Machine learning-based inverse design of auxetic metamaterial with zero Poisson's ratio

The inverse design from property to microstructure is more urgent in practical engineering than the regular design from microstructure to property. In this paper, a data-driven machine learning (ML) model based on the combination of artificial back-propagation neural network (BPNN) and genetic algorithm (GA) is developed for designing auxetic metamaterial with specific Poisson's ratio, i.e. zero Poisson’s ratio. Different to topology optimization, the ML model can optimize auxetic metamaterials with higher computational efficiency, lower requirement of deep knowledge of mathematics and physical model. In the ML model, the data set prepared by solving a large number of regular design problems using finite element simulation are used to train the BPNN to establish the underlying mapping relationships from the microstructure parameters to the Poisson’s ratio, and through which the GA optimization is conducted to globally seek optimal solution of the microstructure parameters related to the specific Poisson’s ratio. The effectiveness of the ML model is demonstrated by comparing to the tensile experiment and the finite element simulation of the structure designed with the given prediction. The results show the ML-based method offers an efficient pathway to design the microstructure of auxetic metamaterials with arbitrary specific Poisson’s ratio. [Display omitted] •The re-entrant model was studied using machine learning method.•The BPNN model was built for the prediction of structural Poisson's ratio.•The GA optimization integrating BPNN was performed for inverse design.•The accuracy of inverse design was verified by tension experiment.