Stability of nonlinear impulsive higher order differential – fractional integral delay equations with nonlocal initial conditions

Authors

  • Ahmed Adnan Hashem Aljumaili Ministry of Higher Education and Scientific Research image/svg+xml , Ministry of Higher Education and Scientific Research image/svg+xml , Ministry of Higher Education and Scientific Research image/svg+xml , Ministry of Higher Education and Scientific Research image/svg+xml , Ministry of Higher Education and Scientific Research image/svg+xml , Ministry of Higher Education And Scientific Research image/svg+xml , Ministry of Higher Education and Scientific Research image/svg+xml
  • Sameer Qasim Hasan Alasadi Mustansiriyah university. College of Education. Mathematics Department

DOI:

https://doi.org/10.31185/wjps.261

Keywords:

stability, impulsive, higher order, delay time, nonlocal initial conditions.

Abstract

The aim of this paper is to investigate some types of stability such as generalized Hyers-Ulam- Rassias stability(G-H-U-R-stabile) and the relation with Hyers-Ulam(H-U-stabile) stable and Hyers-Ulam-Rassias stable (H-U-R-stabile) and generalized Hyers-Ulam stable (G-H-U- stable) to obtain which one guarantee to satisfy stability of equations included a nonlinear function some of them contains a delay time of solution and the other contain a vector of different order of  derivatives for the  solution to n-time  and vector of fractional order of integrals with different fractional orders and that was the for using a claculse of fractional calculus to satisfies the issue of this techniques. Moreover, the nonlocal initial   values for the proposal equation of nonlinear impulsive higher order differential – fractional integral delay time equations which are adding more interesting for nonlinear analytic object of nonlinear higher order integro – fractional order impulsive classes, and the impulsive difference of the equation has some necessary conditions to prove the results of solution to be stable with certain type has related with other types. The necessary and sufficient conditions which assumed on this nonlinear higher order integro-differential impulsive equation have been achieved the stability with interesting certain estimates obtain through the proving technique. Also the uniqueness of solution has been studied with same conditions was presented for stability and used for that issue a contraction fixed point theorem.

References

R. Agarwal, S. Hristova, D. O. Regan and P. Kopanov, P-Moment Mittag–Leffler Stability of Riemann–Liouville Fractional Differential Equations with Random Impulses, Mathematics MDPI, 2020.

R. Agarwal, S. Hristova, and D. O. Regan, Integral presentations of the solution of a boundary value problem for impulsive fractional integro-differential equations with Riemann-Liouville derivatives, AIMS Mathematics, 2021, 7(2): 2973–2988.

R. Agarwal, S. Hristova.D. and O. Regan, Stability Concepts of Riemann-Liouville Fractional-Order Delay Nonlinear Systems, Mathematics MDPI, 2021, 9(4), 435.

M. U. Akhmetov, A. Zafer, Stability of the zero solution of impulsive differential equations by the Lyapunov second method, Journal of mathematical analysis and applications, 248, 69-82 (2000).

A. Al-OmariID, and H, Al-SaadiID, Impulsive fractional order integrodifferential equation via fractional operators, PLoS ONE, 2023, 18(3): e0282665.

D. Baleanu, R. Kasinathan, R. Kasinathan, and V. Sandrasekaran, Existence, uniqueness and Hyers-Ulam stability of random impulsive stochastic integro-differential equations with nonlocal conditions, AIMS Mathematics, 2022, 8(2): 2556–2575.

D. Chalishajar, C. Ravichandran, S. Dhanalakshmi, and R. Murugesu, Existence of Fractional Impulsive Functional Integro-Differential Equations in Banach Spaces, Applied System Innovation MDPI, 2019.

Q. Chen, A. Debbouche, Z. Luo and Wang, Impulsive fractional differential equations with Riemann–Liouville derivative and iterative learning control, Chaos, Solitons & Fractals 2017, V. 102, P. 111-118.

X. Fu, Q. Zhu, Stability of nonlinear impulsive Stochastic systems with Markovian switching under generalized average dwell time condition, science china, 2018, vol.61.

K. Kaliraj, P. Lakshmi Priya, and J. Nieto, Finite-Interval Stability Analysis of Impulsive Fractional-Delay Dynamical System, fractal Fractional MDPI, 2023, 7, 447.

M. Lazarevic, Stability and stabilization of fractional order time delay systems, Scientific technical review, 2011, vol. 61, no.1

X. Li, J. Wu, Stability of nonlinear differential system with state-dependent delayed impulsive, Autonatica, 64 (2016) 63-69.

X. Liu, Stability of impulsive control system with time delay, Mathematical and computer modelling39 (2004), 511-519.

X. Liu, Y. Liu. K. L. Teo, Stability analysis of impulsive control, Mathematical and computer modelling 37 (2003), 1357-1370.

M. Obloza, Hyers stability of the linear differential equation, Rocznik Nauk.-Dydakt. Prace Mat., (1993), 259–270. 1

M. Obloza, Connections between Hyers and Lyapunov stability of the ordinary differential equations, Rocznik Nauk.-Dydakt. Prace Mat., 14 (1997), 141–146. 1

D. Raghavan, S. Nagarjan, and C. Zhai, Generalized Mittag-Leffler stability of hilfer fractional impulsive differential systems, math.oc , 2022.

L. Wang, B. Yang, A. Abraham, Distilling middle-age cement hydration kinetics from observed data using phased hybrid evolution, Soft Comput., 20 (2016), 3637–3656. 1

L. Wang, B. Yang, J. Orchard, Particle swarm optimization using dynamic tournament topology, Appl. Soft Comput.,48 (2016), 584–596.1

J. Wang, A. Zada and W. Ali, Ulam’s-Type Stability of First-Order Impulsive Differential Equations with Variable Delay in Quasi–Banach Spaces, International Journal of Nonlinear Sciences and Numerical Simulation, De Gruyter 2018, V (19) Issue ( 5) .

J. R. Wang, M. Feckan, Y. Zhou, On the stability of first order impulsive evolution equations, Opuscula Math., 34 (2014), 639–657. 1

T. Yuldashev, T. Ergashev and T. Abduvahobov, Nonlinear system of impulsive integro-differential equations with Hilfer fractional operator and mixed maxima, Chelyabinsk Physical and Mathematical Journal. 2022. Vol. 7, iss. 3. P. 312–325

A. Zada, J. Alzabut, H. Waheed, and I. Popa, Ulam–Hyers stability of impulsive integrodifferential equations with Riemann–Liouville boundary conditions, Advances in Difference Equations a springer Open Journal (2020) 2020:64

A. Zada, S. Faisal, Y. Li, On the Hyers–Ulam stability of first-order impulsive delay differential equations, J. Funct. Spaces, 2016 (2016), 6 pages. 1

A. Zada and S. Omar Shah, HyersUlam stability of rst-order non-linear delay dierential equations with fractional integrable impulses, Hacettepe Journal of Mathematics and Statistics 2018, V. 47 (5), 1196 – 1205.

A. Zada, O. Shah, R. Shah, Hyers–Ulam stability of non-autonomous systems in terms of boundedness of Cauchy problems, Appl. Math. Comput., 271 (2015), 512–518.

K. Zhaoa, Existence and UH-stability of integral boundary problem for a class of nonlinear higher-order Hadamard fractional Langevin equation via Mittag-Leffler functions, Faculty of Sciences and Mathematics, University of Nis, Serbia (2023), 37:4,1053–1063.

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Published

2023-12-30

Issue

Vol. 2 No. 4 (2023)

Section

Mathematics

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Copyright (c) 2023 Ahmed Adnan Hashem Aljumaili, Sameer Qasim Hasan Alasadi

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This work is licensed under a Creative Commons Attribution 4.0 International License.

How to Cite

Aljumaili, A. A. H., & Alasadi, S. Q. H. (2023). Stability of nonlinear impulsive higher order differential – fractional integral delay equations with nonlocal initial conditions. Wasit Journal for Pure Sciences , 2(4), 26-36. https://doi.org/10.31185/wjps.261