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Main Authors: Grand, Mathys Le, Urard, Pascal, Rideau, Denis, Trémas, Loumi, Maitre, Damien, Fuchs, Adam, Fernandez-Mouron, Louis-Henri, Orobtchouk, Régis
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.06605
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author Grand, Mathys Le
Urard, Pascal
Rideau, Denis
Trémas, Loumi
Maitre, Damien
Fuchs, Adam
Fernandez-Mouron, Louis-Henri
Orobtchouk, Régis
author_facet Grand, Mathys Le
Urard, Pascal
Rideau, Denis
Trémas, Loumi
Maitre, Damien
Fuchs, Adam
Fernandez-Mouron, Louis-Henri
Orobtchouk, Régis
contents Metasurface inverse design is challenged by the intricate relationship between structural parameters and electromagnetic responses, as well as the high dimensionality of the optimization space. Local models, while commonly employed, quickly become infeasible for complex and locally coupled structures. Conventional iterative optimization techniques, on the other hand, are computationally intensive, time-consuming, and susceptible to convergence in local minima. This study explores a versatile generative methodology based on enhanced posterior sampling within the Schrödinger Bridge framework. By decomposing posterior sampling into amplitude and directional contributions, we effectively integrated different kind of posterior sampling. This approach is further supported by refined training strategies to enhance performance and reduce the complexity of hyperparameter optimization. The proposed framework demonstrates exceptional accuracy and robustness, representing a significant advancement in metasurface design. Notably, it enables high-precision inverse design for large-scale configurations of up to $350 \times 350$ pillar arrays, despite being trained on significantly smaller arrays of $23 \times 23$ pillars.
format Preprint
id arxiv_https___arxiv_org_abs_2602_06605
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Diffusion Schrödinger Bridges with enhanced posterior sampling for metasurface inverse design
Grand, Mathys Le
Urard, Pascal
Rideau, Denis
Trémas, Loumi
Maitre, Damien
Fuchs, Adam
Fernandez-Mouron, Louis-Henri
Orobtchouk, Régis
Optics
Metasurface inverse design is challenged by the intricate relationship between structural parameters and electromagnetic responses, as well as the high dimensionality of the optimization space. Local models, while commonly employed, quickly become infeasible for complex and locally coupled structures. Conventional iterative optimization techniques, on the other hand, are computationally intensive, time-consuming, and susceptible to convergence in local minima. This study explores a versatile generative methodology based on enhanced posterior sampling within the Schrödinger Bridge framework. By decomposing posterior sampling into amplitude and directional contributions, we effectively integrated different kind of posterior sampling. This approach is further supported by refined training strategies to enhance performance and reduce the complexity of hyperparameter optimization. The proposed framework demonstrates exceptional accuracy and robustness, representing a significant advancement in metasurface design. Notably, it enables high-precision inverse design for large-scale configurations of up to $350 \times 350$ pillar arrays, despite being trained on significantly smaller arrays of $23 \times 23$ pillars.
title Diffusion Schrödinger Bridges with enhanced posterior sampling for metasurface inverse design
topic Optics
url https://arxiv.org/abs/2602.06605