Simulink Approach to Solve Fuzzy Differential Equation under Generalized Differentiability
In this paper, solution of fuzzy differential equation
under general differentiability is obtained by simulink. The simulink
solution is equivalent or very close to the exact solution of the
problem. Accuracy of the simulink solution to this problem is
qualitatively better. An illustrative numerical example is presented
for the proposed method.
[1] S. Abbasbandy, J. J. Nieto, M. Alavi, Tuning of reachable set in one
dimensional fuzzy differential inclusions, Chaos, Solitons & Fractals, 26
(2005), 1337-1341.
[2] M. F. Abbod, D. G. Von Keyserlingk, D. A. Linkens,M. Mahfouf, Survey
of utilisation of fuzzy technology in medicine and healthcare, Fuzzy Sets
and Systems, 120 (2001), 331-349.
[3] Albagul, Othman O. Khalifa, Wahyudi, Matlab and Simulink in Mechatranics,
Int. J. engng Ed., 21 (2005), 896-905.
[4] S. Barro, R. Mar'─▒n, Fuzzy logic in medicine, Heidelberg: Physica-Verlag,
2002.
[5] B. Bede, S. G. Gal, Almost periodic fuzzy number valued functions,
Fuzzy Sets and Systems, 147 (2004), 385-403.
[6] B. Bede, S. G. Gal, Generalizations of the differentiability of fuzzy
number valued functions with applications to fuzzy differential equations,
Fuzzy Sets and Systems, 151 (2005), 581-599.
[7] B. Bede, I. J. Rudas, A. L. Bencsik, First order linear fuzzy differential
equations under generalized differentiability, Inform. Sciences, 177
(2007), 1648-1662.
[8] Y. Chalco-Cano, H. Rom'an-Flores, On new solutions of fuzzy differential
equations, Chaos, Solitons & Fractals, 38 (2008), 112-119.
[9] D. P. Datta, The Golden mean, scale free extension of real number system,
fuzzy sets and 1/f spectrum in physics and biology, Chaos, Solitons &
Fractals, 17 (2003), 781-788.
[10] P. Diamond, Brief note on the variation of constants formula for fuzzy
differential equations, Fuzzy Sets and Systems, 129 (2002), 65-71.
[11] M. S. El Naschie, From experimental quantum optics to quantum gravity
via a fuzzy K¨ahler manifold, Chaos, Solitons & Fractals, 25 (2005), 969-
977.
[12] T. Gnana Bhaskar, V. Lakshmikantham, V. Devi, Revisiting fuzzy
differential equations, Nonlinear Analysis, 58 (2004), 351-358.
[13] M. Guo, X. Xue, R. Li, The oscillation of delay differential inclusions
and fuzzy biodynamics models, Math. Comput. Model., 37 (2003), 651-
658.
[14] M. Guo, R. Li, Impulsive functional differential inclusions and fuzzy
population models, Fuzzy Sets and Systems, 138 (2003), 601-615.
[15] M. Hanss, Applied fuzzy arithmetic: An introduction with engineering
applications, Springer-Verlag, Berlin, 2005.
[16] O. Kaleva, Fuzzy differential equations, Fuzzy Sets and Systems, 24
(1987), 301-317.
[17] O. Kaleva, A note on fuzzy differential equations, Nonlinear Analysis,
64 (2006), 895-900.
[18] J. J. Nieto, R. Rodr'─▒guez-L'opez, Bounded solutions for fuzzy differential
and integral equations, Chaos, Solitons & Fractals, 27 (2006), 1376-
1386.
[19] M. Puri, D. Ralescu, Differential and fuzzy functions, J. Math. Anal.
Appl., 91 (1983), 552-558.
[20] S. Song, Lei Guo, Chumbo Feng, Global existence of solutions to fuzzy
differential equations, Fuzzy Sets and Systems, 115 (2000), 371-376.
[21] S. Song, C. Wu, Existence and uniqueness of solutions to Cauchy
problem of fuzzy differential equations, Fuzzy Sets and Systems, 110
(2000), 55-67.
[22] C. X. Wu, S. Song, Stanley Lee, Approximate solutions, existence and
uniqueness of the Cauchy problem of fuzzy differential equations, J.
Math. Anal. Appl., 202 (1996), 629-644.
[23] C. X. Wu, S. Song, Existence theorem to the Cauchy problem of
fuzzy differential equations under compactness-type conditions, Inform.
Sciences, 108 (1998), 123-134.
[24] H. Zhang, X. Liao, J. Yu, Fuzzy modeling and synchronization of
hyperchaotic systems, Chaos, Solitons & Fractals, 26 (2005), 835-843.
[1] S. Abbasbandy, J. J. Nieto, M. Alavi, Tuning of reachable set in one
dimensional fuzzy differential inclusions, Chaos, Solitons & Fractals, 26
(2005), 1337-1341.
[2] M. F. Abbod, D. G. Von Keyserlingk, D. A. Linkens,M. Mahfouf, Survey
of utilisation of fuzzy technology in medicine and healthcare, Fuzzy Sets
and Systems, 120 (2001), 331-349.
[3] Albagul, Othman O. Khalifa, Wahyudi, Matlab and Simulink in Mechatranics,
Int. J. engng Ed., 21 (2005), 896-905.
[4] S. Barro, R. Mar'─▒n, Fuzzy logic in medicine, Heidelberg: Physica-Verlag,
2002.
[5] B. Bede, S. G. Gal, Almost periodic fuzzy number valued functions,
Fuzzy Sets and Systems, 147 (2004), 385-403.
[6] B. Bede, S. G. Gal, Generalizations of the differentiability of fuzzy
number valued functions with applications to fuzzy differential equations,
Fuzzy Sets and Systems, 151 (2005), 581-599.
[7] B. Bede, I. J. Rudas, A. L. Bencsik, First order linear fuzzy differential
equations under generalized differentiability, Inform. Sciences, 177
(2007), 1648-1662.
[8] Y. Chalco-Cano, H. Rom'an-Flores, On new solutions of fuzzy differential
equations, Chaos, Solitons & Fractals, 38 (2008), 112-119.
[9] D. P. Datta, The Golden mean, scale free extension of real number system,
fuzzy sets and 1/f spectrum in physics and biology, Chaos, Solitons &
Fractals, 17 (2003), 781-788.
[10] P. Diamond, Brief note on the variation of constants formula for fuzzy
differential equations, Fuzzy Sets and Systems, 129 (2002), 65-71.
[11] M. S. El Naschie, From experimental quantum optics to quantum gravity
via a fuzzy K¨ahler manifold, Chaos, Solitons & Fractals, 25 (2005), 969-
977.
[12] T. Gnana Bhaskar, V. Lakshmikantham, V. Devi, Revisiting fuzzy
differential equations, Nonlinear Analysis, 58 (2004), 351-358.
[13] M. Guo, X. Xue, R. Li, The oscillation of delay differential inclusions
and fuzzy biodynamics models, Math. Comput. Model., 37 (2003), 651-
658.
[14] M. Guo, R. Li, Impulsive functional differential inclusions and fuzzy
population models, Fuzzy Sets and Systems, 138 (2003), 601-615.
[15] M. Hanss, Applied fuzzy arithmetic: An introduction with engineering
applications, Springer-Verlag, Berlin, 2005.
[16] O. Kaleva, Fuzzy differential equations, Fuzzy Sets and Systems, 24
(1987), 301-317.
[17] O. Kaleva, A note on fuzzy differential equations, Nonlinear Analysis,
64 (2006), 895-900.
[18] J. J. Nieto, R. Rodr'─▒guez-L'opez, Bounded solutions for fuzzy differential
and integral equations, Chaos, Solitons & Fractals, 27 (2006), 1376-
1386.
[19] M. Puri, D. Ralescu, Differential and fuzzy functions, J. Math. Anal.
Appl., 91 (1983), 552-558.
[20] S. Song, Lei Guo, Chumbo Feng, Global existence of solutions to fuzzy
differential equations, Fuzzy Sets and Systems, 115 (2000), 371-376.
[21] S. Song, C. Wu, Existence and uniqueness of solutions to Cauchy
problem of fuzzy differential equations, Fuzzy Sets and Systems, 110
(2000), 55-67.
[22] C. X. Wu, S. Song, Stanley Lee, Approximate solutions, existence and
uniqueness of the Cauchy problem of fuzzy differential equations, J.
Math. Anal. Appl., 202 (1996), 629-644.
[23] C. X. Wu, S. Song, Existence theorem to the Cauchy problem of
fuzzy differential equations under compactness-type conditions, Inform.
Sciences, 108 (1998), 123-134.
[24] H. Zhang, X. Liao, J. Yu, Fuzzy modeling and synchronization of
hyperchaotic systems, Chaos, Solitons & Fractals, 26 (2005), 835-843.
@article{"International Journal of Engineering, Mathematical and Physical Sciences:63396", author = "N. Kumaresan and J. Kavikumar and Kuru Ratnavelu", title = "Simulink Approach to Solve Fuzzy Differential Equation under Generalized Differentiability", abstract = "In this paper, solution of fuzzy differential equation
under general differentiability is obtained by simulink. The simulink
solution is equivalent or very close to the exact solution of the
problem. Accuracy of the simulink solution to this problem is
qualitatively better. An illustrative numerical example is presented
for the proposed method.", keywords = "Fuzzy differential equation, Generalized differentiability,
H-difference and Simulink.", volume = "6", number = "4", pages = "487-4", }
