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2011 | 21 | 3 | 535-547

Tytuł artykułu

An operational Haar wavelet method for solving fractional Volterra integral equations

Treść / Zawartość

Warianty tytułu

Języki publikacji

EN

Abstrakty

EN
A Haar wavelet operational matrix is applied to fractional integration, which has not been undertaken before. The Haar wavelet approximating method is used to reduce the fractional Volterra and Abel integral equations to a system of algebraic equations. A global error bound is estimated and some numerical examples with smooth, nonsmooth, and singular solutions are considered to demonstrate the validity and applicability of the developed method.

Rocznik

Tom

21

Numer

3

Strony

535-547

Opis fizyczny

Daty

wydano
2011
otrzymano
2010-06-16
poprawiono
2010-11-30

Twórcy

  • Department of Mathematics, Faculty of Mathematics and Computer Science, Shahid Bahonar University of Kerman, Kerman, 76169-14111, Iran
  • Department of Mathematics, Faculty of Mathematics and Computer Science, Shahid Bahonar University of Kerman, Kerman, 76169-14111, Iran
  • Department of Mathematics, Faculty of Mathematics and Computer Science, Shahid Bahonar University of Kerman, Kerman, 76169-14111, Iran
  • Max Planck Institute for Mathematics in the Sciences (MIS), Inselstrasse 22, Leipzig 04103, Germany
  • Mahani Mathematical Research Center, Shahid Bahonar University of Kerman, Kerman, 76169-14111, Iran
  • Max Planck Institute for Mathematics in the Sciences (MIS), Inselstrasse 22, Leipzig 04103, Germany
  • Institute of Theoretical and Experimental Biophysics, Russian Academy of Sciences, Pushchino, Moscow Region 142290, Russia

Bibliografia

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  • Baillie, R.T. (1996). Long memory processes and fractional integration in econometrics, Journal of Econometrics 73(1): 5-59.
  • Baratella, P. and Orsi, A.P. (2004). New approach to the numerical solution of weakly singular Volterra integral equations, Journal of Computational and Applied Mathematics 163(2): 401-418.
  • Brunner, H. (1984). The numerical solution of integral equations with weakly singular kernels, in D.F. GriMths (Ed.), Numerical Analysis, Lecture Notes in Mathematics, Vol. 1066, Springer, Berlin, pp. 50-71.
  • Chen, C.F. and Hsiao, C.H. (1997). Haar wavelet method for solving lumped and distributed parameter systems, IEE Proceedings: Control Theory and Applications 144(1): 87-94.
  • Chena, W., Suna, H., Zhang, X. and Korŏsak, D. (2010). Anomalous diffusion modeling by fractal and fractional derivatives, Computers & Mathematics with Applications 59(5): 265-274.
  • Chiodo, S., Chuev, G.N., Erofeeva, S.E., Fedorov, M.V., Russo, N. and Sicilia, E. (2007). Comparative study of electrostatic solvent response by RISM and PCM methods, International Journal of Quantum Chemistry 107: 265-274.
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  • Chuev, G.N., Fedorov, M.V., Chiodo, S., Russo, N. and Sicilia, E. (2008). Hydration of ionic species studied by the reference interaction site model with a repulsive bridge correction, Journal of Computational Chemistry 29(14): 2406-2415.
  • Chuev, G.N., Chiodo, S., Fedorov, M.V., Russo, N. and Sicilia, E. (2006). Quasilinear RISM-SCF approach for computing solvation free energy of molecular ions, Chemical Physics Letters 418: 485-489.
  • Dixon, J. (1985). On the order of the error in discretization methods for weakly singular second kind Volterra integral equations with non-smooth solution, BIT 25(4): 624-634.
  • Hsiao, C.H. and Wu, S.P. (2007). Numerical solution of timevarying functional differential equations via Haar wavelets, Applied Mathematics and Computation 188(1): 1049-1058.
  • Lepik, Ü. and Tamme, E. (2004). Application of the Haar wavelets for solution of linear integral equations, Dynamical Systems and Applications, Proceedings, Antalya, Turkey, pp. 494-507.
  • Lepik, Ü. (2009). Solving fractional integral equations by the Haar wavelet method, Applied Mathematics and Computation 214(2): 468-478.
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  • Magin, R.L. (2004). Fractional calculus in bioengineering. Part 2, Critical Reviews in Bioengineering 32: 105-193.
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  • Meral, F.C., Royston, T.J. and Magin, R. (2010). Fractional calculus in viscoelasticity: An experimental study, Communications in Nonlinear Science and Numerical Simulation 15(4): 939-945.
  • Metzler, R. and Nonnenmacher, T.F. (2003). Fractional relaxation processes and fractional rheological models for the description of a class of viscoelastic materials, International Journal of Plasticity 19(7): 941-959.
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Bibliografia

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