D. J. Zirra, Y. Skwame, John Sabo, J. Kwanamu, Silas Daniel
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引用次数: 0
摘要
本研究探讨了利用线性方程组法(LBA)求解高阶振荡微分方程的一般 K 步方程组法。研究还分析并满足了新方法的基本特性,如阶次、误差常数、零稳定性、一致性、收敛性、线性稳定性和绝对稳定区域。为了克服还原法在步长变化时的缺陷,一些明显的四阶振荡微分方程被直接应用于新方法。所获得的结果与文献中的结果进行了比较,新方法减轻了求解四阶振荡微分方程的负担。事实证明,新方法的精度优于现有方法。因此,从结果来看,新方法在图形上显示出更好的精度和更快的收敛速度。新方法的优点之一是不需要太多的计算负担,而且还能自启动。
On the Numerical Approximation of Higher Order Differential Equation
This research examines the general K - step block approach for solving higher order oscillatory differential equations using Linear Block Approach (LBA). The basic properties of the new method such as order, error constant, zero-stability, consistency, convergence, linear stability and region of absolute stability were also analyzed and satisfied. Some distinct fourth order oscillatory differential equation were directly applied on the new method in order to overcome the setbacks in reduction method, where the step size varies. The results obtained were compared with those in literature and the new method takes away the burden of solving fourth order oscillatory differential equations. The accuracy of the new method proved to be better as it outperformed those of existing methods. Therefore, from the results, the new method has shown better accuracy and faster convergence graphically. One of the advantage of the new method is that it does not require much computational burden and it is also self-starting.
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