Abstract
Dynamic relaxation (DR) is a widely used numerical method to determine the static equilibrium of a dynamic system. However, it is difficult to apply conventional DR methods to nonlinear models because they require estimation of a stiffness matrix of the model. To resolve the forementioned problem, a new dynamic relaxation method using continuous kinetic damping (CKDR) was proposed in previous research. The CKDR method does not require any model parameters including the stiffness matrix, and it possesses absolute stability and a second-order convergence rate. However, the convergence rate is proportional to square of the step size, and this may result in a low convergence rate if the selected step size is excessively small. This problem leads to difficulties in the practical use of CKDR. Thus, an adaptive step-size method is proposed in this paper to control the convergence rate of CKDR. The proposed method estimates natural frequency of the model and determines adaptive step size. Static equilibrium simulations were performed for three different models to verify the method. The results revealed that the computational cost of CKDR with a variable step size was very efficient when compared to fixed step sizes and that the convergence rate was also controlled as intended. In addition, the lowest natural frequencies of models in static equilibrium were accurately estimated.
Highlights
Dynamic relaxation (DR) is the most widely used approach for static equilibrium analyses
The DR method basically compels the dynamic system to converge to a static equilibrium through the application of fictitious damping
The kinetic damping in KDR is applied by resetting the velocity to zero when each kinetic energy peak occurs. This discontinuous procedure makes it difficult to predict the convergence rate and stability of KDR. These conventional DR methods require the estimation of a stiffness matrix of the model, and, it is difficult to apply these methods to nonlinear models
Summary
Dynamic relaxation (DR) is the most widely used approach for static equilibrium analyses. The DR method basically compels the dynamic system to converge to a static equilibrium through the application of fictitious damping. Dynamic relaxation with kinetic damping (KDR) is a widely used method proposed in a study by Cundall [8]. The kinetic damping in KDR is applied by resetting the velocity to zero when each kinetic energy peak occurs This discontinuous procedure makes it difficult to predict the convergence rate and stability of KDR. To resolve the aforementioned problem, a new dynamic relaxation method using continuous kinetic damping (CKDR) is proposed in the previous research [9].
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