Enhanced posterior sampling via diffusion models for efficient metasurfaces inverse design

Abstract

The inverse design of metasurfaces faces inherent challenges due to the nonlinear and highly complex relationship between geometric configurations and their electromagnetic behavior. Traditional optimization approaches often suffer from excessive computational demands and a tendency to converge to suboptimal solutions. This study presents a diffusion-based generative framework that incorporates a dedicated consistency constraint and advanced posterior sampling methods to ensure adherence to desired electromagnetic specifications. Through rigorous validation on small-scale metasurface configurations, the proposed approach demonstrates marked enhancements in both accuracy and reliability of the generated designs. Furthermore, we introduce a scalable methodology that extends inverse design capabilities to large-scale metasurfaces, validated for configurations of up to 98 × 98 nanopillars. Notably, this approach enables rapid design generation completed in minute by leveraging models trained on substantially smaller arrays (23 × 23). These innovations establish a robust and efficient framework for high-precision metasurface inverse design.