English

A variational geometric framework for multi-objective level set topology optimization

Optimization and Control 2026-03-25 v1

Abstract

This paper proposes a variational framework for multi-objective level set topology optimization. The approach interprets the level set function as a generalized coordinate of a fictitious material and derives its equation of motion from Hamilton's principle, resulting in a damped wave equation governing the optimization process. The objective functionals are combined using a weighted sum formulation. An analysis of the underlying system structure reveals a geometric interpretation of the problem, shifting the perspective beyond conventional approaches based on purely discrete approximations of the Pareto frontier. Under suitable regularity assumptions, the set of stationary solutions forms a structured subset in objective space, in which the Pareto frontier is locally embedded and the weighting factors act as intrinsic coordinates. This perspective motivates the introduction of a dynamic evolution of the weights, leading to a coupled dynamical system for the level set function and the weighting parameters that enables adaptive exploration of the objective landscape. Numerical results demonstrate that the proposed framework provides a stable and uniform approximation of the Pareto frontier and scales to higher-dimensional objective spaces.

Keywords

Cite

@article{arxiv.2603.22739,
  title  = {A variational geometric framework for multi-objective level set topology optimization},
  author = {Jan Oellerich and Takayuki Yamada},
  journal= {arXiv preprint arXiv:2603.22739},
  year   = {2026}
}
R2 v1 2026-07-01T11:34:43.151Z