Araştırma Makalesi
BibTex RIS Kaynak Göster
Yıl 2021, Cilt: 17 Sayı: 1, 59 - 66, 30.12.2020
https://doi.org/10.18466/cbayarfbe.791302

Öz

Kaynakça

  • 1. Erdem, K, Yalçınbaş, S, Sezer, M. 2013. A Bernoulli polynomial approach with residual correction for solving mixed linear Fredholm integro-differentialdifference equations. Journal of Difference Equations and Applications; 19: 1619-1631.
  • 2. Laib, H, Bellour, A, Bousselsal, A. 2019. Numerical solution of high-order linear Volterra integro-differential equations by using Taylor collocation method. International Journal of Computer Mathematics; 96 (5): 1066–1085.
  • 3. Chen, J, He, M, Zeng, T. 2019. A multiscale Galerkin method for second-order boundary value problems of Fredholm integro-differential equation II: Efficient algorithm for the discrete linear system. J. Vis. Commun. Image R.; 58: 112–118.
  • 4. Hesameddini, E, Shahbazi, M. 2019. Solving multipoint problems with linear Volterra–Fredholm integro-differential equations of the neutral type using Bernstein polynomials Method. Applied Numerical Mathematics; 136: 122–138.
  • 5. Rohaninasab, N, Maleknejad, K, Ezzati, R. 2018. Numerical solution of high-order Volterra–Fredholm integro-differential equations by using Legendre collocation method. Applied Mathematics and Computation; 328: 171–188.
  • 6. Wang, Y, Zhu, L. 2017. Solving nonlinear Volterra integro-differential equations of fractional order by using Euler wavelet method. Advances in Difference Equations; 2017(1): 27.
  • 7. Babayar-Razlighi, B, Soltanalizadeh, B. 2013. Numerical solution for system of singular nonlinear Volterra integro-differential equations by Newton-Product method. Applied Mathematics and Computation; 219: 8375–8383.
  • 8. Roul, P, Meyer, P. 2011. Numerical solutions of systems of nonlinear integro-differential equations by Homotopy-perturbation method. Applied Mathematical Modelling; 35: 4234–4242.
  • 9. Yüzbaşı, Ş. 2016. Improved Bessel collocation method for linear Volterra integro-differential equations with piecewise intervals and application of a Volterra population model. Applied Mathematical Modelling; 40: 5349–5363.
  • 10. Gu, Z. 2019. Spectral collocation method for weakly singular Volterra integro-differential equations. Applied Numerical Mathematics; 143: 263–275.
  • 11. Yuzbasi, S, Sahin, N, Sezer, M. 2011. Bessel matrix method for solving high-order linear Fredholm integro-differential equations, Journal of Advanced Research in Applied Math.; 3(23): 1-25.
  • 12. Hosseini, SM, Shahmorad, S. 2003. Tau numerical solution of Fredholm integro-differential equations with arbitrary polynomial bases. Applied Mathematical Modelling; 27: 145–154.
  • 13. Erdem, Biçer, K, Sezer, M. 2017. Bernoulli matrix-collocation method for solving general functional integro- differential equations with Hybrid delays. Journal of Inequalities and Special Functions; 8(3): 85-99.
  • 14. Turkyilmazoglu, M. 2014. An effective approach for numerical solutions of high-order Fredholm integro-differential equations. Appl. Math. Comput; 227: 384–398.
  • 15. Kürkçü, ÖK, Aslan, E, Sezer, M. 2016. A numerical approach with error estimation to solve general integro-differential–difference equations using Dickson polynomials. Applied Mathematics and Computation; 276: 324–339
  • 16. Yıldırım, A. 2008. Solution of BVPs for fourth-order integro-differential equations by using homotopy perturbation method. Computers and Mathematics with Applications; 56: 3175-3180.
  • 17. Mirzaee, F, Hoseini, SF. 2017. A new collocation approach for solving systems of high-order linear Volterra integro-differential equations with variable coefficients. Applied Mathematics and Computation; 311: 272–282.
  • 18. Yalçınbaş, S, Erdem, K. 2014. A New Approximation Method for the Systems of Nonlinear Fredholm Integral Equations. Applied Mathematics and Physic; 2(2): 40-48.
  • 19. Mustafa, MM, Muhammad, AM. 2014. Numerical Solution of Linear Volterra-Fredholm Integro-Differential Equations Using Lagrange Polynomials. Mathematical Theory and Modelin; 4(5): 137-146.
  • 20. Dastjerdi, HL, Maalek, Ghaini FM. 2012. Numerical solution of Volterra–Fredholm integral equations by moving least square method and Chebyshev polynomials. Applied Mathematical Modelling; 36: 3283–3288.
  • 21. Maleknejad, K, Basirat, B, Hashemizadeh E. 2012. A Bernstein operational matrix approach for solving a system of high order linear Volterra–Fredholm integro-differential equations. Mathematical and Computer Modelling; 55: 1363–1372.
  • 22. Yüzbaşı, Ş, Şahin, N, Yildirim, A. 2012. A collocation approach for solving high-order linear Fredholm–Volterra integro-differential equations. Mathematical and Computer Modelling; 55: 547–563. 23. Rashidinia, J, Tahmasebi, A. 2013. Approximate solution of linear integro-differential equations by using modified Taylor expansion method. World Journal of Modelling and Simulation; 9(4): 289-301.
  • 24. Erdem, Bicer, K, Yalcinbas, S. 2016. A Matrix Approach to Solving Hyperbolic Partial Differential Equations Using Bernoulli Polynomials, Published by Faculty of Sciences and Mathematics, 30(4): 993–1000.
  • 25. Cravero, I, Pittaluga, G, Sacripante, L. 2012. An algorithm for solving linear Volterra integro-differential equations. Numer Algor; 60: 101–114,
  • 26. Jordan, C. Calculus of Finite Differences; Chelsea Publishing Company: New York, 1950; pp 318.
  • 27. Baykus, Savasaneril, N, Sezer, M. 2016. Laguerre polynomial solution of high- order linear Fredholm integro-differential equations. NTMSCI; 4(2), 273-284.
  • 28. Yüzbaşı, Ş, Şahin, N, Sezer, M. 2011. Bessel polynomial solutions of high-order linear Volterra integro-differential equations. Computers and Mathematics with Applications; 62: 1940–1956.
  • 29. Balcı, MA, Sezer, M. 2016. Hybrid Euler-Taylor matrix method for solving of generalized linear Fredholm integro-differential difference equations. Applied Mathematics and Computation; 273: 33–41.
  • 30. Roman, S., The Umbral Calculus; ACADEMIC PRESS: New York, 1984; pp 12.
  • 31. Kim, DS. 2014. A note on Boole polynomials. Integral Transforms and Special Functions, 25(8): 627-633.

Boole approximation method with residual error function to solve linear Volterra integro-differential equations

Yıl 2021, Cilt: 17 Sayı: 1, 59 - 66, 30.12.2020
https://doi.org/10.18466/cbayarfbe.791302

Öz

In this study, a numerical method is developed for the approximate solution of the linear Volterra integro-differential equations. This method is based Boole polynomial, its
derivatives and the collocation points. The aim is to reduce the given problem, as the linear algebraic equation, to the matrix equation. This matrix equation is solved using Boole collocation points. As a result, the approximate solution is obtained in the truncated Boole series in the interval [a,b]. The exact solution and the approximate solution are included in the study. Also, the error analysis and residual correction calculations are performed in the study. The results have been obtained by using computer program MATLAB.

Kaynakça

  • 1. Erdem, K, Yalçınbaş, S, Sezer, M. 2013. A Bernoulli polynomial approach with residual correction for solving mixed linear Fredholm integro-differentialdifference equations. Journal of Difference Equations and Applications; 19: 1619-1631.
  • 2. Laib, H, Bellour, A, Bousselsal, A. 2019. Numerical solution of high-order linear Volterra integro-differential equations by using Taylor collocation method. International Journal of Computer Mathematics; 96 (5): 1066–1085.
  • 3. Chen, J, He, M, Zeng, T. 2019. A multiscale Galerkin method for second-order boundary value problems of Fredholm integro-differential equation II: Efficient algorithm for the discrete linear system. J. Vis. Commun. Image R.; 58: 112–118.
  • 4. Hesameddini, E, Shahbazi, M. 2019. Solving multipoint problems with linear Volterra–Fredholm integro-differential equations of the neutral type using Bernstein polynomials Method. Applied Numerical Mathematics; 136: 122–138.
  • 5. Rohaninasab, N, Maleknejad, K, Ezzati, R. 2018. Numerical solution of high-order Volterra–Fredholm integro-differential equations by using Legendre collocation method. Applied Mathematics and Computation; 328: 171–188.
  • 6. Wang, Y, Zhu, L. 2017. Solving nonlinear Volterra integro-differential equations of fractional order by using Euler wavelet method. Advances in Difference Equations; 2017(1): 27.
  • 7. Babayar-Razlighi, B, Soltanalizadeh, B. 2013. Numerical solution for system of singular nonlinear Volterra integro-differential equations by Newton-Product method. Applied Mathematics and Computation; 219: 8375–8383.
  • 8. Roul, P, Meyer, P. 2011. Numerical solutions of systems of nonlinear integro-differential equations by Homotopy-perturbation method. Applied Mathematical Modelling; 35: 4234–4242.
  • 9. Yüzbaşı, Ş. 2016. Improved Bessel collocation method for linear Volterra integro-differential equations with piecewise intervals and application of a Volterra population model. Applied Mathematical Modelling; 40: 5349–5363.
  • 10. Gu, Z. 2019. Spectral collocation method for weakly singular Volterra integro-differential equations. Applied Numerical Mathematics; 143: 263–275.
  • 11. Yuzbasi, S, Sahin, N, Sezer, M. 2011. Bessel matrix method for solving high-order linear Fredholm integro-differential equations, Journal of Advanced Research in Applied Math.; 3(23): 1-25.
  • 12. Hosseini, SM, Shahmorad, S. 2003. Tau numerical solution of Fredholm integro-differential equations with arbitrary polynomial bases. Applied Mathematical Modelling; 27: 145–154.
  • 13. Erdem, Biçer, K, Sezer, M. 2017. Bernoulli matrix-collocation method for solving general functional integro- differential equations with Hybrid delays. Journal of Inequalities and Special Functions; 8(3): 85-99.
  • 14. Turkyilmazoglu, M. 2014. An effective approach for numerical solutions of high-order Fredholm integro-differential equations. Appl. Math. Comput; 227: 384–398.
  • 15. Kürkçü, ÖK, Aslan, E, Sezer, M. 2016. A numerical approach with error estimation to solve general integro-differential–difference equations using Dickson polynomials. Applied Mathematics and Computation; 276: 324–339
  • 16. Yıldırım, A. 2008. Solution of BVPs for fourth-order integro-differential equations by using homotopy perturbation method. Computers and Mathematics with Applications; 56: 3175-3180.
  • 17. Mirzaee, F, Hoseini, SF. 2017. A new collocation approach for solving systems of high-order linear Volterra integro-differential equations with variable coefficients. Applied Mathematics and Computation; 311: 272–282.
  • 18. Yalçınbaş, S, Erdem, K. 2014. A New Approximation Method for the Systems of Nonlinear Fredholm Integral Equations. Applied Mathematics and Physic; 2(2): 40-48.
  • 19. Mustafa, MM, Muhammad, AM. 2014. Numerical Solution of Linear Volterra-Fredholm Integro-Differential Equations Using Lagrange Polynomials. Mathematical Theory and Modelin; 4(5): 137-146.
  • 20. Dastjerdi, HL, Maalek, Ghaini FM. 2012. Numerical solution of Volterra–Fredholm integral equations by moving least square method and Chebyshev polynomials. Applied Mathematical Modelling; 36: 3283–3288.
  • 21. Maleknejad, K, Basirat, B, Hashemizadeh E. 2012. A Bernstein operational matrix approach for solving a system of high order linear Volterra–Fredholm integro-differential equations. Mathematical and Computer Modelling; 55: 1363–1372.
  • 22. Yüzbaşı, Ş, Şahin, N, Yildirim, A. 2012. A collocation approach for solving high-order linear Fredholm–Volterra integro-differential equations. Mathematical and Computer Modelling; 55: 547–563. 23. Rashidinia, J, Tahmasebi, A. 2013. Approximate solution of linear integro-differential equations by using modified Taylor expansion method. World Journal of Modelling and Simulation; 9(4): 289-301.
  • 24. Erdem, Bicer, K, Yalcinbas, S. 2016. A Matrix Approach to Solving Hyperbolic Partial Differential Equations Using Bernoulli Polynomials, Published by Faculty of Sciences and Mathematics, 30(4): 993–1000.
  • 25. Cravero, I, Pittaluga, G, Sacripante, L. 2012. An algorithm for solving linear Volterra integro-differential equations. Numer Algor; 60: 101–114,
  • 26. Jordan, C. Calculus of Finite Differences; Chelsea Publishing Company: New York, 1950; pp 318.
  • 27. Baykus, Savasaneril, N, Sezer, M. 2016. Laguerre polynomial solution of high- order linear Fredholm integro-differential equations. NTMSCI; 4(2), 273-284.
  • 28. Yüzbaşı, Ş, Şahin, N, Sezer, M. 2011. Bessel polynomial solutions of high-order linear Volterra integro-differential equations. Computers and Mathematics with Applications; 62: 1940–1956.
  • 29. Balcı, MA, Sezer, M. 2016. Hybrid Euler-Taylor matrix method for solving of generalized linear Fredholm integro-differential difference equations. Applied Mathematics and Computation; 273: 33–41.
  • 30. Roman, S., The Umbral Calculus; ACADEMIC PRESS: New York, 1984; pp 12.
  • 31. Kim, DS. 2014. A note on Boole polynomials. Integral Transforms and Special Functions, 25(8): 627-633.
Toplam 30 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Mühendislik
Bölüm Makaleler
Yazarlar

Kübra Erdem Biçer 0000-0002-4998-6531

Hale Gül Dağ 0000-0003-4378-0177

Yayımlanma Tarihi 30 Aralık 2020
Yayımlandığı Sayı Yıl 2021 Cilt: 17 Sayı: 1

Kaynak Göster

APA Erdem Biçer, K., & Dağ, H. G. (2020). Boole approximation method with residual error function to solve linear Volterra integro-differential equations. Celal Bayar Üniversitesi Fen Bilimleri Dergisi, 17(1), 59-66. https://doi.org/10.18466/cbayarfbe.791302
AMA Erdem Biçer K, Dağ HG. Boole approximation method with residual error function to solve linear Volterra integro-differential equations. CBUJOS. Aralık 2020;17(1):59-66. doi:10.18466/cbayarfbe.791302
Chicago Erdem Biçer, Kübra, ve Hale Gül Dağ. “Boole Approximation Method With Residual Error Function to Solve Linear Volterra Integro-Differential Equations”. Celal Bayar Üniversitesi Fen Bilimleri Dergisi 17, sy. 1 (Aralık 2020): 59-66. https://doi.org/10.18466/cbayarfbe.791302.
EndNote Erdem Biçer K, Dağ HG (01 Aralık 2020) Boole approximation method with residual error function to solve linear Volterra integro-differential equations. Celal Bayar Üniversitesi Fen Bilimleri Dergisi 17 1 59–66.
IEEE K. Erdem Biçer ve H. G. Dağ, “Boole approximation method with residual error function to solve linear Volterra integro-differential equations”, CBUJOS, c. 17, sy. 1, ss. 59–66, 2020, doi: 10.18466/cbayarfbe.791302.
ISNAD Erdem Biçer, Kübra - Dağ, Hale Gül. “Boole Approximation Method With Residual Error Function to Solve Linear Volterra Integro-Differential Equations”. Celal Bayar Üniversitesi Fen Bilimleri Dergisi 17/1 (Aralık 2020), 59-66. https://doi.org/10.18466/cbayarfbe.791302.
JAMA Erdem Biçer K, Dağ HG. Boole approximation method with residual error function to solve linear Volterra integro-differential equations. CBUJOS. 2020;17:59–66.
MLA Erdem Biçer, Kübra ve Hale Gül Dağ. “Boole Approximation Method With Residual Error Function to Solve Linear Volterra Integro-Differential Equations”. Celal Bayar Üniversitesi Fen Bilimleri Dergisi, c. 17, sy. 1, 2020, ss. 59-66, doi:10.18466/cbayarfbe.791302.
Vancouver Erdem Biçer K, Dağ HG. Boole approximation method with residual error function to solve linear Volterra integro-differential equations. CBUJOS. 2020;17(1):59-66.