鬼影成像
光学
傅里叶变换
散射
管道(软件)
迭代重建
计算机科学
物理
图像复原
拉曼散射
信号(编程语言)
图像处理
点扩散函数
光散射
数字图像处理
信号处理
频域
光子计数
傅里叶光学
空间频率
杂散光
快速傅里叶变换
计算机视觉
重建算法
算法
图像形成
自适应光学
离散傅里叶变换(通用)
图像质量
人工智能
傅里叶级数
傅里叶分析
图像分辨率
时域
摄影术
光传递函数
材料科学
作者
Rehmat Iqbal,Jie Cao,Ayesha Abbas,Kai Lin,Qun Hao
出处
期刊:Applied Optics
[Optica Publishing Group]
日期:2025-10-15
卷期号:64 (32): 9553-9553
被引量:1
摘要
Remote-sensing applications within atmospheric scattering environments pose substantial challenges for traditional optical imaging systems owing to photon scattering, signal attenuation, and noise-induced degradation. This paper presents a ghost imaging technique operating in the Fourier domain, integrated with adaptive multistage post-processing enhancement algorithms to improve image reconstruction fidelity in the presence of scattering media. The experimental framework utilizes a digital micromirror device (DMD) to generate structured Fourier basis patterns in the reference arm, while the signal arm traverses controllable scattering media simulated using a precision-positioned ground glass (GG) diffuser. Image reconstruction is achieved through frequency-domain correlation processing employing a three-step phase-shifting algorithm, while reconstructed image degradation is mitigated through a multi-stage enhancement pipeline incorporating adaptive denoising, deblurring, and contrast optimization algorithms. Experimental validation demonstrates that the proposed methodology achieves recognizable image reconstruction using 25% of the Fourier coefficient set under high-scattering conditions, with enhancement algorithms providing up to 30% improvement in peak signal-to-noise ratio (PSNR) relative to unprocessed reconstructions. This investigation reveals fundamental limitations in dense scattering regimes and provides insights into the computational trade-offs inherent in ghost imaging systems under challenging environmental conditions.
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