📝 SummarXiv

Abstract

Solving dynamic topology optimization problems often yields low-performing local optima. Instead of converging towards a design that exploits dynamic mechanisms, a less interesting, mass-driven solution is often generated. This necessitates repeated and computationally expensive optimization reruns before a suitable optimum is found. In this work, an overview of three strategy classes that reduce the need for such reruns is presented: exclusion strategies, frequency shift methods and relaxation strategies. Novel variants for each strategy class are developed, implemented and compared via Monte Carlo sampling on a benchmark problem, namely the sound transmission loss optimization of a sandwich panel. Probabilities of achieving high-performing optima are estimated and all investigated strategies demonstrate quantifiable improvements and trade-offs. The study offers furthermore a quantitative comparison of the presented strategies, supporting researchers in making an informed choice when addressing convergence to poor local optima in dynamic topology optimization.