What question did this study set out to answer?

The aim is to enhance topology optimization methods by integrating multifidelity analyses with topological derivatives.

May 20, 2026

Developmental Approach for Topology Optimization via Multifidelity Analyses and Topological Derivative

Key Points

The aim is to enhance topology optimization methods by integrating multifidelity analyses with topological derivatives.
Extended a two-point topological derivative approach to multifidelity modeling.
Implemented the cellular division method for topological design in benchmark test cases.
Utilized gradient-based optimization to manage multidisciplinary responses.
Achieved superior optimization results in benchmark cases using the multifidelity approach.
Demonstrated effective handling of the curse of dimensionality in discrete topological design.
Provided a framework to improve structural design processes in additive manufacturing.

Abstract

A recent tractable gradient-based approach that exploits a new two-point topological derivative is extended here to encompass multifidelity modeling. Handling multidisciplinary responses during structural topology optimization is important to a field that has grown rapidly in the last decade, spurred by additive manufacturing. The cellular division method for topological design is more general than conventional optimality criterion methods used most often in industrial structural topology design; however, it is a discrete approach that is daunting without topological derivatives, due to the curse of dimensionality. Results are presented to address that issue for benchmark test cases using the multifidelity approach with two-point topological derivatives to drive cellular development.

Bookmark

Developmental Approach for Topology Optimization via Multifidelity Analyses and Topological Derivative

Key Points

Abstract

Cite This Study