حل عددی معادلات انتگرال –دیفرانسیل تأخیری فردهلم خطی مرتبۀ بالا با ضرایب متغیر با استفاده از بسط چبیشف

نویسندگان
1 دانشگاه خوارزمی، دانشکدۀ علوم ریاضی و کامپیوتر
2 دانشگاه اصفهان، پردیس خوانسار، گروه ریاضی
چکیده
ایدۀ اصلی این مقاله، استفاده از چندجمله‌ای‌های چبیشف برای حل معادلات انتگرال-دیفرانسیل تأخیری فردهلم خطی با مراتب بالا است. معمولاً حل این معادلات به‌روش‌های تحلیلی امکان‌پذیر نیست یا در صورت امکان بسیار مشکل است. در این روش معادله مورد نظر به‌وسیلۀ روابط ماتریسی بین چندجمله‌ای‌های چبیشف و مشتقات آنها به دستگاه معادلات خطی تبدیل می‌شود. ماتریس‌های عملیاتی عملگرهای تأخیر و مشتق همراه با روش تائو برای محاسبۀ ضرایب مجهول بسط چبیشف جواب استفاده می‌شوند. همگرایی روش بررسی شده است. مثال‌های عددی، اعتبار و کارایی روش ارائه شده را نشان می‌دهند. هم‌چنین نتایج حاصل از روش با نتایج موجود مقایسه شده است.
کلیدواژه‌ها

عنوان مقاله English

Numerical Solution using Chebyshev Expansion of the Higher-Orders Linear Fredholm Integro-Differential-Difference Equations with Variable Coefficients

نویسندگان English

Babolian 1
Fatemeh Chitsaz 1
Ali Davari 2
1 Kharazmi University
2 Department of Mathematics, Khansar Campus, University of Isfahan, Iran
چکیده English

The main aim of this paper is to apply the Chebyshev polynomials for the solution of the linear Fredholm integro-differential-difference equation of high orders. It is usually difficult to analytically solve this equation. Our approach consists of reducing the problem to a set of linear equations by means of the matrix relations between the Chebyshev polynomials and their derivatives. The operational matrices of delay and derivative together with the Tau method are then utilized to evaluate the unknown coefficients of Chebyshev expansion of the solution. The convergence analysis is studied. Illustrative examples show the validity and applicability of the presented technique. Also, a comparison is made with existing results.
Introduction
The integro-difference equations arise in different applications such as biological, physical and engineering problems. In recent years, there has been a growing interest in the numerical treatment of the integro-differential-difference equations. Since the mentioned equations are usually difficult to solve analytically, numerical methods are required. Several numerical methods were used such as successive approximation method, Adomian decomposition method, the Taylor collocation method, Haar wavelet method, Legendre wavelets method, wavelet-Galerkin method, monotone iterative technique, Walsh series method, etc.
In this work, we develop a framework to obtain the numerical solution of the s-order linear Fredholm integro-differential-difference equation with variable coefficients.

under the mixed conditions

whereand are known continuous functions. Here, the real coefficients and are given constants.
Our approach consists of reducing the problem to a set of linear equations by expanding the solution in terms of Chebyshev polynomials. The operational matrices of delay and derivative are given. These matrices together with the Tau method utilized to evaluate the unknown coefficients of expansion. The Tau method has been originally proposed by Lanczos for ordinary differential equations and extended by Ortiz. The method consists of expanding the required approximate solution as the elements of a complete set of orthogonal polynomials. Recently there have been several published works in the literature on the applications of the Tau method.
Conclusion
This paper deals with the solution of linear Fredholm integro-differential-difference equations of high order with variable coefficients. Our approach was based on the Chebyshev Tau method which reduces a linear Fredholm integro-differential-difference equation into a set of linear algebraic equations. Numerical results show that this approach can solve the problem effectively. The approach, with some modifications, can be employed to solve differential-difference equations and Fredholm integro-differential equations../files/site1/files/64/4.pdf

کلیدواژه‌ها English

Differential-difference equation
Fredholm integro-differential-difference equation
Tau method
Operational matrix
Chebyshev polynomials
1. Jackiewicz Z., Rahman M., Welfert B. D., "Numerical solution of a Fredholm integro-differential equation modelling neural networks", Appl. Numer. Math. 56 (2006) 423-432.## 2. Cao J., Wang J., "Delay-dependent robust stability of uncertain nonlinear systems with time delay", Appl. Math. Comput. 154 (2004) 289-297. ## 3. Wazwaz A. M., "A First Course in Integral Equations, World Scientific", River Edge, NJ, (1997). ## 4. Wang W., Lin C., "A new algorithm for integral of trigonometric functions with mechanization", Appl. Math. Comput. 164 (1) (2005) 71-82. ## 5. Rashed M. T., "Numerical solution of functional differential", integral and integro-differential equations, Appl. Numer. Math. 156 (2004) 485-492. ## 6. Maleknejad K., Mahmoudi Y., "Numerical solution of linear Fredholm integral equation by using hybrid Taylor and block-pulse functions", Appl. Math. Comput. 149 (2004) 799-806. ## 7. Dehghan M., Shakeri F., "Solution of an integro-differential equation arising in oscillating magnetic fields using He’s homotopy perturbation method", Progr. In Electromagn. Res., PIER 78 (2008) 361-376. ## 8. Gulsu M., Ozturk Y., Sezer M., "A new collocation method for solution of mixed linear integro-differential-difference equations", Appl. Math. Comput. 216 (2010) 2183-2198. ## 9. Delves L. M., Mohamed J. L., "Computational Methods for Integral Equations", Cambridge University Press, Cambridge (1985). ## 10. Bellman R., Cook K., "Differential-Difference Equations", Academic Press (1963). ## 11. Maleknejad K., Aghazadeh N., "Numerical solutions of Volterra integral equations of the second kind with convolution kernel by using Taylor-series expansion method", Appl. Math. Comput. 161 (3) (2005) 915-922. ## 12. Karamete A., Sezer M., "A Taylor collocation method for the solution of linear integro-differential equations", Int. J. Comput. Math. 79 (9) (2002) 987-1000. ## 13. Tavassoli Kajani M., Ghasemi M., Babolian E., "Numerical solution of linear integro-differential equation by using sine-cosine wavelets", Appl. Math. Comput. 180 (2006) 569-574. ## 14. Razzaghi M., Yousefi S., "Legendre wavelets method for the nonlinear Volterra-Fredholm integral equations", Math. Comput. Simul. 70 (2005) 1-8. ## 15. Asady B., Tavassoli Kajani M., HadiVencheh A., Heydari A., "Solving second kind integral equations with hybrid Fourier and block-pulse functions", Appl. Math. Comput. 160 (14) (2005) 517-522. ## 16. Nas S., Yalcinbas S., Sezer M., "A Taylor polynomial approach for solving high order linear Fredholm integro-differential equations", Int. J. Math. Educ. Sci. Technol. 31 (2) (2000) 213-225. ## 17. Zhao J., Corless R. M., "Compact finite difference method for integro-differential equations, Appl. Math. Comput. 177 (2006) 271-288. ## 18. Gulsu M., Sezer M., "Approximations to the solution of linear Fredholm integro-differential-difference equation of high order", J. Franklin Inst. 343 (2006) 720-737. ## 19. Lanczos C., "Trigonometric interpolation of empirical and analytic functions", J. Math. Phys. 17 (1938) 123-199. ## 20. Ortiz E. L., "The Tau method, SIAM J. Numer", Anal. Optim. 12 (1969) 480-492. ## 21. Canuto C., Hussaini M. Y., Quarteroni A., Zang T. A., "Spectral Methods: Fundamentals in Single Domains", Springer, Berlin (2006). ## 22. Mason J. C., Handscomb D. C., "Chebyshev Polynomials", CRC Press (2002). ## 23. Dehghan M., Saadatmandi A., "A Tau method for the one-dimensional parabolic inverse problem subject to temperature overspecification", Comput. Math. Appl. 52 (2006) 933-940. ## 24. Pour-Mahmoud J., Rahimi-Ardabili M. Y., Shahmorad S., "Numerical solution of the system of Fredholm integro-differential equations by the Tau method", Appl. Math. Comput. 168 (2005) 465-478. ## 25. Hosseini S. M., Shahmorad S., "A matrix formulation of the Tau method and Volterra linear integro-differential equations", Korean J. Comput. Appl. Math. 9 (2) (2002) 497-507. ## 26. Kalla S. L., Khajah H. G., "Tau approximation method of the Hubbell rectangular source integral", Radiat. Phys. Chem. 59 (1) (2000) 17-21. ##