DynNet: Physics-based neural architecture design for nonlinear structural response modeling and prediction

Data-driven models for predicting dynamic responses of linear and nonlinear systems are of great importance due to their wide application from probabilistic analysis to inverse problems such as system identification and damage diagnosis. In this study, a physics-based recurrent neural network model is designed that is able to estimate the dynamics of linear and nonlinear multiple degrees of freedom systems given the ground motions. The model is able to estimate a complete set of responses, including displacement, velocity, acceleration, and internal forces. Compared to the most advanced counterparts, this model requires smaller number of trainable variables while the accuracy of predictions is higher for long trajectories. In addition, the architecture of the recurrent block is inspired by differential equation solver algorithms and it is expected that this approach yields more generalized solutions. In the training phase, we propose multiple novel techniques to substantially accelerate the learning process using smaller datasets, such as hardsampling, utilization of a trajectory loss function, and implementation of a trust-region optimization approach. Numerical case studies are conducted to examine the strength of the network to learn different nonlinear behaviors. It is shown that the network is able to capture different nonlinear behaviors of dynamic systems with high accuracy and with no need for prior information or very large datasets.

Automated summary

A physics-based recurrent neural network model is proposed in this study to accurately estimate dynamic responses of linear and nonlinear multi-degree-of-freedom systems. Compared with other models, this model has higher accuracy and requires fewer trainable variables. Numerical case studies demonstrate the network's ability to learn different nonlinear behaviors of dynamic systems with high accuracy.