D*y(t) = f (t, y (t) , y (t *τ) , D*y(t), Dαy(t

Behrouz Parsa Moghaddam; Zeynab salamat Mostaghim

A Matrix Scheme Based on Fractional Finite Difference Method for Solving Fractional Delay Differential Equations with Boundary Values

Year 2015, Volume: 3 Issue: 2, 13 - 23, 19.01.2015

Behrouz Parsa Moghaddam Zeynab salamat Mostaghim

https://izlik.org/JA22KL73ZK

Abstract

In this paper, the method of fractional finite difference presents and used for solving a number of famous fractional orderversion of scientific models. The proposed method besides being simple is so exact which is sensible in the solved problems

Keywords

Finite difference method , Caputo derivative; Fractional delay differential equations; Boundary conditions

References

Averina V., Kolmanovsky I., Gibson A., Song G., Bueler E. Analysis and control of delay-dependent behavior of engine air-to-fuel ratio. Proceedings of 2005 IEEE Conference on Control Applications (CCA 2005) 28, 1222–1227.
Bhalekar S. Dynamical analysis of fractional order Ucar prototype delayed system. vol. 6. Springer Verlag London Limited;(2012) 513–
Comte F. Operateurs fractionnaires en econometrie et en finance. Prepubl. MAP5. 2001.
Fall C.P., Marland E.S., Wagner J.M., Tyson J.J. Computational cell biology. New York: Springer-Verlag; 2002.
Feliu V., Rivas R., Castillo F. Fractional order controller robust to time delay for water distribution in an irrigation main canal pool. Comput Electron Agric 69(2), (2009) 185–97.
Kilbas A. A., Srivastava H. M., Trujillo J. J. Theory and Applications of Fractional Differential Equations, in: N. – Holl. Math. Stud. vol. 204, Elsevier Sci. B. V, Amst. 2006.
Landry M., Campbell S., Morris K., Aguilar C. Dynamics of an inverted pendulum with delayed Control, SIAM J.Appl. Dyn. Syst. 4(2005), 333 - 351.
Magin R. l. Fractional calculus of complex dynamics in biological tissues, Comput. Math. Appl. 59(5) (2010) 1586 - 1593.
Moghaddam B. P., Mostaghim Z. S. A Numerical method based on finite difference for solving fractional delay differential equations, J. Taibah Univ. Sci. 7 (2013) 120-127.
Moghaddam B. P., Mostaghim Z. S. A Novel Matrix Approach to Fractional Finite Difference for solving Models Based on Nonlinear Fractional Delay Differential Equations, Ain Shams Engineering Journal 5 (2014), 585–594.
Murray JD. Mathematical biology I: an introduction, inter appl. mathematics, 3rd ed., vol. 17. Berlin: Springer; 2002.
Park H., Hong K. S. Boundary control of container cranes, Proc. SPIE, Vol. 6042, 604210 (2005).

Dy(t) = f (t, y (t) , y (t τ) , D*y(t), Dαy(t

Year 2015, Volume: 3 Issue: 2, 13 - 23, 19.01.2015

Behrouz Parsa Moghaddam Zeynab salamat Mostaghim

https://izlik.org/JA22KL73ZK

Abstract

References

Averina V., Kolmanovsky I., Gibson A., Song G., Bueler E. Analysis and control of delay-dependent behavior of engine air-to-fuel ratio. Proceedings of 2005 IEEE Conference on Control Applications (CCA 2005) 28, 1222–1227.
Bhalekar S. Dynamical analysis of fractional order Ucar prototype delayed system. vol. 6. Springer Verlag London Limited;(2012) 513–
Comte F. Operateurs fractionnaires en econometrie et en finance. Prepubl. MAP5. 2001.
Fall C.P., Marland E.S., Wagner J.M., Tyson J.J. Computational cell biology. New York: Springer-Verlag; 2002.
Feliu V., Rivas R., Castillo F. Fractional order controller robust to time delay for water distribution in an irrigation main canal pool. Comput Electron Agric 69(2), (2009) 185–97.
Kilbas A. A., Srivastava H. M., Trujillo J. J. Theory and Applications of Fractional Differential Equations, in: N. – Holl. Math. Stud. vol. 204, Elsevier Sci. B. V, Amst. 2006.
Landry M., Campbell S., Morris K., Aguilar C. Dynamics of an inverted pendulum with delayed Control, SIAM J.Appl. Dyn. Syst. 4(2005), 333 - 351.
Magin R. l. Fractional calculus of complex dynamics in biological tissues, Comput. Math. Appl. 59(5) (2010) 1586 - 1593.
Moghaddam B. P., Mostaghim Z. S. A Numerical method based on finite difference for solving fractional delay differential equations, J. Taibah Univ. Sci. 7 (2013) 120-127.
Moghaddam B. P., Mostaghim Z. S. A Novel Matrix Approach to Fractional Finite Difference for solving Models Based on Nonlinear Fractional Delay Differential Equations, Ain Shams Engineering Journal 5 (2014), 585–594.
Murray JD. Mathematical biology I: an introduction, inter appl. mathematics, 3rd ed., vol. 17. Berlin: Springer; 2002.
Park H., Hong K. S. Boundary control of container cranes, Proc. SPIE, Vol. 6042, 604210 (2005).

There are 12 citations in total.

Details

Authors	Behrouz Parsa Moghaddam This is me Zeynab salamat Mostaghim This is me
Publication Date	January 19, 2015
IZ	https://izlik.org/JA22KL73ZK
Published in Issue	Year 2015 Volume: 3 Issue: 2

Cite

APA	Moghaddam, B. P., & Mostaghim, Z. salamat. (2015). Dy(t) = f (t, y (t) , y (t τ) , Dy(t), Dαy(t. New Trends in Mathematical Sciences*, 3(2), 13-23. https://izlik.org/JA22KL73ZK
AMA	1.Moghaddam BP, Mostaghim Z salamat. Dy(t) = f (t, y (t) , y (t τ) , Dy(t), Dαy(t. New Trends in Mathematical Sciences*. 2015;3(2):13-23. https://izlik.org/JA22KL73ZK
Chicago	Moghaddam, Behrouz Parsa, and Zeynab salamat Mostaghim. 2015. “Dy(t) = F (t, Y (t) , Y (t τ) , Dy(t), Dαy(t”. New Trends in Mathematical Sciences* 3 (2): 13-23. https://izlik.org/JA22KL73ZK.
EndNote	Moghaddam BP, Mostaghim Z salamat (January 1, 2015) Dy(t) = f (t, y (t) , y (t τ) , D*y(t), Dαy(t. New Trends in Mathematical Sciences 3 2 13–23.
IEEE	[1]B. P. Moghaddam and Z. salamat Mostaghim, “Dy(t) = f (t, y (t) , y (t τ) , Dy(t), Dαy(t”, New Trends in Mathematical Sciences*, vol. 3, no. 2, pp. 13–23, Jan. 2015, [Online]. Available: https://izlik.org/JA22KL73ZK
ISNAD	Moghaddam, Behrouz Parsa - Mostaghim, Zeynab salamat. “Dy(t) = F (t, Y (t) , Y (t τ) , Dy(t), Dαy(t”. New Trends in Mathematical Sciences* 3/2 (January 1, 2015): 13-23. https://izlik.org/JA22KL73ZK.
JAMA	1.Moghaddam BP, Mostaghim Z salamat. Dy(t) = f (t, y (t) , y (t τ) , Dy(t), Dαy(t. New Trends in Mathematical Sciences*. 2015;3:13–23.
MLA	Moghaddam, Behrouz Parsa, and Zeynab salamat Mostaghim. “Dy(t) = F (t, Y (t) , Y (t τ) , Dy(t), Dαy(t”. New Trends in Mathematical Sciences*, vol. 3, no. 2, Jan. 2015, pp. 13-23, https://izlik.org/JA22KL73ZK.
Vancouver	1.Behrouz Parsa Moghaddam, Zeynab salamat Mostaghim. Dy(t) = f (t, y (t) , y (t τ) , D*y(t), Dαy(t. New Trends in Mathematical Sciences [Internet]. 2015 Jan. 1;3(2):13-2. Available from: https://izlik.org/JA22KL73ZK