The SiMPL Method for Multi-Material Topology Optimization

TL;DR

The paper presents a scalable density-based multi-material topology optimization method that integrates mirror descent with convex polytope constraints, ensuring feasible designs and efficient convergence.

Contribution

It introduces a novel Bregman divergence-based framework that enforces point-wise convex constraints and easily incorporates global constraints in multi-material topology optimization.

Findings

Demonstrates robustness and efficiency in structural design problems.

Validates the method on isotropic, anisotropic, and magnetic flux optimization cases.

Abstract

We introduce an efficient and scalable method for density-based multi-material topology optimization, integrating classical mirror descent techniques with point-wise polytopal design constraints. Such constraints arise naturally in this class of problems, wherein the vertices of convex polytopes correspond to distinct design states, only one of which should be occupied at each point in space. The framework generates a descending sequence of iterates by penalizing the design space around the previous iterate with a generalized distance function tailored to the convex geometry of the $n$-dimensional polytope. This distance function, called a Bregman divergence, smooths the optimization landscape, ensuring that each iterate strictly satisfies the point-wise constraints. Subsequently, global constraints (e.g., bounds on the structural mass) can be enforced easily by solving a small, finite-dimensional dual problem. The resulting method is simple to implement and demonstrates robustness and efficiency when combined with an Armijo-type line search algorithm. We validate the method in structural design problems involving the optimal arrangement of both isotropic and anisotropic materials, as well as magnetic flux optimization in electric motors.