Abstract
Analytical studies of fuzzy fractional differential equations (FFDEs) of two different independent fractional orders are often complex and difficult. It is essential to develop comprehensive schemes for the solutions of FFDEs with independent orders. This article introduces and investigates the fully closed-form analytical solutions of FFDEs involving two different independent fractional orders under the strongly generalized Hukuhara differentiability (SGHD). Based on the concept of SGHD, we extract two possible solutions of FFDEs in terms of the Mittag-Leffler function. Potential solutions for homogeneous and inhomogeneous FFDEs are obtained using the definition of the fuzzy Laplace transform technique. Some interesting properties and results for the FFDEs are introduced using the concepts of SGHD. We illustrate some examples as applications to explain the effectiveness of our proposed results. FFDE has a variety of applications in science and engineering. To enhance the functional significance of this work, we solve the RLC circuit using the proposed technique in a fuzzy setting to analyze and interpret the theoretical results.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Data availability
No data were used to support this study.
References
Agarwal RP, Lakshmikantham V, Nieto JJ (2010) On the concept of solution for fractional differential equations with uncertainty. Nonlinear Anal Theory Methods Appl 72(6):2859–2862
Ahmad MZ, Hassan MK, Abbasbanday S (2013) Solving fuzzy fractional differential equations using Zadeh’s extension principle. Sci World J 2013:1–11
Ahmad A, Nieto JJ (2010) Solvability of nonlinear Langevin equation involving two fractional orders with Dirichlet boundary conditions. Int J Differ Equ 1649486
Ahmad B, Nieto JJ, Alsaedi A, El-Shahed M (2012) A study of nonlinear Langevin equation involving two fractional orders in different intervals. Nonlinear Anal Real World Appl 13:599–606
Ahmad S, Ullah A, Ullah A, Akgül A, Abdeljawad T (2021) Computational analysis of fuzzy fractional order non-dimensional Fisher equation. Phys Scr 96(8):084004
Ahmadova A, Huseynov IT, Fernandez A, Mahmudov NI (2021) Trivariate Mittag-Leffler functions used to solve multi-order systems of fractional differential equations. Commun Nonlinear Sci Numer Simul 97:105735
Akram M, Allahviranloo T, Pedrycz W, Ali M (2021) Methods for solving \(LR\)-bipolar fuzzy linear systems. Soft Comput 25:85–108
Akram M, Ihsan T, Allahviranloo T (2022) Solving Pythagorean fuzzy fractional differential equations using Laplace transform. Granul Comput. https://doi.org/10.1007/s41066-022-00344-z
Akram M, Ihsan T, Allahviranloo T, Al-Shamiri MMA (2022) Analysis on determining the solution of fourth-order fuzzy initial value problem with Laplace operator. Math Biosci Eng 19(12):11868–11902
Akram M, Ihsan T (2022) Solving Pythagorean fuzzy partial fractional diffusion model using the Laplace and Fourier transforms. Granul Comput. https://doi.org/10.1007/s41066-022-00349-8
Akram M, Muhammad G, Allahviranloo T, Ali G (2022) New analysis of fuzzy fractional Langevin differential equations in Caputo’s derivative sense. AIMS Math 7(10):18467–18496
Akram M, Muhammad G, Allahviranloo T, Ali G (2023) A solving method for two-dimensional homogeneous system of fuzzy fractional differential equations. AIMS Math 8(1):228–263
Allahviranloo T, Ahmadi MB (2010) Fuzzy laplace transforms. Soft Comput 14(3):235
Allahviranloo T, Armand A, Gouyandeh Z (2014) Fuzzy fractional differential equations under generalized fuzzy Caputo derivative. J Intell Fuzzy Syst 26(3):1481–1490
Allahviranloo T, Ghanbari B (2020) On the fuzzy fractional differential equation with interval Atangana-Baleanu fractional derivative approach. Chaos Solit Fractals 130:109397
Allahviranloo T, Salahshour S, Abbasbandy S (2012) Explicit solutions of fractional differential equations with uncertainty. Soft Comput 16(2):297–302
Baghani H, Nieto JJ (2019) On fractional Langevin equation involving two fractional orders in different intervals. Nonlinear Anal Model 24:884–897
Bede B, Gal SG (2005) Generalizations of the differentiability of fuzzy-number-valued functions with applications to fuzzy differential equations. Fuzzy Sets Syst 151(3):581–599
Blackwell B, Beck J (2010) A technique for uncertainty analysis for inverse heat conduction problems. Int J Heat Mass Transf 53(4):753–759
Chen A, Chen Y (2011) Existence of solutions to nonlinear Langevin equation involving two fractional orders with boundary value conditions. Bound Value Probl 3:1–17
Devi A, Jakhar M (2020) Analytic solution of fractional order differential equation arising in RLC electrical circuit. Malaya J Matematik 8(2):421–426
Diethelm K (2010) The analysis of fractional differential equations: an application-oriented exposition using differential operators of Caputo type. Series on complexity, nonlinearity and chaos. Springer, Heidelberg
Diethelm K, Ford NJ (2004) Multi-order fractional differential equations and their numerical solution. Appl Math Comput 154:621–640
Diethelm K, Ford NJ, Freed AD (2002) A predictor-corrector approach for the numerical solution of fractional differential equations. Nonlinear Dyn 29:3–22
Dong NP, Son NTK, Allahviranloo T, Tam HTT (2022) Finite-time stability of mild solution to time-delay fuzzy fractional differential systems under granular computing. Granul Comput. https://doi.org/10.1007/s41066-022-00325-2
Dubios D, Prade H (1982) Towards fuzzy differential calculus part 3: differentiation. Fuzzy Sets Syst 8(3):225–233
Ezadi S, Allahviranloo T (2020) Artificial neural network approach for solving fuzzy fractional order initial value problems under \(gH\)-differentiability. Math Methods Appl Sci
Friedman M, Ming M, Kandel A (1996) Fuzzy derivatives and fuzzy Cauchy problems using LP metric. Fuzzy Logic Found Ind Appl 8:57–72
Fazli H, Sun H, Nieto JJ (2020) Fractional Langevin equation involving two fractional orders: existence and uniqueness. Mathematics 8(5):743
Ghaffari M, Allahviranloo T, Abbasbandy S, Azhini M (2021) On the fuzzy solutions of time-fractional problems. IJFS 18(3):51–66
Goetschel R Jr, Voxman W (1986) Elementary fuzzy calculus. Fuzzy Sets Syst 18(1):31–43
Haq EU, Hassan QMU, Ahmad J, Ehsan K (2022) Fuzzy solution of system of fuzzy fractional problems using a reliable method. Alex Eng J 61(4):3051–3058
Hoa NV, Lupulescu V, O’Regan D (2017) Solving interval-valued fractional initial value problems under Caputo \(gH\)-fractional differentiability. Fuzzy Sets Syst 309:1–34
Khakrangin S, Allahviranloo T, Mikaeilvand N, Abbasbandy S (2021) Numerical solution of fuzzy fractional differential equation by Haar wavelet. Int J Appl Math 16(1):14
Kilbas AA, Srivastava HM, Trujillo JJ (2006) Theory and applications of fractional differential equations, 20th edn, vol 204. Elsevier Science, Amsterdam, pp 1–523
Magin RL (2006) Fractional calculus in bioengineering. Begell House Publisher Inc, Connecticut
Mahmudov NI (2020) Fractional Langevin type delay equations with two fractional derivatives. Appl Math Lett 106215
Melliani S, Arhrrabi E, Elomari MH, Chadli LS (2021) Ulam-Hyers-Rassias stability for fuzzy fractional integrodifferential equations under Caputo \(gH\)-differentiability. Int J Optim Appl 51
Miller KS, Ross B (1993) An introduction to the fractional calculus and differential equations. Wiley, New York
Ngo HV, Lupulescu V, O’Regan D (2018) A note on initial value problems for fractional fuzzy differential equations. Fuzzy Sets Syst 347:54–69
Podlubny I (1998) Fractional differential equations: an introduction to fractional derivatives, fractional differential equations, to methods of their solution and some of their applications. Elsevier, Amsterdam
Podlubny I (1999) Fractional differential equations. Academic Press, San Diego
Prabhakar TR (1971) A singular integral equation with a generalized Mittag-Leffler function in the kernel. Yokohama Math J
Puri ML, Ralescu DA (1983) Differentials of fuzzy functions. J Math Anal Appl 91(2):552–558
Rahaman M, Mondal SP, Alam S, Khan NA, Biswas A (2021) Interpretation of exact solution for fuzzy fractional non-homogeneous differential equation under the Riemann-Liouville sense and its application on the inventory management control problem. Granul Comput 6(4):953–976
Salahshour S, Allahviranloo T (2013) Applications of fuzzy Laplace transforms. Soft comput 17(1):145–158
Salahshour S, Allahviranloo T, Abbasbandy S (2012) Solving fuzzy fractional differential equations by fuzzy Laplace transforms. Commun Nonlinear Sci Numer Simul 17(3):1372–1381
Samko SG, Kilbas AA, Marichev OI (1993) Fractional integrals and derivatives: theory and applications. Gordon & Breach Science Publishers, Yverdon
Seikkala S (1987) On the fuzzy initial value problem. Fuzzy Sets Syst 24(3):319–330
Smadi MA, Arqub OA, Zeidan D (2021) Fuzzy fractional differential equations under the Mittag-Leffler kernel differential operator of the ABC approach: Theorems and applications. Chaos Solit Fractals 146:110891
Vu H, Hoa NV (2019) Uncertain fractional differential equations on a time scale under granular differentiability concept. Comput Appl Math 38(3):1–22
Wang C, Qiu Z, He Y (2015) Fuzzy interval perturbation method for uncertain heat conduction problem with interval and fuzzy parameters. Int J Numer Methods Eng 104(5):330–34
Wasques V, Laiate B, Pedro FS, Esmi E, Barros LCD (2020) Interactive fuzzy fractional differential equation: application on HIV dynamics. In: International conference on information processing and management of uncertainty in knowledge-based systems. Springer, Cham, pp 198–211
Yue Z, Guangyuan W (1998) Time domain methods for the solutions of \(N\)-order fuzzy differential equations. Fuzzy Sets Syst 94(1):77–92
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
The authors declare no conflicts of interest.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
About this article
Cite this article
Akram, M., Muhammad, G. Analysis of incommensurate multi-order fuzzy fractional differential equations under strongly generalized fuzzy Caputo’s differentiability. Granul. Comput. 8, 809–825 (2023). https://doi.org/10.1007/s41066-022-00353-y
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s41066-022-00353-y