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Different Implementation Approaches of the Strong Form Meshless Implementation of Taylor Series Method

Year 2015, Volume: 1 Issue: 3, 95 - 105, 22.06.2015
https://doi.org/10.19072/ijet.68465

Abstract

Based on the Taylor series expansion (TSE) and employing the technique of differential transform method (DTM), three new meshless approaches which are called Meshless Implementation of Taylor Series Methods (MITSM) are presented. In particular, Strong Form Meshless Implementation of Taylor Series Methods (SMITSM) are studied in this paper.  Then, the basis functions are used to solve a 1D second-order ordinary differential equation and 2D Laplace equation by using the SMITSM. Comparisons are made with the analytical solutions and results of Symmetric Smoothed Particle Hydrodynamics (SSPH) method. We also compared the effectiveness of the SMITSM and SSPH method by considering various particle distributions, nonhomogeneous terms and number of terms in the basis functions. It is observed that the MITSM has the conventional convergence properties and, at the expense of CPU time, yields smaller L2 error norms than the SSPH method, especially in the existence of nonsmooth nonhomogeneous problems.

References

  • Lucy LB, A numerical approach to the testing of the fission hypothesis, Astron J, 82, 1013–1024, 1987.
  • Chen JK, Beraun JE, Jin CJ, An improvement for tensile instability in smoothed particle hydrodynamics, Comput Mech, 23, 279–287, 1999.
  • Chen JK, Beraun JE, Jin CJ, Completeness of corrective smoothed particlemethod for linear elastodynamics, Comput Mech, 24, 273–285, 1999.
  • Liu WK, Jun S, Zhang YF, Reproducing kernel particle methods, Int J Num Meth Fluids, 20, 1081–1106, 1995.
  • Liu WK, Jun S, Li S, Adee J, Belytschko T, Reproducing kernel particle methods for structural dynamics, Int J Num Meth Eng, 38, 1655–1679, 1995.
  • Chen JS, Pan C,Wu CT, Liu WK, Reproducing kernel particlemethods for large deformation analysis of non-linear structures, Comput Method Appl Mech Eng, 139, 195–227, 1996.
  • Zhang GM, Batra RC, Modified smoothed particle hydrodynamics method and its application to transient problems, Comput Mech, 34, 137–146, 2004.
  • Batra RC, Zhang GM, Analysis of adiabatic shear bands in elasto-thermo- viscoplastic materials by modified smoothedparticle hydrodynamics (MSPH) method, J Comput Phys, 201, 172–190, 2004.
  • Zhang GM, Batra RC, Wave propagation in functionally graded materials by modified smoothed particle hydrodynamics (MSPH) method, J Comput Phys, 222, 374–390, 2007.
  • Batra RC, Zhang GM, Search algorithm, and simulation of elastodynamic crack propagation by modified smoothed particle hydrodynamics (MSPH) method, Comput Mech, 40, 531–546, 2007.
  • Zhang GM, Batra RC, Symmetric smoothed particle hydrodynamics (SSPH) method and its application to elastic problems, Comput Mech, 43, 321-340, 2009.
  • Batra RC, Zhang GM, SSPH basis functions for meshless methods, and comparison of solutions with strong and weak formulations, Comput Mech, 41, 527-545, 2008.
  • Karamanli A, Mugan A, Solutions of two–dimensional heat transfer problems by using symmetric smoothed particle hydrodynamics method, Journal of Applied and Computational Mathematics, 1, 1-6, 2012.
  • Karamanli A, Mugan A, Strong from meshless implementation of Taylor series method, Appl. Math. Comput, 219, 9069-9080, 2013.
  • Bervillier C, Status of the differential transformation method, Appl. Math. Comput, 218, ,10158-10170, 2012.
  • Liu H, Song Y, Differential transform method applied to high index differential–algebraic equations, App Math Comput, 184, 748-753, 2007.
  • Ayaz F, Solutions of the system of differential equations by differential transform method, App Math Comput, 147, 547-567, 2004.
  • Yalcin HS, Arikoglu A, Ozkol I, Free vibration analysis of circular plates by differential transform method, App Math Comput, 212, 377-386, 2009.
  • Arikoglu A, Ozkol I, Solution of differential-difference equations by using differential transform method, App Math Comput, 181, 153-162, 2006.
  • Arikoglu A, Ozkol I, Solution of difference equations by using differential transform method, App Math Comput, 174, 1216-1228, 2006.
  • Arikoglu A, Ozkol I, Solution of boundary value problems for integro differential equations by using differential transform method, App Math Comput, 168, 1145-1158, 2005.
Year 2015, Volume: 1 Issue: 3, 95 - 105, 22.06.2015
https://doi.org/10.19072/ijet.68465

Abstract

References

  • Lucy LB, A numerical approach to the testing of the fission hypothesis, Astron J, 82, 1013–1024, 1987.
  • Chen JK, Beraun JE, Jin CJ, An improvement for tensile instability in smoothed particle hydrodynamics, Comput Mech, 23, 279–287, 1999.
  • Chen JK, Beraun JE, Jin CJ, Completeness of corrective smoothed particlemethod for linear elastodynamics, Comput Mech, 24, 273–285, 1999.
  • Liu WK, Jun S, Zhang YF, Reproducing kernel particle methods, Int J Num Meth Fluids, 20, 1081–1106, 1995.
  • Liu WK, Jun S, Li S, Adee J, Belytschko T, Reproducing kernel particle methods for structural dynamics, Int J Num Meth Eng, 38, 1655–1679, 1995.
  • Chen JS, Pan C,Wu CT, Liu WK, Reproducing kernel particlemethods for large deformation analysis of non-linear structures, Comput Method Appl Mech Eng, 139, 195–227, 1996.
  • Zhang GM, Batra RC, Modified smoothed particle hydrodynamics method and its application to transient problems, Comput Mech, 34, 137–146, 2004.
  • Batra RC, Zhang GM, Analysis of adiabatic shear bands in elasto-thermo- viscoplastic materials by modified smoothedparticle hydrodynamics (MSPH) method, J Comput Phys, 201, 172–190, 2004.
  • Zhang GM, Batra RC, Wave propagation in functionally graded materials by modified smoothed particle hydrodynamics (MSPH) method, J Comput Phys, 222, 374–390, 2007.
  • Batra RC, Zhang GM, Search algorithm, and simulation of elastodynamic crack propagation by modified smoothed particle hydrodynamics (MSPH) method, Comput Mech, 40, 531–546, 2007.
  • Zhang GM, Batra RC, Symmetric smoothed particle hydrodynamics (SSPH) method and its application to elastic problems, Comput Mech, 43, 321-340, 2009.
  • Batra RC, Zhang GM, SSPH basis functions for meshless methods, and comparison of solutions with strong and weak formulations, Comput Mech, 41, 527-545, 2008.
  • Karamanli A, Mugan A, Solutions of two–dimensional heat transfer problems by using symmetric smoothed particle hydrodynamics method, Journal of Applied and Computational Mathematics, 1, 1-6, 2012.
  • Karamanli A, Mugan A, Strong from meshless implementation of Taylor series method, Appl. Math. Comput, 219, 9069-9080, 2013.
  • Bervillier C, Status of the differential transformation method, Appl. Math. Comput, 218, ,10158-10170, 2012.
  • Liu H, Song Y, Differential transform method applied to high index differential–algebraic equations, App Math Comput, 184, 748-753, 2007.
  • Ayaz F, Solutions of the system of differential equations by differential transform method, App Math Comput, 147, 547-567, 2004.
  • Yalcin HS, Arikoglu A, Ozkol I, Free vibration analysis of circular plates by differential transform method, App Math Comput, 212, 377-386, 2009.
  • Arikoglu A, Ozkol I, Solution of differential-difference equations by using differential transform method, App Math Comput, 181, 153-162, 2006.
  • Arikoglu A, Ozkol I, Solution of difference equations by using differential transform method, App Math Comput, 174, 1216-1228, 2006.
  • Arikoglu A, Ozkol I, Solution of boundary value problems for integro differential equations by using differential transform method, App Math Comput, 168, 1145-1158, 2005.
There are 21 citations in total.

Details

Primary Language English
Journal Section Makaleler
Authors

Armagan Karamanli

Publication Date June 22, 2015
Published in Issue Year 2015 Volume: 1 Issue: 3

Cite

APA Karamanli, A. (2015). Different Implementation Approaches of the Strong Form Meshless Implementation of Taylor Series Method. International Journal of Engineering Technologies IJET, 1(3), 95-105. https://doi.org/10.19072/ijet.68465
AMA Karamanli A. Different Implementation Approaches of the Strong Form Meshless Implementation of Taylor Series Method. IJET. September 2015;1(3):95-105. doi:10.19072/ijet.68465
Chicago Karamanli, Armagan. “Different Implementation Approaches of the Strong Form Meshless Implementation of Taylor Series Method”. International Journal of Engineering Technologies IJET 1, no. 3 (September 2015): 95-105. https://doi.org/10.19072/ijet.68465.
EndNote Karamanli A (September 1, 2015) Different Implementation Approaches of the Strong Form Meshless Implementation of Taylor Series Method. International Journal of Engineering Technologies IJET 1 3 95–105.
IEEE A. Karamanli, “Different Implementation Approaches of the Strong Form Meshless Implementation of Taylor Series Method”, IJET, vol. 1, no. 3, pp. 95–105, 2015, doi: 10.19072/ijet.68465.
ISNAD Karamanli, Armagan. “Different Implementation Approaches of the Strong Form Meshless Implementation of Taylor Series Method”. International Journal of Engineering Technologies IJET 1/3 (September 2015), 95-105. https://doi.org/10.19072/ijet.68465.
JAMA Karamanli A. Different Implementation Approaches of the Strong Form Meshless Implementation of Taylor Series Method. IJET. 2015;1:95–105.
MLA Karamanli, Armagan. “Different Implementation Approaches of the Strong Form Meshless Implementation of Taylor Series Method”. International Journal of Engineering Technologies IJET, vol. 1, no. 3, 2015, pp. 95-105, doi:10.19072/ijet.68465.
Vancouver Karamanli A. Different Implementation Approaches of the Strong Form Meshless Implementation of Taylor Series Method. IJET. 2015;1(3):95-105.

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