Metasurface-based all-optical diffractive convolutional neural networks
Abstract
The escalating energy demands and parallel-processing bottlenecks of electronic neural networks underscore the need for alternative computing paradigms. Optical neural networks, capitalizing on the inherent parallelism and speed of light propagation, present a compelling solution. Nevertheless, physically realizing convolutional neural network (CNN) components all-optically remains a significant challenge. To this end, we propose a metasurface-based all-optical diffractive convolutional neural network (MAODCNN) for computer vision tasks. This architecture synergistically integrates metasurface-based optical convolutional layers, which perform parallel convolution on the optical field, with cascaded diffractive neural networks acting as all-optical decoders. This co-design facilitates layer-wise feature extraction and optimization directly within the optical domain. Numerical simulations confirm that the fusion of convolutional and diffractive layers markedly enhances classification accuracy, a performance that scales with the number of diffractive layers. The MAODCNN framework establishes a viable foundation for practical all-optical CNNs, paving the way for high-efficiency, low-power optical computing in advanced pattern recognition.
Cite
@article{arxiv.2512.05558,
title = {Metasurface-based all-optical diffractive convolutional neural networks},
author = {Zhijiang Liang and Chenxuan Xiang and Shuyuan Xiao and Jumin Qiu and Jie Li and Qiegen Liu and Chengjun Zou and Tingting Liu},
journal= {arXiv preprint arXiv:2512.05558},
year = {2026}
}