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Auteurs principaux: Xiong, JunYi, Su, Can, Wang, ZhiYuan, Xiong, YangYang, Wang, HongJie, Cai, MengQiang, Cao, GuiYuan, Deng, XioaHua, Nie, ZhongQuan, Yan, WeiChao, Jia, BaoHua
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2504.21290
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author Xiong, JunYi
Su, Can
Wang, ZhiYuan
Xiong, YangYang
Wang, HongJie
Cai, MengQiang
Cao, GuiYuan
Deng, XioaHua
Nie, ZhongQuan
Yan, WeiChao
Jia, BaoHua
author_facet Xiong, JunYi
Su, Can
Wang, ZhiYuan
Xiong, YangYang
Wang, HongJie
Cai, MengQiang
Cao, GuiYuan
Deng, XioaHua
Nie, ZhongQuan
Yan, WeiChao
Jia, BaoHua
contents Single-pixel imaging (SPI) has offered an unprecedented technique for capturing a targeted scenes without requiring either raster-scanned systems or muti-pixel detectors. However, in the current research, there are rare study reports about achieving both high spatial quality and low sampling ratio below 5% without additional algorithms in the existing SPI architectures. To circumvent these challenges, here we demonstrate a novel Laguerre Gaussian single-pixel imaging (LGSI) technique achieving ultra-low sampling ratio (3%) and super-high spatial imaging quality (Structural Similarity (SSIM) of 0.739 and a peak signal-to-noise ratio (PSNR) of 20.762 dB). The fundamental methodology relies on the enhancement of the encoded patterns by the differential modulation of discrete orthogonal physical LG moments, enabling the reconstruction of illuminated target object via a linear weighting of the structured light intensity. Leveraging this orthogonal mechanism, LGSI demonstrates superior imaging quality and computational efficiency, surpassing the capabilities of non-orthogonal moments. Comparative analyses of the power spectra from reconstructed images highlight the enhanced efficacy of LGSI over Hadamard SPI (HSI) and Fourier SPI (FSI). Our results suggest the possibility of encoding multi-dimensional structured light fields as a promising pathway for realizing low sampling ratio, universal, and physical-endow SPI.
format Preprint
id arxiv_https___arxiv_org_abs_2504_21290
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle High-Fidelity Single-Pixel Imaging at Ultra-Low Sampling Ratios via Physically Enhanced Laguerre Gaussian Encoding
Xiong, JunYi
Su, Can
Wang, ZhiYuan
Xiong, YangYang
Wang, HongJie
Cai, MengQiang
Cao, GuiYuan
Deng, XioaHua
Nie, ZhongQuan
Yan, WeiChao
Jia, BaoHua
Optics
Single-pixel imaging (SPI) has offered an unprecedented technique for capturing a targeted scenes without requiring either raster-scanned systems or muti-pixel detectors. However, in the current research, there are rare study reports about achieving both high spatial quality and low sampling ratio below 5% without additional algorithms in the existing SPI architectures. To circumvent these challenges, here we demonstrate a novel Laguerre Gaussian single-pixel imaging (LGSI) technique achieving ultra-low sampling ratio (3%) and super-high spatial imaging quality (Structural Similarity (SSIM) of 0.739 and a peak signal-to-noise ratio (PSNR) of 20.762 dB). The fundamental methodology relies on the enhancement of the encoded patterns by the differential modulation of discrete orthogonal physical LG moments, enabling the reconstruction of illuminated target object via a linear weighting of the structured light intensity. Leveraging this orthogonal mechanism, LGSI demonstrates superior imaging quality and computational efficiency, surpassing the capabilities of non-orthogonal moments. Comparative analyses of the power spectra from reconstructed images highlight the enhanced efficacy of LGSI over Hadamard SPI (HSI) and Fourier SPI (FSI). Our results suggest the possibility of encoding multi-dimensional structured light fields as a promising pathway for realizing low sampling ratio, universal, and physical-endow SPI.
title High-Fidelity Single-Pixel Imaging at Ultra-Low Sampling Ratios via Physically Enhanced Laguerre Gaussian Encoding
topic Optics
url https://arxiv.org/abs/2504.21290