Zhang, DiZhai, XiaoyaFu, Xiao-MingWang, HemingLiu, LigangUmetani, NobuyukiWojtan, ChrisVouga, Etienne2022-10-042022-10-0420221467-8659https://doi.org/10.1111/cgf.14698https://diglib.eg.org:443/handle/10.1111/cgf14698We propose a novel topology optimization method to efficiently minimize the maximum compliance for a high-resolution model bearing uncertain external loads. Central to this approach is a modified power method that can quickly compute the maximum eigenvalue to evaluate the worst-case compliance, enabling our method to be suitable for large-scale topology optimization. After obtaining the worst-case compliance, we use the adjoint variable method to perform the sensitivity analysis for updating the density variables. By iteratively computing the worst-case compliance, performing the sensitivity analysis, and updating the density variables, our algorithm achieves the optimized models with high efficiency. The capability and feasibility of our approach are demonstrated over various large-scale models. Typically, for a model of size 512×170×170 and 69934 loading nodes, our method took about 50 minutes on a desktop computer with an NVIDIA GTX 1080Ti graphics card with 11 GB memory.Keywords: Worst-case topology optimization, Displacement-oriented problem, Modified inverse power methodWorstcase topology optimizationDisplacementoriented problemModified inverse power methodLarge-Scale Worst-Case Topology Optimization10.1111/cgf.14698529-54012 pages