Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Abstract This paper presents a finite element scheme for analyzing the dynamic response of the saturated poroelastic media. The proposed scheme employs the standard finite element method for space domain discretization of the dynamic u-p equation system. We introduce the precise time step integration method as an explicit, direct integration algorithm for handling the time derivatives. The spectral radius analysis, the error and convergence analysis show that the proposed scheme is unconditionally stable as well as convergent with numerical solutions that are of any order accuracy to exact solutions. Compared with the Newmark scheme, the advantages of the proposed scheme are demonstrated by simulating five examples in both one- and two-dimensions. The proposed scheme yields high-precision results and exhibits good adaptability under large time step size, which remarkably outperforms the Newmark scheme.
Highlights Precise time step integration method is introduced to perform dynamic analysis of the saturated poroelastic media. The Routh-Hurwitz criterion is applied to examine the stability of the proposed scheme. Five numerical models are analyzed to validate the proposed scheme.
Abstract This paper presents a finite element scheme for analyzing the dynamic response of the saturated poroelastic media. The proposed scheme employs the standard finite element method for space domain discretization of the dynamic u-p equation system. We introduce the precise time step integration method as an explicit, direct integration algorithm for handling the time derivatives. The spectral radius analysis, the error and convergence analysis show that the proposed scheme is unconditionally stable as well as convergent with numerical solutions that are of any order accuracy to exact solutions. Compared with the Newmark scheme, the advantages of the proposed scheme are demonstrated by simulating five examples in both one- and two-dimensions. The proposed scheme yields high-precision results and exhibits good adaptability under large time step size, which remarkably outperforms the Newmark scheme.
Highlights Precise time step integration method is introduced to perform dynamic analysis of the saturated poroelastic media. The Routh-Hurwitz criterion is applied to examine the stability of the proposed scheme. Five numerical models are analyzed to validate the proposed scheme.
An unconditionally stable and high-accuracy finite element scheme for dynamic analysis of saturated poroelastic media
08.05.2020
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch