Journal Name:
- European Journal of Pure and Applied Mathematics
Publication Year:
- 2013
Key Words:
| Author Name | University of Author | Faculty of Author |
|---|---|---|
- 2
- English
REFERENCES
[1] J. Abouir, A. Cuyt, P. Gonzalez-Vera, and R. Orive. On the Convergence of General Order
Multivariate Padé-Type Approximants. Journal of Approximation Theory, 86:216–228,
1996.
[2] G. Adomian. A review of the decomposition method in applied mathematics. Fractional
Calculus and Applied Analysis, 135:501–544, 1988.
[3] G. Adomian. Solving Frontier Problems of Physics: The Decomposition Method. Kluwer
Academic Publishers, Boston, 1994.
[4] M. Caputo. Linear models of dissipation whose Q is almost frequency independent. part
II. Journal of the Royal Astronomical Society, 13:529–539, 1967.
[5] A. Cuyt. Multivariate Padé-approximant. Journal of Mathematical Analysis and Applications,
96:283–293, 1983.
[6] A. Cuyt. A review of multivariate Padé approximation theory. Journal of Computational
and Applied Mathematics, 12:221–232, 1985.
[7] A. Cuyt. How well can the concept of Padé approximant be generalized to the multivariate
case? Journal of Computational and Applied Mathematics, 105:25–50, 1985.
[8] A. Cuyt and L. Wuytack. Nonlinear Methods in Numerical Analysis. Elsevier Science
Publishers B.V, Amsterdam, 1987.
[9] A. Cuyt, L.Wuytack, and H.Werner. On the continuity of the multivariate Padé operator.
Journal of Computational and Applied Mathematics, 11:95–102, 1984.
[10] L. Debnath and D. Bhatta. Solutions to few linear fractional inhomogeneous partial differential
equations in fluid mechanics. Fractional Calculus and Applied Analysis, 7:153–
192, 2004.
[11] R. Gorenflo. Afterthoughts on interpretation of fractional derivatives and integrals. In
P. Rusev, I. Di-movski, and V. Kiryakovai, editors, Transform Methods and Special Functions,
pages 589–591, Sofia, 1998. Bulgarian Academy of Sciences, Institute of Mathematics
ands Informatics.
REFERENCES 169
[12] Ph. Guillaume and A. Huard. Multivariate Padé Approximants. Journal of Computational
and Applied Mathematics, 121:197–219, 2000.
[13] Ph. Guillaume, A. Huard, and V. Robin. Generalized Multivariate Padé Approximants.
Journal of Approximation Theory, 95:203–214, 1998.
[14] J.H. He. Semi-inverse method of establishing generalized principlies for fluid mechanics
with emphasis on turbomachinery aerodynamics. International Journal of Turbo and Jet
Engines, 14(1):23–28, 1997.
[15] J.H. He. Variational iteration method for delay differential equations. Communications
in Nonlinear Science and Numerical Simulation, 2(4):235–236, 1997.
[16] J.H. He. Approximate analytical solution for seepage flow with fractional derivatives
in porous media. Computer Methods in Applied Mechanics and Engineering, 167:57–68,
1998.
[17] J.H. He. Approximate solution of nonlinear differential equations with convolution
product nonlinearities. Computer Methods in Applied Mechanics and Engineering,
167:69–73, 1998.
[18] J.H. He. Nonlinear oscillation with fractional derivative and its applications. International
Conference on Vibrating Engineering ’98, pages 288–291, 1998.
[19] J.H. He. Some applications of nonlinear fractional differential equations and their approximations.
Bulletin of Science and Technology, 15(2):86–90, 1999.
[20] J.H. He. Variational iteration method – a kind of non-linear analytical technique: some
examples. International Journal of Non-Linear Mechanics, 34:699–708, 1999.
[21] J.H. He. Variational iteration method for autonomous ordinary differential systems.
Applied Mathematics and Computation, 114:115–123, 2000.
[22] J.H. He. Variational theory for linear magneto-electro-elasticity. International Journal
of Nonlinear Sciences and Numerical Simulation, 2(4):309–316, 2001.
[23] J.H. He. Variational principle for Nano thin film lubrication. International Journal of
Nonlinear Sciences and Numerical Simulation, 4(3):313–314, 2003.
[24] J.H. He. Variational principle for some nonlinear partial differential equations with
variable coefficients. Chaos Solitons and Fractals, 19(4):847–851, 2004.
[25] J.H. He. Variational iteration method: Some recent results and new interpretations.
Journal of Computational and Applied Mathematics, 207(1):3–17, 2007.
[26] J.H. He and X.H. Wu. Variational iteration method: New development and applications.
Computers and Mathematics with Applications, 54(7-8):881–894, 2007.
REFERENCES 170
[27] M. Inokuti, H. Sekine, and T. Mura. General use of the lagrange multiplier in non-linear
mathematical physics. In S. Nemat-Nasser, editor, Variational Method in the Mechanics
of Solids, pages 156–162, Oxford, 1978. Pergamon Press.
[28] A. Luchko and R. Groneflo. The initial value problem for some fractional differential
equations with the Caputo derivative. Preprint series A0–98, Fachbreich Mathematik und
Informatik, Freic Universitat Berlin, 1997.
[29] F. Mainardi. Fractional calculus: Some basic problems in continuum and statistical mechanics.
Springer-Verlag, New York, 1997.
[30] K.S. Miller and B. Ross. An Introduction to the Fractional Calculus and Fractional Differential
Equations. John Wiley and Sons, Inc, New York, 1993.
[31] S. Momani. An explicit and numerical solutions of the fractional KdV equation. Mathematics
and Computers in Simulation, 70(2):110–118, 2005.
[32] S. Momani. Non-perturbative analytical solutions of the space- and time-fractional Burgers
equations. Chaos, Solitons and Fractals, 28(4):930–937, 2006.
[33] S. Momani and S. Abuasad. Application of He’s variational iteration method to
Helmholtz equation. Chaos Solitons and Fractals, 27(5):1119–1123, 2006.
[34] S. Momani and Z. Odibat. Analytical approach to linear fractional partial differential
equations arising in fluild mechanics. Physics Letters A, 355:271–279, 2006.
[35] S. Momani and Z. Odibat. Analytical solution of a time-fractional Navier–Stokes
equation by Adomian decomposition method. Applied Mathematics and Computation,
177:488–494, 2006.
[36] S. Momani and Z. Odibat. Approximate solutions for boundary value problems of timefractional
wave equation. Applied Mathematics and Computation, 181:767–774, 2006.
[37] S. Momani and Z. Odibati. Numerical comparison of methods for solving linear differential
equations of fractional order. Chaos Solitons and Fractals, 31:1248–1255, 2007.
[38] S. Momani and R. Qaralleh. Numerical approximations and Padé approximants for a
fractional population growth model. Applied Mathematical Modelling, 31:1907–1914,
2007.
[39] S. Momani and N. Shawagfeh. Decomposition method for solving fractional Riccatti
differential equations. Applied Mathematics and Computation, 182:1083–1092, 2006.
[40] Z. Odibat and S. Momani. An explicit and numerical solutions of the fractional KdV
equation. International Journal of Nonlinear Sciences and Numerical Simulation, 7(1):15–
27, 2006.
REFERENCES 171
[41] Z. Odibat and S. Momani. Numerical methods for nonlinear differential equations of
fractional order. Applied Mathematical Modelling, 32:28–39, 2008.
[42] Z. Odibat and S. Momani. The variational iteration method: An efficient scheme for
handling fractional partial differential equations in fluid mechanics. Computers and
Mathematics with Applications, 58:2199–2208, 2009.
[43] K.B. Oldham and J. Spanier. The Fractional Calculus. Academic Press, New York, 1974.
[44] I. Podlubny. Fractional Differential Equations. Academic Press, New York, 1999.
[45] I. Podlubny. Geometric and physical interpretation of fractional integration and fractional
differentiation. Fractional Calculus and Applied Analysis, 5:367–386, 2002.
[46] A. Rèpaci. Nonlinear dynamical systems: On the accuracy of Adomian’s decomposition
method. Applied Mathematics Letters, 3(3):35–39, 1990.
[47] V. Turut, E. Celik, and M. Yigider. Multivariate Padé approximation for solving partial
differential equations (PDE). International Journal For Numerical Methods In Fluids,
66(9):1159–1173, 2011.
[48] A. Wazwaz. A new algorithm for calculating Adomian polynomials for nonlinear operators.
Applied Mathematics and Computation, 111:53–69, 2000.
[49] A. Wazwaz and S. El-Sayed. A new modification of the Adomian decomposition method
for linear and nonlinear operators. Applied Mathematics and Computation, 122:393–405,
2001.
[50] P. Zhou. Explicit construction of multivariate Padé approximants. Journal of Computational
and Applied Mathematics, 79:1–17, 1997.
[51] P. Zhou. Multivariate Padé Approximants Associated with Functional Relations. Journal
of Approximation Theory, 93:201–230, 1998.