The Analitical Solution of Linear and Non-Linear Differential- Algebraic Equations (DAEs) with Laplace-Padé Series Method
Year 2024,
, 129 - 134, 21.06.2024
Nooriza Myrzabekova
,
Ercan Celık
Abstract
In this paper, we apply Laplace-Padé Series method to solve linear and non-linear differentialalgebraic
equations (DAEs). Firstly, The basic properties of the Laplace-Padé Series method are
given. Secondly, we calculate the arbitrary order power series of differential-algebraic equations
(DAEs), then convert it to the series form Laplace-Padé. Then, the three differential-algebraic
equations (DAEs) are solved by Laplace-Padé Series method. It was seen that the method gave
effective and fast results. Therefore, the method can be easily applied to linear and non-linear
differential-algebraic equations (DAEs) problems in different fields.
Project Number
The authors have been supported by the Kyrgyz-Turkish Manas University BAP Coordination Unit with Project number KTMU-BAP-2023.FB.02.
References
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Algebraic Equations, Elsevier, New York, 1989.
- [2]. E. Hairer, S.P. Norsett and G. Wanner, Solving Ordinary Differential Equations II. Stiff and Differential-
Algebraic Problems, Springer, New York, 1992.
- [3]. L.R. Petzold, Numerical solution of differential-algebraic equations, Adv. Numer. Anal. 4 (1995).
- [4]. U.M. Ascher, On symmetric schemes and differential-algebraic equations, SIAM J. Sci. Stat. Comput. 10,
937–949, 1989.
- [5]. C.W. Gear and L.R. Petzold, ODE systems for the solution of differential-algebraic systems, SIAM J. Numer.
Anal. 21, 716–728, 1984.
- [6]. U.M. Ascher and L.R. Petzold, Projected implicit Runge–Kutta methods for differential-algebraic equations,
SIAM J. Numer. Anal. 28, 1097–1120, 1991.
- [7]. E. Çelik and M. Bayram, On the numerical solution of differential-algebraic equation by Pade´ series, Appl. Math. Comput. 137, 151–160, 2003.
- [8]. E. Çelik and M. Bayram, The numerical solution of physical problems modeled as a systems of differential-algebraic equations(DAEs), Journal of Franklin Institute, 342, 1-6, 2005.
- [9]. U.M. Ascher and P. Lin, Sequential regularization methods for higher index differential-algebraic
equations with constant singularities: the linear index-2 case, SIAM J. Numer. Anal. 33, 1921–1940, 1996.
- [10]. U.M. Ascher and P. Lin, Sequential regularization methods for non-linear higher index differential-algebraic equations, SIAM J. Sci. Comput. 18, 160–181, 1997.
- [11]. S.L. Campbell, A computational method for general higher index singular systems of differential equations, IMACS Trans. Sci. Comput. 89, 555–560, 1989.
- [12]. S.L. Campbell, E. Moore and Y. Zhong, Utilization of automatic differentiation in control algorithms, IEEE
Transactions on Automatic Control, 39 (5), 1047 – 1052,1994.
- [13]. S. K. Vanani and A. Aminataei, “Numerical solution of differential algebraic equations using a multiquadric approximation scheme,” Mathematical and Computer Modelling, 53 (5-6), 659 – 666, 2011.
- [14]. Y. Khan and N. Faraz, Application of modified laplace decomposition method for solving boundary layer equation, Journal of King Saud University - Science, 23 (1), 115 – 119, 2011.
- [15]. H.Vazquez-Leal, Exact solutions for Differential-Algebraic Equations, Miskolc Mathematical Notes, 15 (1), 227-238, 2014.
- [16]. H. Singh and A. Wazwaz, Computational Method for Reaction Diffusion-Model Arising in a Spherical Catalyst, International Journal of Applied and Computational Mathematics, 7 (3), 65, 2021.
- [17]. H. Singh, Analysis for fractional dynamics of Ebola virus model, Chaos solitons & fractals, 138, 109992, 2020.
- [18]. H. Singh, Analysis of drug treatment of the fractional HIV infection model of CD4+ T-cells, Chaos Solitons & Fractals, 146, 110868, 2021.
- [19]. H. Singh, Jacobi collocation method for the fractional advection‐dispersion equation arising in porous media, Numerical methods for partial differential equations, 2020.
- [20]. H. Singh, H.M. Srivastava and D. Kumar, A reliable numerical algorithm for the fractional vibration equation, Chaos, Solitons and Fractals, vol. 103, 131-138, 2017.
- [21]. H. Singh, Chebyshev spectral method for solving a class of local and nonlocal elliptic boundary value problems, International Journal of Nonlinear Sciences and Numerical Simulation, 24(3), 899-915, 2021
Year 2024,
, 129 - 134, 21.06.2024
Nooriza Myrzabekova
,
Ercan Celık
Project Number
The authors have been supported by the Kyrgyz-Turkish Manas University BAP Coordination Unit with Project number KTMU-BAP-2023.FB.02.
References
- [1]. K. E. Brenan, S.L. Campbell and L.R. Petzold, Numerical Solution of Initial Value Problems in Differential
Algebraic Equations, Elsevier, New York, 1989.
- [2]. E. Hairer, S.P. Norsett and G. Wanner, Solving Ordinary Differential Equations II. Stiff and Differential-
Algebraic Problems, Springer, New York, 1992.
- [3]. L.R. Petzold, Numerical solution of differential-algebraic equations, Adv. Numer. Anal. 4 (1995).
- [4]. U.M. Ascher, On symmetric schemes and differential-algebraic equations, SIAM J. Sci. Stat. Comput. 10,
937–949, 1989.
- [5]. C.W. Gear and L.R. Petzold, ODE systems for the solution of differential-algebraic systems, SIAM J. Numer.
Anal. 21, 716–728, 1984.
- [6]. U.M. Ascher and L.R. Petzold, Projected implicit Runge–Kutta methods for differential-algebraic equations,
SIAM J. Numer. Anal. 28, 1097–1120, 1991.
- [7]. E. Çelik and M. Bayram, On the numerical solution of differential-algebraic equation by Pade´ series, Appl. Math. Comput. 137, 151–160, 2003.
- [8]. E. Çelik and M. Bayram, The numerical solution of physical problems modeled as a systems of differential-algebraic equations(DAEs), Journal of Franklin Institute, 342, 1-6, 2005.
- [9]. U.M. Ascher and P. Lin, Sequential regularization methods for higher index differential-algebraic
equations with constant singularities: the linear index-2 case, SIAM J. Numer. Anal. 33, 1921–1940, 1996.
- [10]. U.M. Ascher and P. Lin, Sequential regularization methods for non-linear higher index differential-algebraic equations, SIAM J. Sci. Comput. 18, 160–181, 1997.
- [11]. S.L. Campbell, A computational method for general higher index singular systems of differential equations, IMACS Trans. Sci. Comput. 89, 555–560, 1989.
- [12]. S.L. Campbell, E. Moore and Y. Zhong, Utilization of automatic differentiation in control algorithms, IEEE
Transactions on Automatic Control, 39 (5), 1047 – 1052,1994.
- [13]. S. K. Vanani and A. Aminataei, “Numerical solution of differential algebraic equations using a multiquadric approximation scheme,” Mathematical and Computer Modelling, 53 (5-6), 659 – 666, 2011.
- [14]. Y. Khan and N. Faraz, Application of modified laplace decomposition method for solving boundary layer equation, Journal of King Saud University - Science, 23 (1), 115 – 119, 2011.
- [15]. H.Vazquez-Leal, Exact solutions for Differential-Algebraic Equations, Miskolc Mathematical Notes, 15 (1), 227-238, 2014.
- [16]. H. Singh and A. Wazwaz, Computational Method for Reaction Diffusion-Model Arising in a Spherical Catalyst, International Journal of Applied and Computational Mathematics, 7 (3), 65, 2021.
- [17]. H. Singh, Analysis for fractional dynamics of Ebola virus model, Chaos solitons & fractals, 138, 109992, 2020.
- [18]. H. Singh, Analysis of drug treatment of the fractional HIV infection model of CD4+ T-cells, Chaos Solitons & Fractals, 146, 110868, 2021.
- [19]. H. Singh, Jacobi collocation method for the fractional advection‐dispersion equation arising in porous media, Numerical methods for partial differential equations, 2020.
- [20]. H. Singh, H.M. Srivastava and D. Kumar, A reliable numerical algorithm for the fractional vibration equation, Chaos, Solitons and Fractals, vol. 103, 131-138, 2017.
- [21]. H. Singh, Chebyshev spectral method for solving a class of local and nonlocal elliptic boundary value problems, International Journal of Nonlinear Sciences and Numerical Simulation, 24(3), 899-915, 2021