Topology optimization using immersed isogeometric analysis and its software implementation

•An adaptive IITO model is proposed with improved accuracy for trimmed elements.•Stiffness of active elements are explicitly computed by multi-level Bézier extraction operator.•Tensor decomposed implicit filter is applied to adaptive IITO with decoupled design mesh.•An independent object-oriented II...

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Bibliographic Details
Published in:Computer methods in applied mechanics and engineering 2024-12, Vol.432, p.117374, Article 117374
Main Authors: Xie, Xianda, Wang, Shuting, Xie, Qingtian, Liu, Can, Ren, Yuhang, Yang, Aodi
Format: Article
Language:English
Subjects:
Engineering software
Immersed boundary method
Isogeometric analysis
Topology optimization
Truncated hierarchical B-spline
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Summary:•An adaptive IITO model is proposed with improved accuracy for trimmed elements.•Stiffness of active elements are explicitly computed by multi-level Bézier extraction operator.•Tensor decomposed implicit filter is applied to adaptive IITO with decoupled design mesh.•An independent object-oriented IITO software system is developed by C++ language.•IITO software can implement the lightweight design of complex engineering structures effectively. This work integrates the immersed isogeometric analysis (IGA) with topology optimization (IITO), which paves the way of seamless integration between CAD and CAE as well as topology optimization for complex engineering structures. A truncated hierarchical B-spline (THB) based local adaptivity strategy is proposed to improve the integral accuracy of trimmed elements for immersed IGA, and an adaptive IITO framework is established in terms of the explicit elemental stiffness representation using multi-level Bézier extraction operator and tensor product decomposed implicit filter, as well as the suitably graded THB constraint. Numerical examples indicates that the proposed adaptive IITO method is superior to both traditional IITOs with adaptive Gaussian quadrature rule and successive global refinement, and achieves a sound balance between optimization accuracy and computation efficiency, irrespectively of the physical dimension and boundary conditions as well as geometry shape of design domain. Moreover, an object-oriented IITO engineering software is developed by C++ language and can be applied in engineering topology optimization design problems effectively, which show the superiorities of our IITO system. Therefore, the proposed IITO framework is a very promising way of implementing the seamless integration between CAD and CAE as well as topology optimization for complex engineering problems.
ISSN:0045-7825
DOI:10.1016/j.cma.2024.117374