Home On the behaviour solutions of fractional and partial integro differential heat equations and its numerical solutions
Article
Licensed
Unlicensed Requires Authentication

On the behaviour solutions of fractional and partial integro differential heat equations and its numerical solutions

  • Gamal A. Mosa , Mohamed A. Abdou , Fatma A. Gawish EMAIL logo and Mostafa H. Abdalla
Published/Copyright: March 28, 2022
Become an author with De Gruyter Brill
Author Information Explore this Subject
Mathematica Slovaca
From the journal Mathematica Slovaca Volume 72 Issue 2

Abstract

In this paper, the semi-group method is used to discuss the existence and uniqueness of solutions for fractional and partial integro differential equations (F-PIDEs) of heat type in Banach space E. In addition, the stability of the solutions for F-PIDEs are discussed. Moreover, the Adomian decomposition method (ADM) is used to obtain the solutions numerically. Finally, numerical results of each case are obtained, and the difference of results between the fractional partial integro differential equation and partial integro differential equation are explained. Furthermore, the error is computed in each case.

MSC 2010: Primary 35K05; 65M99; 35R09
Keywords: Fractional and partial integro differential equations; heat equation; Caputo derivative; Riemman integral; semi-group; Adomian decomposition method

This work was supported by Benha University.

Acknowledgement

The authors would like to express their sincere gratitude to the anonymous referee for carefully reading the original manuscript and valuable comments that helped to accentuate important details and improve presentation of results.

  1. (Communicated by Alberto Lastra )

References

[1] Abdou, M. A.—El-Kojak, M. K.—Raad, S. A.: Analytic and numeric solution of linear partial differential equation of fractional order, Global Journal of Science Frontier Research: Mathematics and Decision Sciences 13(3/10) (2013), 57–71.Search in Google Scholar

[2] Abdou, M. A.—Raad, S. A.: Nonlocal solution of a nonlinear partial differential equation and its equivalent of nonlinear integral equation, J. Comput. Theor. Nanosci. 13(7) (2016), 4580–4587.10.1166/jctn.2016.5323Search in Google Scholar

[3] Arqub, O. A.: Numerical solutions for the robin time-fractional partial differential equations of heat and fluid flows based on the reproducing kernel algorithm, Int. J. Numer. Methods Heat Fluid Flow 28(4) (2018), 828–856.10.1108/HFF-07-2016-0278Search in Google Scholar

[4] Atangana, A.—Baleanu, D.: New fractional derivatives with nonlocal and non-singular kernel: Theory and application to heat transfer model, https://arxiv.org/abs/1602.03408.Search in Google Scholar

[5] AVCI, D.—Yavuz, M.—Özdemir, D.: Fundamental solutions to the Cauchy and Dirichlet problems for a heat conduction equation equipped with the Caputo-Fabrizio differentiation. In: Heat conduction: Methods, Applications and Research, Nova Science Publishers, 2019, pp. 95–107.Search in Google Scholar

[6] Baleanu, D.—Jajarmi, A.—Bonyah, E.—Hajipour, M.: New aspects of poor nutrition in the life cycle within the fractional calculus, Adv. Difference Equ. 2018(1) (2018), 1–14.10.1186/s13662-018-1684-xSearch in Google Scholar

[7] Burton, T. A.: Volterra Integral and Differential Equations, Elsevier, 2005.Search in Google Scholar

[8] Debnath, L.—Bhatta, D.: Solutions to few linear fractional inhomogeneous partial differential equations in fluid mechanics, Fract. Calc. Appl. Anal. 7(1) (2004), 21–36.Search in Google Scholar

[9] Ducrot, A.—Magal, P.—Prevost K.: Integrated semigroups and parabolic equations. Part I: linear perburbation of almost sectorial operators, J. Evol. Equ. 10(2) (2010), 263–291.10.1007/s00028-009-0049-zSearch in Google Scholar

[10] El-Borai, M. M.: Some probability densities and fundamental solutions of fractional evolution equations, Chaos Solitons Fractals 14(3) (2002), 433–440.10.1016/S0960-0779(01)00208-9Search in Google Scholar

[11] Elbeleze, A. A.—Kiliçman, A.—Taib, B. M.: Fractional variational iteration method and its application to fractional partial differential equation, Math. Probl. Eng. 2013 (2013), Art. ID 543848.10.1155/2013/543848Search in Google Scholar

[12] Gepreel, K. A.: Adomian decomposition method to find the approximate solutions for the fractional PDEs, WSEAS Transactions on Mathematics 11(7) (2012), 652–659.Search in Google Scholar

[13] Gupta, A. K.—Ray, S. S.: Numerical treatment for the solution of fractional fifth-order Sawada–Kotera equation using second kind Chebyshev wavelet method, Appl. Math. Model. 39(17) (2015), 5121–5130.10.1016/j.apm.2015.04.003Search in Google Scholar

[14] Khader, M. M.—Solouma, E. M.: Introducing FDM combined with Hermite formula for solving numerically the linear fractional Klein-Gordon equation, J. Comput. Theor. Nanosci. 12(11) (2015), 4579–4583.10.1166/jctn.2015.4403Search in Google Scholar

[15] Linz, P.: Analytical and Numerical Methods for Volterra Equations, Siam Studies in Applied and Numerical Mathematics, 1985.10.1137/1.9781611970852Search in Google Scholar

[16] Mackey, M. C.—Rudnicki, R.: Global stability in a delayed partial differential equation describing cellular replication, J. Math. Biol. 33(1) (1994), 89–109.10.1007/BF00160175Search in Google Scholar PubMed

[17] Marin, M.—Nicaise, S.: Existence and stability results for thermoelastic dipolar bodies with double porosity, Contin. Mech. Thermodyn. 28(6) (2016), 1645–1657.10.1007/s00161-016-0503-4Search in Google Scholar

[18] Mittal, R. C.—Nigam, R.: Solution of fractional integro-differential equations by Adomian decomposition method, Int. J. Appl. Math. Mech. 4(2) (2008), 87–94.Search in Google Scholar

[19] Nowakowski, J.—Ostalczyk, P.—Sankowski, D.: Application of fractional calculus for modelling of two-phase gas/liquid flow system, Informatyka, Automatyka, Pomiary w Gospodarce i Ochronie Środowiska 7(1) (2017), 42–45.10.5604/01.3001.0010.4580Search in Google Scholar

[20] Rudnicki, R. Markov operators: applications to diffusion processes and population dynamics, Appl. Math. (Warsaw) 27 (2000), 67–79.10.4064/am-27-1-67-79Search in Google Scholar

[21] Shi, X.—Huang, L.—Zeng, Y.: Fast Adomian decomposition method for the Cauchy problem of the time-fractional reaction diffusion equation, Adv. Mech. Eng. 8(2) (2016), https://doi.org/10.1177/1687814016629898.Search in Google Scholar

[22] Singh, H.—Singh, C.: Stable numerical solutions of fractional partial differential equations using legendre scaling functions operational matrix, Ain Shams Engineering Journal 9(4) (2018), 717–725.10.1016/j.asej.2016.03.013Search in Google Scholar

[23] Su, X.—Zhang, S.: Solutions to boundary-value problems for nonlinear differential equations of fractional order, Electron. J. Differential Equations 26 (2009), 1–15.10.1155/2009/978605Search in Google Scholar

[24] Vanani, S.—Aminataei, A.: On the numerical solution of fractional partial differential equations, Math. Comput. Appl. 17(2) (2012), 140–151.10.3390/mca17020140Search in Google Scholar

[25] YOSIDA, K.: An operator-theoretical treatment of temporally homogeneous Markoff process, J. Math. Soc. Japan 1(3) (1949), 244–253.10.2969/jmsj/00130244Search in Google Scholar

[26] Yu, Q.—Liu, F.—Anh, V.—Turner, I.: Solving linear and non-linear space-time fractional reaction-diffusion equations by the Adomian decomposition method, Int. J. Numer. Methods Eng. 74(1) (2008), 138–158.10.1002/nme.2165Search in Google Scholar

[27] Zayed, E. M.—Nofal, T. A.—Gepreel, K. A.: Homotopy perturbation and Adomian decomposition methods for solving nonlinear Boussinesq equations, Comm. Appl. Nonlinear Anal. 15(3) (2008), 57.Search in Google Scholar

[28] Zhang, X.—Chen, P.—Ahmed, A.—Li, Y.: Mild solution of stochastic partial differential equation with nonlocal conditions and noncompact semigroups, Math. Slovaca 69(1) (2019), 111–124.10.1515/ms-2017-0207Search in Google Scholar

[29] Zheng, B.: Exp-function method for solving fractional partial differential equations, The Scientific World Journal 2013 (2013), Art. ID 465723.10.1155/2013/465723Search in Google Scholar PubMed PubMed Central

Received: 2020-05-29
Accepted: 2021-05-08
Published Online: 2022-03-28
Published in Print: 2022-04-26

© 2022 Mathematical Institute Slovak Academy of Sciences

Articles in the same Issue

  1. Regular Papers
  2. Logical and algebraic properties of generalized orthomodular posets
  3. Integral prefilters and integral Eq-algebras
  4. Modules with fusion and implication based over distributive lattices: Representation and duality
  5. Localization of k × j-rough Heyting algebras
  6. Meet infinite distributivity for congruence lattices of direct sums of algebras
  7. Some exponential diophantine equations II: The equation x2Dy2 = kz for even k
  8. On extensions of the Open Door Lemma
  9. Nevanlinna theory for holomophic curves from annuli into semi-Abelian varieties
  10. Stability and feedback stabilizability of delay periodic differential equations with pairwise permutable matrix functions
  11. On the behaviour solutions of fractional and partial integro differential heat equations and its numerical solutions
  12. Oscillatory and asymptotic behavior of solutions of third-order quasi-linear neutral difference equations
  13. Some properties of Kantorovich variant of Chlodowsky-Szász operators induced by Boas-Buck type polynomials
  14. A Study on statistical versions of convergence of sequences of functions
  15. Fuzzy fixed point theorems and Ulam-Hyers stability of fuzzy set-valued maps
  16. Notes on affine Killing and two-Killing vector fields
  17. Prediction of the exponential fractional upper record-values
  18. On concomitants of generalized order statistics from generalized FGM family under a general setting
  19. One-parameter generalization of dual-hyperbolic Pell numbers
https://doi.org/10.1515/ms-2022-0027
Keywords for this article
Fractional and partial integro differential equations; heat equation; Caputo derivative; Riemman integral; semi-group; Adomian decomposition method

Articles in the same Issue

  1. Regular Papers
  2. Logical and algebraic properties of generalized orthomodular posets
  3. Integral prefilters and integral Eq-algebras
  4. Modules with fusion and implication based over distributive lattices: Representation and duality
  5. Localization of k × j-rough Heyting algebras
  6. Meet infinite distributivity for congruence lattices of direct sums of algebras
  7. Some exponential diophantine equations II: The equation x2Dy2 = kz for even k
  8. On extensions of the Open Door Lemma
  9. Nevanlinna theory for holomophic curves from annuli into semi-Abelian varieties
  10. Stability and feedback stabilizability of delay periodic differential equations with pairwise permutable matrix functions
  11. On the behaviour solutions of fractional and partial integro differential heat equations and its numerical solutions
  12. Oscillatory and asymptotic behavior of solutions of third-order quasi-linear neutral difference equations
  13. Some properties of Kantorovich variant of Chlodowsky-Szász operators induced by Boas-Buck type polynomials
  14. A Study on statistical versions of convergence of sequences of functions
  15. Fuzzy fixed point theorems and Ulam-Hyers stability of fuzzy set-valued maps
  16. Notes on affine Killing and two-Killing vector fields
  17. Prediction of the exponential fractional upper record-values
  18. On concomitants of generalized order statistics from generalized FGM family under a general setting
  19. One-parameter generalization of dual-hyperbolic Pell numbers
Sign up now to receive a 20% welcome discount
Institutional Access
How does access work?
Have an idea on how to improve our website?
Please write us.
© 2025 De Gruyter Brill
Downloaded on 21.9.2025 from https://www.degruyterbrill.com/document/doi/10.1515/ms-2022-0027/html
Scroll to top button