Size, shape and topology optimization of truss structure via the finite particle method

•Finite Particle Method (FPM) is introduced into structural optimization.•A general structural sensitivity analysis procedure is proposed for structural optimization based on FPM.•The structural sensitivity formulation for static optimization of truss structure is derived.•Particle fusion and projec...

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Bibliographic Details
Published in:Computers & structures 2024-12, Vol.305, p.107570, Article 107570
Main Authors: Zhou, Jinhang, Zeng, Yan, Li, Gang
Format: Article
Language:English
Subjects:
Finite particle method
Sensitivity analysis
Structural optimization
Truss structure
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Summary:•Finite Particle Method (FPM) is introduced into structural optimization.•A general structural sensitivity analysis procedure is proposed for structural optimization based on FPM.•The structural sensitivity formulation for static optimization of truss structure is derived.•Particle fusion and projection strategies are specified for the optimization of truss structure. The finite particle method (FPM), a novel numerical analysis approach for simulating structural statics and dynamics, is introduced into the field of structural optimization through the development of a new structural sensitivity analysis procedure. Using FPM, we can analyze static and dynamic structural responses, including typical nonlinear behaviors, based on a system composed of a finite number of particles. The new sensitivity analysis procedure integrates seamlessly with the general time-difference scheme of FPM. In the initial application of this sensitivity analysis procedure, we focus on the static optimization of truss structures. Optimization strategies tailored to truss structures are developed by predicting static responses via FPM. The positions of improperly placed particles are adjusted through particle fusion and projection strategies to achieve a reasonable configuration, enabling collaborative size, shape, and topology optimization. Various 2D and 3D numerical examples demonstrate the effectiveness and efficiency of the static optimization framework, made possible by the new sensitivity analysis procedure and FPM.
ISSN:0045-7949
DOI:10.1016/j.compstruc.2024.107570