Robust geometry and topology optimization of plane frames using order statistics and force density method with global stability constraint

This paper presents a worst case approach for robust geometry and topology optimization of plane frames with global stability constraint. Uncertainty is assumed to exist in the nodal locations and cross‐sectional areas, and the worst values of the objective and stability constraint functions are rel...

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Bibliographic Details
Published in:International journal for numerical methods in engineering 2021-07, Vol.122 (14), p.3653-3677
Main Authors: Shen, Wei, Ohsaki, Makoto, Yamakawa, Makoto
Format: Article
Language:English
Subjects:
Confidence intervals
Density
force density method
Geometry
Nodes
Optimization
order statistics
plane frame
robust optimization
Robustness (mathematics)
stability constraint
Stiffness matrix
Topology optimization
Uncertainty
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Summary:This paper presents a worst case approach for robust geometry and topology optimization of plane frames with global stability constraint. Uncertainty is assumed to exist in the nodal locations and cross‐sectional areas, and the worst values of the objective and stability constraint functions are relaxed to the quantile structural responses represented by the order statistics with given robustness and confidence levels. In order to alleviate the difficulty caused by melting nodes to some extent, the force density method is applied to an auxiliary truss model for geometry optimization of the frame, and the closely spaced nodes are merged. A method is presented for generating correlated imperfections for the nodal locations along each member, and a penalization approach is proposed for geometrical stiffness matrix to exclude superficial local buckling. It is demonstrated in the numerical examples that the result of robust optimization obtained by the proposed method is less sensitive to the uncertainty, and the stability constraint is also satisfied under uncertainty with the specified robustness and confidence levels.
ISSN:0029-5981
1097-0207
DOI:10.1002/nme.6676