Abstract
The evaluation of structural response constitutes a fundamental task in the design of ground-excited structures. In this context, the Monte Carlo simulation is a powerful tool to estimate the response statistics of nonlinear systems, which cannot be represented analytically. Unfortunately, the number of samples which is required for estimations with high confidence increases disproportionally to obtain a reliable estimation of low-probability events. As a consequence, the Monte Carlo simulation becomes a non-realizable task from a computational perspective. We show that the application of machine learning algorithms significantly lowers the computational burden of the Monte Carlo method. We use artificial neural networks to predict structural response behavior using supervised learning. However, one shortcoming of supervised learning is the inability of a sufficiently accurate prediction when extrapolating to data the neural network has not seen yet. In this paper, neural networks predict the response of structures subjected to non-stationary ground excitations. In doing so, we propose a novel selection process for the training data to provide the required samples to reliably predict rare events. We, finally, prove that the new strategy results in a significant improvement of the prediction of the response statistics in the tail end of the distribution.
Highlights
As engineers, we are responsible for the reliable design of structures and infrastructures
We focus on predicting the peak story drift ratio (PSDR) for the output instead of predicting the complete response time history
Using the new selection strategy, the predicted response statistics significantly improve in the tail region of the distribution
Summary
We are responsible for the reliable design of structures and infrastructures This task turns out to be challenging, especially when structures are supposed to withstand natural hazards, such as earthquakes. Structural failure should occur very rarely in order to save infrastructures and, human life so that the number of samples of the crude Monte Carlo method must be chosen high. On the one hand, measured earthquake acceleration data are limited and, on the other hand, experimental setups of such a high number of samples are not realizable. One strategy to overcome this problem is the realization of hybrid simulations [4]. This approach significantly decreases the costs, it is still inefficient to collect enough data for reliable Monte Carlo predictions of low failure probabilities
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