An efficient coupling reduction model-based evolutionary topology optimization method

Expensive computational cost and zigzag structural topology hinder the applications of topology optimization in practical industry. In this paper, a coupling reduction model-based evolutionary topology (CRMETO) method is proposed to improve computational efficiency and obtain smooth boundary representation. In the proposed method, the coupling reduction model is based on the integration of high-fidelity multigrid conjugate gradient model and low-fidelity on-the-fly reduced order model. To further improve the efficiency, a relaxed updated strategy is put forward to reduce the number of evaluations of both low-fidelity and high-fidelity models. The proposed method is validated and compared with various 2D and 3D examples. With the increase in the scale of model, the advantage of the proposed method is much more obvious in terms of efficiency, the maximum speedup is up to 38.55 times in the given examples. Moreover, the memory also can be saved so that 3D problems with more than millions of degrees of freedom can be easily solved.

Automated summary

In this paper, a coupling reduction model-based evolutionary topology (CRMETO) method is proposed to improve the computational efficiency and obtain smooth boundary representation. By integrating high-fidelity multigrid conjugate gradient model and low-fidelity on-the-fly reduced order model, the coupling reduction model is used to reduce the computational complexity. The proposed method is validated and compared with various 2D and 3D examples, showing significant advantages in terms of efficiency as the model scale increases.