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Main Authors: Zhang, Huanshu, Kang, Lei, Campbell, Sawyer D., Werner, Douglas H.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2509.24196
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author Zhang, Huanshu
Kang, Lei
Campbell, Sawyer D.
Werner, Douglas H.
author_facet Zhang, Huanshu
Kang, Lei
Campbell, Sawyer D.
Werner, Douglas H.
contents Traditional metasurface design is limited by the computational cost of full-wave simulations, preventing thorough exploration of complex configurations. Data-driven approaches have emerged as a solution to this bottleneck, replacing costly simulations with rapid neural network evaluations and enabling near-instant design for meta-atoms. Despite advances, implementing a new optical function still requires building and training a task-specific network, along with exhaustive searches for suitable architectures and hyperparameters. Pre-trained large language models (LLMs), by contrast, sidestep this laborious process with a simple fine-tuning technique. However, applying LLMs to the design of nanophotonic devices, particularly for arbitrarily shaped metasurfaces, is still in its early stages; as such tasks often require graphical networks. Here, we show that an LLM, fed with descriptive inputs of arbitrarily shaped metasurface geometries, can learn the physical relationships needed for spectral prediction and inverse design. We further benchmarked a range of open-weight LLMs and identified relationships between accuracy and model size at the billion-parameter level. We demonstrated that 1-D token-wise LLMs provide a practical tool to designing 2-D arbitrarily shaped metasurfaces. Linking natural-language interaction to electromagnetic modelling, this "chat-to-chip" workflow represents a step toward more user-friendly data-driven nanophotonics.
format Preprint
id arxiv_https___arxiv_org_abs_2509_24196
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Chat to Chip: Large Language Model Based Design of Arbitrarily Shaped Metasurfaces
Zhang, Huanshu
Kang, Lei
Campbell, Sawyer D.
Werner, Douglas H.
Optics
Artificial Intelligence
Traditional metasurface design is limited by the computational cost of full-wave simulations, preventing thorough exploration of complex configurations. Data-driven approaches have emerged as a solution to this bottleneck, replacing costly simulations with rapid neural network evaluations and enabling near-instant design for meta-atoms. Despite advances, implementing a new optical function still requires building and training a task-specific network, along with exhaustive searches for suitable architectures and hyperparameters. Pre-trained large language models (LLMs), by contrast, sidestep this laborious process with a simple fine-tuning technique. However, applying LLMs to the design of nanophotonic devices, particularly for arbitrarily shaped metasurfaces, is still in its early stages; as such tasks often require graphical networks. Here, we show that an LLM, fed with descriptive inputs of arbitrarily shaped metasurface geometries, can learn the physical relationships needed for spectral prediction and inverse design. We further benchmarked a range of open-weight LLMs and identified relationships between accuracy and model size at the billion-parameter level. We demonstrated that 1-D token-wise LLMs provide a practical tool to designing 2-D arbitrarily shaped metasurfaces. Linking natural-language interaction to electromagnetic modelling, this "chat-to-chip" workflow represents a step toward more user-friendly data-driven nanophotonics.
title Chat to Chip: Large Language Model Based Design of Arbitrarily Shaped Metasurfaces
topic Optics
Artificial Intelligence
url https://arxiv.org/abs/2509.24196