Meijun Qu;Kai Zhang;Jianxun Su;Ying Li;Li Deng;Xiuping Li
{"title":"用于绘制高分辨率、低噪声和均匀强度元表面全息图的增强型衍射神经网络","authors":"Meijun Qu;Kai Zhang;Jianxun Su;Ying Li;Li Deng;Xiuping Li","doi":"10.1109/TAP.2024.3460179","DOIUrl":null,"url":null,"abstract":"In this article, an enhanced diffractive neural network is proposed for achieving metasurface holograms with high resolution, low noise, and uniform intensity. First, we prove the feasibility of Rayleigh-Sommerfeld diffraction theory on a subwavelength scale. Based on this theory, the fully connected diffraction layer is constructed to build a high-resolution diffractive neural network (HR-DNN). Due to the capability of the diffraction layer in precisely manipulating subwavelength electromagnetic (EM) waves, high-resolution holographic imaging of complex patterns can be realized. In addition, a postprocessing method is particularly designed to separate clean target images from noisy holograms without reference assistance. The metrics, such as imaging efficiency (IE), peak signal-to-noise ratio (PSNR), and structural similarity (SSIM), are defined to estimate the imaging quality of the proposed HR-DNN-based holographic imaging system. Three types of complex patterns (airplane, phrase “WORLD PEACE 0921,” Olympic rings) are performed in the full-wave simulation, as well as the imaging results are highly recognizable with low-noise and uniform-intensity features. Compared with the weighted Gerchberg-Saxton (GS) algorithm, the proposed HR-DNN gains significant improvements in IE (241.6%), PSNR (45.6%), and SSIM (44.0%). Finally, a metasurface with \n<inline-formula> <tex-math>$30\\lambda \\times 30\\lambda $ </tex-math></inline-formula>\n based on 3-D printing technology is fabricated to image the Olympic rings. The measured results are in good agreement with the simulated and target ones. Therefore, the proposed HR-DNN can provide a pathway for high-resolution metasurface holograms.","PeriodicalId":13102,"journal":{"name":"IEEE Transactions on Antennas and Propagation","volume":"72 11","pages":"8600-8610"},"PeriodicalIF":4.6000,"publicationDate":"2024-09-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"An Enhanced Diffractive Neural Network for Metasurface Holograms With High Resolution, Low Noise, and Uniform Intensity\",\"authors\":\"Meijun Qu;Kai Zhang;Jianxun Su;Ying Li;Li Deng;Xiuping Li\",\"doi\":\"10.1109/TAP.2024.3460179\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"In this article, an enhanced diffractive neural network is proposed for achieving metasurface holograms with high resolution, low noise, and uniform intensity. First, we prove the feasibility of Rayleigh-Sommerfeld diffraction theory on a subwavelength scale. Based on this theory, the fully connected diffraction layer is constructed to build a high-resolution diffractive neural network (HR-DNN). Due to the capability of the diffraction layer in precisely manipulating subwavelength electromagnetic (EM) waves, high-resolution holographic imaging of complex patterns can be realized. In addition, a postprocessing method is particularly designed to separate clean target images from noisy holograms without reference assistance. The metrics, such as imaging efficiency (IE), peak signal-to-noise ratio (PSNR), and structural similarity (SSIM), are defined to estimate the imaging quality of the proposed HR-DNN-based holographic imaging system. Three types of complex patterns (airplane, phrase “WORLD PEACE 0921,” Olympic rings) are performed in the full-wave simulation, as well as the imaging results are highly recognizable with low-noise and uniform-intensity features. Compared with the weighted Gerchberg-Saxton (GS) algorithm, the proposed HR-DNN gains significant improvements in IE (241.6%), PSNR (45.6%), and SSIM (44.0%). Finally, a metasurface with \\n<inline-formula> <tex-math>$30\\\\lambda \\\\times 30\\\\lambda $ </tex-math></inline-formula>\\n based on 3-D printing technology is fabricated to image the Olympic rings. The measured results are in good agreement with the simulated and target ones. 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An Enhanced Diffractive Neural Network for Metasurface Holograms With High Resolution, Low Noise, and Uniform Intensity
In this article, an enhanced diffractive neural network is proposed for achieving metasurface holograms with high resolution, low noise, and uniform intensity. First, we prove the feasibility of Rayleigh-Sommerfeld diffraction theory on a subwavelength scale. Based on this theory, the fully connected diffraction layer is constructed to build a high-resolution diffractive neural network (HR-DNN). Due to the capability of the diffraction layer in precisely manipulating subwavelength electromagnetic (EM) waves, high-resolution holographic imaging of complex patterns can be realized. In addition, a postprocessing method is particularly designed to separate clean target images from noisy holograms without reference assistance. The metrics, such as imaging efficiency (IE), peak signal-to-noise ratio (PSNR), and structural similarity (SSIM), are defined to estimate the imaging quality of the proposed HR-DNN-based holographic imaging system. Three types of complex patterns (airplane, phrase “WORLD PEACE 0921,” Olympic rings) are performed in the full-wave simulation, as well as the imaging results are highly recognizable with low-noise and uniform-intensity features. Compared with the weighted Gerchberg-Saxton (GS) algorithm, the proposed HR-DNN gains significant improvements in IE (241.6%), PSNR (45.6%), and SSIM (44.0%). Finally, a metasurface with
$30\lambda \times 30\lambda $
based on 3-D printing technology is fabricated to image the Olympic rings. The measured results are in good agreement with the simulated and target ones. Therefore, the proposed HR-DNN can provide a pathway for high-resolution metasurface holograms.
期刊介绍:
IEEE Transactions on Antennas and Propagation includes theoretical and experimental advances in antennas, including design and development, and in the propagation of electromagnetic waves, including scattering, diffraction, and interaction with continuous media; and applications pertaining to antennas and propagation, such as remote sensing, applied optics, and millimeter and submillimeter wave techniques