Exact Implementation of Multiple Initial Conditions in the DQ Solution of Higher-Order ODEs

  1. Young Researchers and Elite Club, Karaj Branch, Islamic Azad University

Revised: 2016-06-10

Accepted: 2016-08-10

Published in Issue 2016-09-20

How to Cite

Eftekhari, S. (2016). Exact Implementation of Multiple Initial Conditions in the DQ Solution of Higher-Order ODEs. Journal of Solid Mechanics, 8(4), 540-559. https://oiccpress.com/jsm/article/view/12549

PDF views: 151

Abstract

The differential quadrature method (DQM) is one of the most elegant and useful approximate methods for solving initial and/or boundary value problems. It is easy to use and also straightforward to implement. However, the conventional DQM is well-known to have some difficulty in implementing multiple initial and/or boundary conditions at a given discrete point. To overcome this difficulty, this paper presents a simple and accurate differential quadrature methodology in which the higher-order initial conditions are exactly implemented. The proposed methodology is very elegant and uses a set of simple polynomials with a simple transformation to incorporate the higher-order initial conditions at the initial discrete time point. The order of accuracy of the proposed method for solving an rth order ordinary differential equation is “m + r – 1,” where m being the number of discrete time points. This is better than the accuracy of the CBCGE (direct Coupling the Boundary/initial Conditions with the discrete Governing Equations) and MWCM (Modifying Weighting Coefficient Matrices) approaches whose order is in general “m – 1.” Some test problems are also provided to highlight the superiority of the proposed method over the CBCGE and MWCM approaches.