., and Furati, K.M. (2020), Efficient high-order compact exponential time differencing method for space-fractional reaction-diffusion systems with nonhomogeneous boundary conditions, Numerical Algorithms, 83(2019), 1373-1397.
|
-
[14]  |
Shah, K., Khan, R.A., and Baleanu, D. (2019), Study of implicit type coupled system of non-integer order differential equations with antiperiodic boundary conditions, Mathematical Methods in the Applied Sciences, 42, 2033-2042.
|
-
[15]  |
Podlubny, I. (1999), Fractional Differential Equations, Academic Press, San Diego.
|
-
[16]  |
Qureshi, S., Yusuf, A., Shaikh, A.A., Inc, M., and Baleanu, D. (2019), Fractional modeling of blood ethanol concentration system with real data application, Chaos: An Interdisciplinary Journal of Nonlinear Science, 29, 013143.
|
-
[17]  |
Tang, Y. and Fang, J.A. (2010), Synchronization of N-coupled fractional-order chaotic systems with ring connection, Communications in Nonlinear Science and Numerical Simmulation, 15, 401-412.
|
-
[18]  |
Tang, Y., Wang, Z., and Fang, J.A. (2009), Pinning control of fractional-order weighted complex networks, Chaos: An Interdisciplinary Journal of Nonlinear Science, 19, 013112.
|
-
[19]  |
Benchohra, M., Henderson, J., and Ntouyas, S. (2006), Impulsive Differential Equations and Inclusions, Hindawi Publishing Corporation: New York.
|
-
[20]  |
Chu, J. and Nieto, J.J. (2008), Impulsive periodic solutions of first-order singular differential equations, Bulletin of the London Mathematical Society, 40, 143-150.
|
-
[21]  |
Lakshmikantham, V. and Simeonov, P.S. (1989) , Theory of Impulsive Differential Equations, World scientific, Singapore.
|
-
[22]  |
Li, X., Bohner, M., and Wang, C.K. (2015), Impulsive differential equations: periodic solutions and applications, Automatica, 52, 173-178.
|
-
[23]  |
Nieto, J.J. and O'Regan, D. (2009), Variational approach to impulsive differential equations, Nonlinear Analysis: Real World Applications, 10, 680-690.
|
-
[24]  |
Zhou, Y., Wang, J., and Zang, L. (2016), Basic Theory of Fractional Differential Equations, World Scientific, New Jersey.
|
-
[25]  |
Feckan, M., Zhou, Y., Wang, J. (2012), On the concept and existence of solution for impulsive fractional differential equations, Communications in Nonlinear Science and Numerical Simulation, 17, 3050-3060.
|
-
[26]  |
Feckan, M., Wang, J.R., and Zhou, Y. (2011), On the new concept of solutions and existence results for impulsive fractional evolution equations, Dynamics of Partial Differential Equations, 8, 345-361.
|
-
[27]  |
Wang, J., Fe{\v{c}}kan, M., and Zhou, Y. (2016), A survey on impulsive fractional differential equations. Fractional Calculus and Applied Analysis, 19, 806-831.
|
-
[28]  |
Wang, J., Ibrahim, A.G., Fečkan, M., and Zhou, Y. (2017), Controllability of fractional non-instantaneous impulsive differential inclusions without compactness, IMA Journal of Mathematical Control and Information, 36, 443-460.
|
-
[29]  |
Yang, X., Li, C., Huang, T., and Song, Q. (2017), Mittag-Leffler stability analysis of nonlinear fractional-order systems with impulses, Applied Mathematics and Computation, 293, 416-422.
|
-
[30]  |
Wu, G.C. Zeng, D.Q., and Baleanu, D. (2019), Fractional impulsive differential equations: Exact solutions, integral equations and short memory case, Fractional Calculus and Applied Analysis, 22, 180-192.
|
-
[31]  |
Wu, G.C., Deng, Z.G., Baleanu, D., and Zeng, D.Q. (2019), New variable-order fractional chaotic systems for fast image encryption, Chaos: An Interdisciplinary Journal of Nonlinear Science, 29, 083103.
|
-
[32]  |
Srivastava, H.M., Shanker Dubey, R., and Monika, J. (2019), A study of the fractional-order mathematical model of diabetes and its resulting complications, Mathematical Methods in the Applied Sciences, 42, 4570-4583.
|
-
[33]  |
Diethelm, K. (2010), The Analysis of Fractional Differential Equations: An Application-Oriented Exposition Using Differential Operators of Caputo Type, Springer Science \& Business Media, Berlin.
|
-
[34]  |
Li, K. and Peng, J. (2011), Laplace transform and fractional differential equations, Applied Mathematics Letters, 24, 2019-2023.
|
-
[35]  |
G{o}mez, J.F., Torres, L., and Escobar, R.F. (2019), Fractional Derivatives with Mittag-Leffler Kernel, Springer, Berlin.
|
-
[36]  |
Gorenflo, R., Kilbas, A.A., Mainardi, F., and Rogosin, S.V. (2014), Mittag-Leffler Functions, Related Topics and Applications, 2ed ed. Springer, Berlin,
|
-
[37]  |
Brunner, H. (2004), Collocation Methods for Volterra Integral and Related Functional
Differential Equations, Cambridge University Press, Cambridge.
|
-
[38]  |
Baleanu, D. and Shiri, B. (2018), Collocation methods for fractional differential equations involving non-singular kernel, Chaos, Solitons $\&$ Fractals, 116, 136-145.
|
-
[39]  |
Ding, H. and Li, C.P. (2013), Mixed spline function method for reaction-subdiffusion equations, Journal of Computational Physics, 242, 103-123.
|
-
[40]  |
Luo, W.H., Huang, T.Z., Wu, G.C., and Gu, X.M. (2016), Quadratic spline collocation method for the time fractional subdiffusion equation, Applied Mathematics and Computation, 276, 252-265.
|
-
[41]  |
Pedas, A. and Tamme, E. (2011), Spline collocation methods for linear milti-term fractional differential equations,
Journal of Computational and Applied Mathematics, 236, 167-176.
|
-
[42]  |
Pedas, A. and Tamme, E. (2011), On the convergence of spline collocation methods for solving fractional differential equations, Journal of Computational and Applied Mathematics, 235, 3502-3514.
|
-
[43]  |
Boutayeb, A., Twizell, E., Achouayb, K., and Chetouani, A. (2004), A mathematical
model for the burden of diabetes and its complications, BioMedical Engineering OnLine,
3(1), 1-8.
|
-
[44]  |
Li, C.P. and Chen, G. (2004), Chaos in the fractional order Chen system and its control, Chaos, Solitons \& Fractals, 22, 549-554.
|
-
[45]  |
Deng, W. (2007), Short memory principle and a predictor-corrector approach for fractional differential equations, Journal of Computational and Applied Mathematics, 206, 174-188.
|