On the Stability of Systems of Nonlinear Ordinary Differential Equations of Fractional Order

Ordinary differential equations of fractional order have been presented as a tool of vital importance in modeling the anomalous dynamics of various problems from the exact sciences and engineering, however, is still under discussion a clear and coherent theory analogous to the classical theory of ordinary differential equations. The nonlocal character of their fractional operators provides additional information that allows the development of a comprehensive analysis of the mathematical models. Within these fractional order differential equations, the qualitative approach is an open topic of study at present, in which stability analysis plays a preponderant role. This article presents a description of recent results on the stability of nonlinear fractional order ordinary differential equations and some analytical methods used. First of all, this article presents and describes the fundamental concepts of the study of stability of systems of ordinary differential equations of fractional order, both linear and nonlinear. The results of this research provide fundamental tools in the study of the stability of systems of nonlinear fractional order differential equations that can be applied to various models of applied sciences and engineering.

Keywords: fractional analysis, fractional differential equations, stability of fractional equations, Mittag-Leffler stability, Lyapunov functions.

https://doi.org/10.55463/issn.1674-2974.50.7.7

BERTRAM R. Fractional Calculus and Its Applications. Lecture Notes in Mathematics. Springer-Verlag, New York, 1975.

SÁNCHEZ J M. Génesis y desarrollo del Cálculo Fraccional. Pensamiento Matemático, 2011, 1: 1-15. http://www2.caminos.upm.es/Departamentos/matematicas/re vistapm/revista_impresa/numero_1/genesis_y_desarrollo_del

_calculo_fraccional.pdf

PODLUBNY I. Geometric and Physical Interpretation of Fractional Integration and Fractional Differentiation. arXiv:Math-0110241v1, 2001: 1-18.

https://arxiv.org/abs/math/0110241

HILFER R. Applications of Fractional Calculus in Physics. World Scientific Publishing, Universitat Mainz, 2000.

https://www.worldscientific.com/worldscibooks/10.1142/37 79#t=aboutBook

LOVERRO A. Fractional Calculus: History, Definitions and Applications for the Engineer, Department of Aerospace and Mechanical Engineering, University of Notre Dame Notre, 2004.

https://www.semanticscholar.org/paper/Fractional-Calculus-

%3A-History-%2C-Definitions-and-for-

Loverro/6256fee0c10bdb7096df51ca8e64df58414ed026

KILBAS A, BLANCA A, and TRUJILLO J J. Kilbas,

Cálculo fraccionario y ecuaciones diferenciales fraccionarias, UNED,. 1, 2003.

HENDY A S, ZAKY M A, and TENREIRO MACHADO

J A. On the Cole–Hopf transformation and integration by parts formulae in computational methods within fractional differential equations and fractional optimal control theory. Journal of Vibration and Control, 2022, 28(21-22): 3364-3370.

LOPES A M, and TENREIRO MACHADO J A.

Nonlinear Dynamics. Mathematics, 2022, 10 (15): 2227-

HASSANI H, TENREIRO MACHADO J A,

AVAZZADEH Z, et al. Optimal solution of the fractional- order smoking model and its public health implications. Nonlinear Dynamics, 2022, 108, 2815-2831.

HASSANI H, AVAZZADEH Z, TENREIRO

MACHADO J A, et al. Optimal Solution of a Fractional HIV/AIDS Epidemic Mathematical Model. Journal of Computational Biology, , 2022, 29(3): 276-291, https://doi.org/10.1089/cmb.2021.0253.

KEIGHOBADI J, PAHNEHKOLAEI S M A, ALFI A,

and TENREIRO MACHADO J A. Command-filtered compound FAT learning control of fractional-order nonlinear systems with input delay and external disturbances. Nonlinear Dynamics, 2022, 108: 293-313.

NIKAN O, GOLBABAI A, TENREIRO MACHADO J

A, and NIKAZAD T. Numerical approximation of the time fractional cable model arising in neuronal dynamics. Engineering with Computers, 2022, 38: 155-173.

MAGIN M D, ORTIGUEIRA I, PODLUBNY I, and

TRUJILLO J J. On the fractional signals and systems. Signal Processing, 2011, 91(3): 350-371.

ORTIGUEIRA M D, and BENGOCHEA G. A Simple

Solution for the General Fractional Ambartsumian Equation.

Applied Sciences, 2023, 13(2): 871.

BENGOCHEA G, and ORTIGUEIRA M D. Operational Calculus with Applications to Generalized Two-Sided Fractional Derivative. Proceedings of the International Conference on Fractional Differentiation and its Applications (ICFDA’21). Lecture Notes in Networks and Systems, 2022, 452.

ORTIGUEIRA M D. Fractional Calculus for Scientists and Engineers. Springer Dordrecht London, New York, 2011.

BALEANU D, DIETHELM K, SCALAS E, and

TRUJILLO J J. Fractional calculus: models and numerical methods. Series on Complexity, Nonlinearity and Chaos, 3, World Scientific, 2012.

ATANGANA A, and BALEANU D. New Fractional Derivatives with Nonlocal and Non-Singular Kernel: Theory and Application to Heat Transfer Model. Thermal Science, 2016, 20, https://doi.org/10.2298/TSCI160111018A.

SUN H G, ZHANG Y, BALEANU D, et al. A new

collection of real world applications of fractional calculus in science and engineering, Communications in Nonlinear Science and Numerical Simulation, 2018, 64: 213-231.

BALEANU D, TENREIRO MACHADO J A, and LUO,

A C J. Fractional dynamics and control. Springer Science and Business Media, New York, 2011.

BALEANU D, JAJARMI A, MOHAMMADI H, and

REZAPOUR S. A new study on the mathematical modelling of human liver with Caputo–Fabrizio fractional derivative. Chaos, Solitons and Fractals, 2020, 134: 109705.

BALEANU D, MOHAMMADI H, and REZAPOUR H.

A fractional differential equation model for the COVID-19 transmission by using the Caputo–Fabrizio derivative. Advances in Difference Equations, 2020: 299.

BALEANU D, MOHAMMADI H, and REZAPOUR H.

Analysis of the model of HIV-1 infection of CD4+T-cell with a new approach of fractional derivative. Advances in Difference Equations, 2020: 71.

KILBAS A, SRIVASTAVA H, and TRUJILLO J J.

Theory and Applications of Fractional Differential Equations, North Holland Mathematics Studies, Elsevier, Amsterdam, 2006.

MATIGNON D. Stability results for fractional differential equations with applications to control processing. Computational Engineering in Systems Applications, 1996, 2: 963-968.

TARASOV V E. Fractional derivative as fractional power of derivative. International Journal of Mathematics, 2007, 18(3): 281-299.

https://doi.org/10.1142/S0129167X07004102

LI Y, CHEN Y Q, and PODLUBNY I. Mittag-Leffler stability of fractional order nonlinear dynamic systems. Automatica, 2009, 45(8): 1965–1969.

https://doi.org/10.1016/j.automatica.2009.04.003

LI Y, CHEN Y Q, and PODLUBNY I. Stability of fractional order nonlinear dynamic systems: Lyapunov direct method and generalized Mittag-Leffler stability. Computers and Mathematics with Applications, 2010, 59(5): 1810-1821. https://doi.org/10.1016/j.camwa.2009.08.019

LI C P, and ZHANG F R. A survey on the stability of fractional differential equations. European Physical Journal: Special Topics, 2011, 193(1): 27–47.

https://doi.org/10.1140/epjst/e2011-01379-1

SHANTANU D. Functional Fractional Calculus. Second Edition, Springer-Verlag Berlin Heidelberg, 2011. https://link.springer.com/book/10.1007/978-3-540-72703-3

KENNETH M, and BERTRAM R. An Introduction to the Fractional Calculus and Fractional Differential Equations. A Wiley-Interscience Publication, New York, 1993.

PODLUBNY I. Fractional Differential Equations. Mathematics in Science and Engineering. Technical University of Kosice, Slovak Republic, Fractional Differential Equations, 1999.

LI C, and ZENG F. Numerical methods for fractional calculus. Numerical Analysis and Scientific Computing. Chapman & Hall, 2015.

LI C, and CAI M. Theory and Numerical Approximations of Fractional Integrals and Derivatives. Society for Industrial and Applied Mathematics, Philadelphia, 2019.

LI C, QIAN D, and CHEN Y. On Riemann-Liouville and Caputo derivatives. Discrete Dynamics in Nature and Society, 2011, Article ID 562494, 2011. https://doi.org/10.1155/2011/562494

DIETHELM K, and FORD N J. Analysis of fractional differential equations. Journal of Mathematical Analysis and Applications, 2002, 265(2): 229-248.

DAFTARDAR-GEJJI V, and BABAKHANI A.

Analysis of a system of fractional differential equations. Journal of Mathematical Analysis and Applications, 2004, 293(2): 511-522.

DAFTARDAR-GEJJI V, and JAFARI H. Analysis of a system of nonautonomous fractional differential equations involving Caputo derivatives. Journal of Mathematical Analysis and Applications, 2007, 328(2): 1026-1033.

MOMANI S, and HADID S. Lyapunov stability solutions of fractional integrodifferential equations. International Journal of Mathematics and Mathematical Sciences, 2004, (47): 2503-2507.

LONGGE Z, JUNMIN L. and GUO-PEI C. Extension

of Lyapunov second method by fractional calculus. Pure and Applied Mathematics, 2005, 21: 291-294.

TARASOV V E. Fractional Stability. 2011. Retrieved from http://arxiv.org/abs/0711.2117.

HASSAN K. Nonlinear Systems. Third Edition, Prentice Hall, New Jersey, 2002.

VIANA M, and ESPINAR J M. Differential Equations: A Dynamical Systems Approach to Theory and Practice. American Mathematical Society, 2021.

NAIFAR O, MAKHLOUF A B, and HAMMAMI M A.

Comments on “Mittag-Leffler stability of fractional order nonlinear dynamic systems”. Automatica, 2017, 45(8): 1965-

WU C. Comments on “Stability analysis of Caputo fractional-order nonlinear systems revisited”. Nonlinear Dynamics, 2021, 104: 551-555.

DENG W. Smoothness and stability of the solutions for nonlinear fractional differential equations, Nonlinear Analysis, Theory, Methods and Applications, 2010, 72(3–4): 1768-1777.

LAKSHMIKANTHAM V, LEELA S, and

VASUNDHARA D J S. Theory of Fractional Dynamic Systems. Cambridge Scientific Publishers, Cambridge UK, 2009.

LAKSHMIKANTHAM V, LEELA S, and

SAMBANDHAM, M. Lyapunov theory for fractional differential equations. Communications in Applied Analysis, 2008.

ZHANG F, LI C, and CHEN Y Q. Asymptotical stability of nonlinear fractional differential system with Caputo derivative. International Journal of Differential Equations, 2011, Article ID 635165, 2011. https://doi.org/10.1155/2011/635165.

WANG G, PEI K, and CHEN Y Q. Stability analysis of nonlinear Hadamard fractional differential system. Journal of the Franklin Institute, 2019, 356(12): 6538-6546.

REN J, and ZHAI C. Stability analysis for generalized fractional differential systems and applications. Chaos, Solitons and Fractals, 2020, 139: 110009. https://doi.org/10.1016/j.chaos.2020.110009

ZHOU X F, HU L G, LIU S, and JIANG W. Stability

criterion for a class of nonlinear fractional differential systems. Applied Mathematics Letters, 2014, 28: 25-29.

DADRAS S, MALEK H, and CHEN, Y. Q. A note on

the lyapunov stability of fractional order nonlinear systems. Proceedings of the ASME Design Engineering Technical Conference, American Society of Mechanical Engineers (ASME), 9, 2017.

WANG Z, YANG D, MA T, and SUN N. Stability

analysis for nonlinear fractional order systems based on comparison principle. Nonlinear Dynamics, 2014, 75(1-2):387-402.

AGARWAL R, O’REGAN D, & HRISTOVA S.

Stability of Caputo fractional differential equations by Lyapunov functions. Applied Mathematics, 2015, 60: 653–

https://doi.org/10.1007/s10492-015-0116-4.

AGARWAL R, HRISTOVA S, and O’REGAN D.

Lyapunov functions and strict stability of Caputo fractional differential equations. Advances in Difference Equations, 2015, 2015(1): 346.

AGARWAL R, HRISTOVA S, and O’REGAN D.

Practical Stability of Caputo fractional differential equations by Lyapunov functions. Differential Equations & Applications, 2016, 8(1): 53-68.

AGARWAL R, O’REGAN D, & HRISTOVA S. Strict

stability with respect to initial time difference for Caputo fractional differential equations by Lyapunov functions. Georgian Mathematical Journal, 2017, 24(1): 1-13. https://doi.org/10.1515/gmj-2016-0080

AGARWAL R, HRISTOVA S, and O’REGAN D. Some

stability properties related to initial time difference for Caputo fractional differential equations. Fractional Calculus and Applied Analysis, 2018, 21(1): 72-93.

AGARWAL R, HRISTOVA S, and O’REGAN D.

Applications of Lyapunov Functions to Caputo Fractional Differential Equations. Mathematics, 2018, 6(11): 229.

HUANG S, and WANG B. Stability and stabilization of a class of fractional order nonlinear systems for . Nonlinear Dynamics, 2017, 88(2): 973-984.

LENKA B K, and BANERJEE S. Sufficient conditions for asymptotic stability and stabilization of autonomous fractional order systems. Communications in Nonlinear Science and Numerical Simulation, 2018, 56: 365-379.

ALIDOUSTI J, KHOSHSIAR G R, and BAYATI E A.

Stability analysis of nonlinear fractional differential order systems with Caputo and Riemann-Liouville derivatives. Turkish Journal of Mathematics, 2017, 41(5): 1260-1278.

WANG G, QIN J, DONG H, and GUAN T. Generalized Mittag-Leffler stability of Hilfer fractional order nonlinear dynamic system. Mathematics, 2019, 7(6): 500; https://doi.org/10.3390/math7060500

AGUILA-CAMACHO N, DUARTE-MERMOUD M A,

and GALLEGOS J. A. Lyapunov functions for fractional order systems. Communications in Nonlinear Science and Numerical Simulation, 2014, 19(9): 2951-2957.

TRIGEASSOU J C, MAAMRI N, SABATIER J, and

OUSTALOUP A. A Lyapunov approach to the stability of fractional differential equations. Signal Processing, 2011, 91(3): 437-445.

GALLEGOS J A, AGUILA-CAMACHO N, and

DUARTE-MERMOUD M A. Using general quadratic Lyapunov functions to prove Lyapunov uniform stability for fractional order systems. Communications in Nonlinear Science and Numerical Simulation, 2015, 22(1-3): 650-659.

GALLEGOS J A, and DUARTE-MERMOUD M A.

Attractiveness and stability for Riemann–Liouville fractional systems. Electronic Journal of Qualitative Theory of Differential Equations, 2018, 73: 1-16.

GALLEGOS J A, and DUARTE-MERMOUD M A.

Converse theorems in Lyapunov’s second method and applications for fractional order systems. Turkish Journal of Mathematics, 2019, 43(3): 1626-1639.