The Application of Hybrid Orthonomal Bernstein and Block-Pulse Functions in Finding Numerical Solution of Fredholm Fuzzy Integral Equations
In this paper, we have proposed a numerical method
for solving fuzzy Fredholm integral equation of the second kind. In
this method a combination of orthonormal Bernstein and Block-Pulse
functions are used. In most cases, the proposed method leads to
the exact solution. The advantages of this method are shown by an
example and calculate the error analysis.
[1] L. A. Zadeh,”Linguistic variable approximate and disposition,” in Med.
Inform, pp. 173-186, 1983.
[2] S. S. L. Chang and L. Zadeh, ”On fuzzy mapping and control, ” in IEEE
trans system Cybernet, vol. 2, pp. 30-34, 1972.
[3] K. Maleknejad, M. Shahrezaee and H. Khatami, ”Numerical solution of
integral equations system of the second kind by Block-Pulse functions,”
in Applied Mathematics and Computation, vol. 166, pp. 15-24, 2005.
[4] E. Babolian and Z. Masouri, ”Direct method to solve Volterra integral
equation of the first kind using operational matrix with block-pulse
functions,” in Applied Mathematics and Computation, vol. 220, pp. 51-57,
2008.
[5] E. Babolian, K. Maleknejad, M. Roodaki and H. Almasieh,
”Twodimensional triangular functions and their applications to nonlinear
2D Volterra-Fredholm integral equations,” in Computer and Mathematics
with Applications, vol. 60, pp. 1711-1722, 2010.
[6] F. Mirzaee and S. Piroozfar, ”Numerical solution of the linear two
dimensional Fredholm integral equations of the second kind via two
dimensional triangular orthogonal functions,” in Journal of King Saud
University, vol. 22, pp. 185-193, 2010.
[7] Y. Ordokhani, ”Solution of nonlinear Volterra-Fredholm-Hammerstein
integral equations via rationalized Haar functions,” in Applied
Mathematics and Computation, vol. 180, pp. 436-443, 2006.
[8] K. Maleknejad and M. T. Kajani, ”Solving second kind integral equations
by Galerkin methods with hybrid Legendre and Block-Pulse functions,”
in Applied Mathematics and Computation, vol. 145, pp. 623-629, 2003.
[9] E. Hashemzadeh, K. Maleknejad and B. Basirat, ”Hybrid functions
approach for the nonlinear Volterra-Fredholm integral equations,” in
Procedia Computer Sience, vol.3, pp. 1189-1194, 2011.
[10] M. T. Kajani and A. H. Vencheh, ”Solving second kind integral
equations with Hybrid Chebyshev and Block-Pulse functions,” in Applied
Mathematics and Computation, vol. 163, pp. 71-77, 2005.
[11] X. T. Wang and Y. M. Li, ”Numerical solutions of integrodifferential
systems by hybrid of general block-pulse functions and the second
Chebyshev polynomials,” in Applied Mathematics and Computation, vol.
209, pp. 266- 272, 2009.
[12] K. Maleknejad and Y. Mahmoudi, ”Numerical solution of linear
Fredholm integral equation by using hybrid Taylor and Block-Pulse
functions,” in Applied Mathematics and Computation, vol. 149, pp.
799-806, 2004.
[13] B. Asady, M. T. Kajani, A. H. Vencheh and A. Heydari, ”Solving second
kind integral equations with hybrid Fourier and block-pulse functions,”
in Applied Mathematics and Computation, vol. 160, pp. 517-522, 2005.
[14] G. P. Rao, ”Piecewise Constant Orthogonal Functions and their
Application to System and Control,” in Springer-Verlag, 1983.
[15] B. M. Mohan and K.B. Datta, ”Orthogonal Function in Systems and
Control,” 1995.
[16] K. Maleknejad, B. Basirat and E. Hashemizadeh, ”A Bernstein
operational matrix approach for solving a system of high order linear
Volterra-Fredholm integro-differential equations,” in Math. Comput.
Model, vol. 55, pp. 1363-1372, 2012.
[17] T. J. Rivlin, ”An introduction to the approximate of functions,” in New
York, DovePublications, 1969.
[18] S. A. yousefi, M. Behroozifar, ”Operational matrrices of Bernstein
polynomials and their applications,” in International Journal of System
Science, vol. 41, pp. 709-716, 2010.
[19] O. Kaleva, ”Fuzzy differential equations,” in Fuzzy Sets Syst, vol. 24,
pp. 301-317, 1987.
[20] M. Ma, M. Friedman and A. Kandel, ”Duality in fuzzy linear systems,”
Fuzzy Sets and Systems, vol. 109, pp. 55-58, 2000.
[21] S. Gal, ”Approximation theory in fuzzy setting,” Chapter 13 in
Handbook of analytic-computational methods in applied mathematics, pp.
617-666, 2000.
[22] G. A. Anastassiou, ”Fuzzy mathematcs: Approximation theory,” in
Springer, Heidelberge, 2010.
[23] R. Goetschel, W. Voxman, ”Elementary fuzzy calculus,” in Fuzzy Sets
and Systems, vol. 18, pp. 31-43, 1986.
[24] H. Wu, ”The fuzzy Riemann integral and its numerical integration,” in
Fuzzy Sets and Systems, vol. 110, pp. 1-25, 2000.
[25] M. Friedman, M. Ming and A. Kandel, ”Fuzzy linear systems,” in FSS,
vol. 96, pp. 201-20, 1998.
[1] L. A. Zadeh,”Linguistic variable approximate and disposition,” in Med.
Inform, pp. 173-186, 1983.
[2] S. S. L. Chang and L. Zadeh, ”On fuzzy mapping and control, ” in IEEE
trans system Cybernet, vol. 2, pp. 30-34, 1972.
[3] K. Maleknejad, M. Shahrezaee and H. Khatami, ”Numerical solution of
integral equations system of the second kind by Block-Pulse functions,”
in Applied Mathematics and Computation, vol. 166, pp. 15-24, 2005.
[4] E. Babolian and Z. Masouri, ”Direct method to solve Volterra integral
equation of the first kind using operational matrix with block-pulse
functions,” in Applied Mathematics and Computation, vol. 220, pp. 51-57,
2008.
[5] E. Babolian, K. Maleknejad, M. Roodaki and H. Almasieh,
”Twodimensional triangular functions and their applications to nonlinear
2D Volterra-Fredholm integral equations,” in Computer and Mathematics
with Applications, vol. 60, pp. 1711-1722, 2010.
[6] F. Mirzaee and S. Piroozfar, ”Numerical solution of the linear two
dimensional Fredholm integral equations of the second kind via two
dimensional triangular orthogonal functions,” in Journal of King Saud
University, vol. 22, pp. 185-193, 2010.
[7] Y. Ordokhani, ”Solution of nonlinear Volterra-Fredholm-Hammerstein
integral equations via rationalized Haar functions,” in Applied
Mathematics and Computation, vol. 180, pp. 436-443, 2006.
[8] K. Maleknejad and M. T. Kajani, ”Solving second kind integral equations
by Galerkin methods with hybrid Legendre and Block-Pulse functions,”
in Applied Mathematics and Computation, vol. 145, pp. 623-629, 2003.
[9] E. Hashemzadeh, K. Maleknejad and B. Basirat, ”Hybrid functions
approach for the nonlinear Volterra-Fredholm integral equations,” in
Procedia Computer Sience, vol.3, pp. 1189-1194, 2011.
[10] M. T. Kajani and A. H. Vencheh, ”Solving second kind integral
equations with Hybrid Chebyshev and Block-Pulse functions,” in Applied
Mathematics and Computation, vol. 163, pp. 71-77, 2005.
[11] X. T. Wang and Y. M. Li, ”Numerical solutions of integrodifferential
systems by hybrid of general block-pulse functions and the second
Chebyshev polynomials,” in Applied Mathematics and Computation, vol.
209, pp. 266- 272, 2009.
[12] K. Maleknejad and Y. Mahmoudi, ”Numerical solution of linear
Fredholm integral equation by using hybrid Taylor and Block-Pulse
functions,” in Applied Mathematics and Computation, vol. 149, pp.
799-806, 2004.
[13] B. Asady, M. T. Kajani, A. H. Vencheh and A. Heydari, ”Solving second
kind integral equations with hybrid Fourier and block-pulse functions,”
in Applied Mathematics and Computation, vol. 160, pp. 517-522, 2005.
[14] G. P. Rao, ”Piecewise Constant Orthogonal Functions and their
Application to System and Control,” in Springer-Verlag, 1983.
[15] B. M. Mohan and K.B. Datta, ”Orthogonal Function in Systems and
Control,” 1995.
[16] K. Maleknejad, B. Basirat and E. Hashemizadeh, ”A Bernstein
operational matrix approach for solving a system of high order linear
Volterra-Fredholm integro-differential equations,” in Math. Comput.
Model, vol. 55, pp. 1363-1372, 2012.
[17] T. J. Rivlin, ”An introduction to the approximate of functions,” in New
York, DovePublications, 1969.
[18] S. A. yousefi, M. Behroozifar, ”Operational matrrices of Bernstein
polynomials and their applications,” in International Journal of System
Science, vol. 41, pp. 709-716, 2010.
[19] O. Kaleva, ”Fuzzy differential equations,” in Fuzzy Sets Syst, vol. 24,
pp. 301-317, 1987.
[20] M. Ma, M. Friedman and A. Kandel, ”Duality in fuzzy linear systems,”
Fuzzy Sets and Systems, vol. 109, pp. 55-58, 2000.
[21] S. Gal, ”Approximation theory in fuzzy setting,” Chapter 13 in
Handbook of analytic-computational methods in applied mathematics, pp.
617-666, 2000.
[22] G. A. Anastassiou, ”Fuzzy mathematcs: Approximation theory,” in
Springer, Heidelberge, 2010.
[23] R. Goetschel, W. Voxman, ”Elementary fuzzy calculus,” in Fuzzy Sets
and Systems, vol. 18, pp. 31-43, 1986.
[24] H. Wu, ”The fuzzy Riemann integral and its numerical integration,” in
Fuzzy Sets and Systems, vol. 110, pp. 1-25, 2000.
[25] M. Friedman, M. Ming and A. Kandel, ”Fuzzy linear systems,” in FSS,
vol. 96, pp. 201-20, 1998.
@article{"International Journal of Engineering, Mathematical and Physical Sciences:68163", author = "Mahmoud Zarrini and Sanaz Torkaman", title = "The Application of Hybrid Orthonomal Bernstein and Block-Pulse Functions in Finding Numerical Solution of Fredholm Fuzzy Integral Equations", abstract = "In this paper, we have proposed a numerical method
for solving fuzzy Fredholm integral equation of the second kind. In
this method a combination of orthonormal Bernstein and Block-Pulse
functions are used. In most cases, the proposed method leads to
the exact solution. The advantages of this method are shown by an
example and calculate the error analysis.
", keywords = "Fuzzy Fredholm Integral Equation, Bernstein,
Block-Pulse, Orthonormal.", volume = "8", number = "7", pages = "1074-5", }
