I.H. Abdel-Halim, Application to differential transformation for solving systems of differential equations, Appl. Math. Modell., 32, 2008, 2552-9.
A. Aky¨uz, M. Sezer, Chebyshev polynomial solutions of systems of high-order linear differential equations with variable coefficients, Appl. Math. Comput., 144, 2003, 237-47.
M.I. Bhatti, P. Bracken, Solutions of differential equations in a Bernstein polynomial basis, J. Comput. Appl. Math., 205, 2007, 272-280.
J. Biazar, E. Babolian, R. Islam Solution of system of ordinary differential equations by Adomian decomposition method, Appl. Math. Comput., 147, 2004, 713-9.
˙I. C¸ elik, Collacation method and residual correction using Chebyshev series, Applied Mathematics and Computation 174, 2006, 910-920.
A. Davies, D. Crann, The solution of systems of differential equations using numerical Laplace transforms,Int. J. Math. Educ. Sci. Technol., 30, 1999, 65-79.
J. Diblik, B.Iricanin, S. Stevic, Z. Smarda, Note on the existence of periodic solutions of a class of systems of differential-difference equations, Applied Mathematics and Computation, 232 (2014), 922-928.
E. G¨okmen, M. Sezer, Taylor collacation method for systems of high-order linear differential-difference equations with variable coefficients, Ain Shams Engineering Jornal, 4, 2013, 117-125.
H. Jafari, V. Daftardar-Gejji, Revised Adomian decomposition method for solving systems of ordinary and fractional differential equations, Appl. Math. Comput., 181, 2006, 598-608.
F. Mohamed, I. Naeem, A. Qadir, Conditional linearizability criteria for a system of third-order ordinary differential equations, Nonlinear Anal:Real World Apll., 10, 2009, 3404-12.
A. Saadatmandi, M. Denghan, A. Eftekhari, Application of He’s homotopy perturbation method for nonlinear system of second orer boundary value problems, Nonlinear Anal:Real World Apll., 10, 2009, 1912-22.
M. Sezer, A. Karamete, M. G¨ulsu, Taylor polynomial solutions of systems of linear differential equations with variable coefficients, Int. J. Comput. Math., 82(6), 2005, 755-64.
S. Shahmorad, Numerical solution of general form linear Fredholm-Volterra integro differential equations by the tau method with an error estimation, Applied Mathematics and Computation 167, 2005, 1418-1429.
S. Stevic, J. Diblik, Z. Smarda, On periodic and solutions converging to zero of some systems of differential-difference equations, Applied Mathematics and Computation, 227 (2014), 43-49.
M. Tatari, M. Denghan, Improvement of He’s variational iteration method for solving systems of differential equations, Comput. Math. Appl., 58, 2009, 2160-6.
M. Thangmoon, S. Pusjuso, Numerical solutions of differential transform method and Laplace transform method for a system of differential equations, Nonlinear Anal: Hybrid Syst., 4, 2010, 425-31.
S¸. Y¨uzbas¸ı, An Efficient algorithm for solving multi-pantograph equation systems, Computers&Mathematics with Applications 64(4), 2012, 589-603.
S¸. Y¨uzbas¸ı, E. G¨ok, M. Sezer, Laguerre matrix Method with the residual error estimation for solutions of a class of delay differential equations, Math. Meth. Appl. Sci. 37, 2014, 453-463.
S¸. Y¨uzbas¸ı, N. S¸ahin, A. Yıldırım, Numerical solutions of systems of high-order linear differential-difference equations with Bessel polynomial bases, Zeitschrift fr Naturforschung A. J. Phys. Sci. 66a, 2011, 519-32.
M. Zurigat, S. Momani, Z. Odibat, A. Alawneh, The homotopy analysis method for handling systems of fractional differential equations, Appl. Math. Modell., 34, 2010, 24-35.
An approach to numerical solutions of system of high-order linear differential-difference equations with variable coefficients and error estimation based on residual function
In this study a method is presented which aims to make an approach by using Bernstein polynomials to solutions of systemsof high order linear differential-difference equations with variable coefficients given under mixed conditions. The method convertsa given system of differential-difference equations and the conditions belonging to this system to equations that can be expressedby matrices by using the collacation points and provides to find the unknown coefficients of approximate solutions sought in termsof Bernstein polynomials. Different examples are presented with the purpose to show the applicability and validity of the method.Absolute error values between exact and approximate solutions are computed. The estimated values of absolute errors are computed byusing the residual function and these estimated errors are compared with absolute errors. For all numerical computations of this studythe computer algebraic system Maple 15 is used
Kaynakça
I.H. Abdel-Halim, Application to differential transformation for solving systems of differential equations, Appl. Math. Modell., 32, 2008, 2552-9.
A. Aky¨uz, M. Sezer, Chebyshev polynomial solutions of systems of high-order linear differential equations with variable coefficients, Appl. Math. Comput., 144, 2003, 237-47.
M.I. Bhatti, P. Bracken, Solutions of differential equations in a Bernstein polynomial basis, J. Comput. Appl. Math., 205, 2007, 272-280.
J. Biazar, E. Babolian, R. Islam Solution of system of ordinary differential equations by Adomian decomposition method, Appl. Math. Comput., 147, 2004, 713-9.
˙I. C¸ elik, Collacation method and residual correction using Chebyshev series, Applied Mathematics and Computation 174, 2006, 910-920.
A. Davies, D. Crann, The solution of systems of differential equations using numerical Laplace transforms,Int. J. Math. Educ. Sci. Technol., 30, 1999, 65-79.
J. Diblik, B.Iricanin, S. Stevic, Z. Smarda, Note on the existence of periodic solutions of a class of systems of differential-difference equations, Applied Mathematics and Computation, 232 (2014), 922-928.
E. G¨okmen, M. Sezer, Taylor collacation method for systems of high-order linear differential-difference equations with variable coefficients, Ain Shams Engineering Jornal, 4, 2013, 117-125.
H. Jafari, V. Daftardar-Gejji, Revised Adomian decomposition method for solving systems of ordinary and fractional differential equations, Appl. Math. Comput., 181, 2006, 598-608.
F. Mohamed, I. Naeem, A. Qadir, Conditional linearizability criteria for a system of third-order ordinary differential equations, Nonlinear Anal:Real World Apll., 10, 2009, 3404-12.
A. Saadatmandi, M. Denghan, A. Eftekhari, Application of He’s homotopy perturbation method for nonlinear system of second orer boundary value problems, Nonlinear Anal:Real World Apll., 10, 2009, 1912-22.
M. Sezer, A. Karamete, M. G¨ulsu, Taylor polynomial solutions of systems of linear differential equations with variable coefficients, Int. J. Comput. Math., 82(6), 2005, 755-64.
S. Shahmorad, Numerical solution of general form linear Fredholm-Volterra integro differential equations by the tau method with an error estimation, Applied Mathematics and Computation 167, 2005, 1418-1429.
S. Stevic, J. Diblik, Z. Smarda, On periodic and solutions converging to zero of some systems of differential-difference equations, Applied Mathematics and Computation, 227 (2014), 43-49.
M. Tatari, M. Denghan, Improvement of He’s variational iteration method for solving systems of differential equations, Comput. Math. Appl., 58, 2009, 2160-6.
M. Thangmoon, S. Pusjuso, Numerical solutions of differential transform method and Laplace transform method for a system of differential equations, Nonlinear Anal: Hybrid Syst., 4, 2010, 425-31.
S¸. Y¨uzbas¸ı, An Efficient algorithm for solving multi-pantograph equation systems, Computers&Mathematics with Applications 64(4), 2012, 589-603.
S¸. Y¨uzbas¸ı, E. G¨ok, M. Sezer, Laguerre matrix Method with the residual error estimation for solutions of a class of delay differential equations, Math. Meth. Appl. Sci. 37, 2014, 453-463.
S¸. Y¨uzbas¸ı, N. S¸ahin, A. Yıldırım, Numerical solutions of systems of high-order linear differential-difference equations with Bessel polynomial bases, Zeitschrift fr Naturforschung A. J. Phys. Sci. 66a, 2011, 519-32.
M. Zurigat, S. Momani, Z. Odibat, A. Alawneh, The homotopy analysis method for handling systems of fractional differential equations, Appl. Math. Modell., 34, 2010, 24-35.
Korkmaz, N., & Sezer, M. (2014). An approach to numerical solutions of system of high-order linear differential-difference equations with variable coefficients and error estimation based on residual function. New Trends in Mathematical Sciences, 2(3), 220-233.
AMA
Korkmaz N, Sezer M. An approach to numerical solutions of system of high-order linear differential-difference equations with variable coefficients and error estimation based on residual function. New Trends in Mathematical Sciences. Aralık 2014;2(3):220-233.
Chicago
Korkmaz, Nebiye, ve Mehmet Sezer. “An Approach to Numerical Solutions of System of High-Order Linear Differential-Difference Equations With Variable Coefficients and Error Estimation Based on Residual Function”. New Trends in Mathematical Sciences 2, sy. 3 (Aralık 2014): 220-33.
EndNote
Korkmaz N, Sezer M (01 Aralık 2014) An approach to numerical solutions of system of high-order linear differential-difference equations with variable coefficients and error estimation based on residual function. New Trends in Mathematical Sciences 2 3 220–233.
IEEE
N. Korkmaz ve M. Sezer, “An approach to numerical solutions of system of high-order linear differential-difference equations with variable coefficients and error estimation based on residual function”, New Trends in Mathematical Sciences, c. 2, sy. 3, ss. 220–233, 2014.
ISNAD
Korkmaz, Nebiye - Sezer, Mehmet. “An Approach to Numerical Solutions of System of High-Order Linear Differential-Difference Equations With Variable Coefficients and Error Estimation Based on Residual Function”. New Trends in Mathematical Sciences 2/3 (Aralık 2014), 220-233.
JAMA
Korkmaz N, Sezer M. An approach to numerical solutions of system of high-order linear differential-difference equations with variable coefficients and error estimation based on residual function. New Trends in Mathematical Sciences. 2014;2:220–233.
MLA
Korkmaz, Nebiye ve Mehmet Sezer. “An Approach to Numerical Solutions of System of High-Order Linear Differential-Difference Equations With Variable Coefficients and Error Estimation Based on Residual Function”. New Trends in Mathematical Sciences, c. 2, sy. 3, 2014, ss. 220-33.
Vancouver
Korkmaz N, Sezer M. An approach to numerical solutions of system of high-order linear differential-difference equations with variable coefficients and error estimation based on residual function. New Trends in Mathematical Sciences. 2014;2(3):220-33.