利用基于深度神经网络的去噪方法重建高光谱图像动态范围

IF 2.4 4区 计算机科学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Loran Cheplanov, Shai Avidan, David J. Bonfil, Iftach Klapp
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引用次数: 0

摘要

高光谱(HS)测量是农业领域早期疾病检测最有用的工具之一。然而,能够完成所需检测任务的高光谱相机成本高昂,通常需要五万到数十万美元。在以色列农业研究组织 Volcani 研究所之前进行的一项研究中,开发了一种低成本、高性能的 HS 系统,其中包括一个点光谱仪和光学元件。其主要缺点是每幅图像的拍摄时间较长。拍摄时间在很大程度上取决于点光谱仪的预定积分时间。虽然在合理的时间内执行监测任务非常重要,但将积分时间从 200 毫秒的典型值缩短到 10 毫秒范围内会导致拍摄场景的动态范围恶化。在这项工作中,我们建议通过学习从短积分时间测量的数据到长积分时间测量的数据之间的转换来纠正这种情况。以去噪自动编码器、DnCNN 和 LambdaNetworks 架构为骨干,利用开发的三种深度神经网络模型,成功克服了动态范围减小和随之而来的低信噪比问题。最好的模型是基于 DnCNN 的模型,在 20 个连续通道的图像上使用了 \(\ell _{2}\) 和 Kullback-Leibler 发散的组合损失函数。该模型的全光谱平均 PSNR 为 30.61,平均 SSIM 为 0.9,与 10 ms 测量值相比,平均 PSNR 和平均 SSIM 值分别提高了 60.43% 和 94.51%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Hyperspectral image dynamic range reconstruction using deep neural network-based denoising methods

Hyperspectral image dynamic range reconstruction using deep neural network-based denoising methods

Hyperspectral (HS) measurement is among the most useful tools in agriculture for early disease detection. However, the cost of HS cameras that can perform the desired detection tasks is prohibitive-typically fifty thousand to hundreds of thousands of dollars. In a previous study at the Agricultural Research Organization’s Volcani Institute (Israel), a low-cost, high-performing HS system was developed which included a point spectrometer and optical components. Its main disadvantage was long shooting time for each image. Shooting time strongly depends on the predetermined integration time of the point spectrometer. While essential for performing monitoring tasks in a reasonable time, shortening integration time from a typical value in the range of 200 ms to the 10 ms range results in deterioration of the dynamic range of the captured scene. In this work, we suggest correcting this by learning the transformation from data measured with short integration time to that measured with long integration time. Reduction of the dynamic range and consequent low SNR were successfully overcome using three developed deep neural networks models based on a denoising auto-encoder, DnCNN and LambdaNetworks architectures as a backbone. The best model was based on DnCNN using a combined loss function of \(\ell _{2}\) and Kullback–Leibler divergence on images with 20 consecutive channels. The full spectrum of the model achieved a mean PSNR of 30.61 and mean SSIM of 0.9, showing total improvement relatively to the 10 ms measurements’ mean PSNR and mean SSIM values by 60.43% and 94.51%, respectively.

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来源期刊
Machine Vision and Applications
Machine Vision and Applications 工程技术-工程:电子与电气
CiteScore
6.30
自引率
3.00%
发文量
84
审稿时长
8.7 months
期刊介绍: Machine Vision and Applications publishes high-quality technical contributions in machine vision research and development. Specifically, the editors encourage submittals in all applications and engineering aspects of image-related computing. In particular, original contributions dealing with scientific, commercial, industrial, military, and biomedical applications of machine vision, are all within the scope of the journal. Particular emphasis is placed on engineering and technology aspects of image processing and computer vision. The following aspects of machine vision applications are of interest: algorithms, architectures, VLSI implementations, AI techniques and expert systems for machine vision, front-end sensing, multidimensional and multisensor machine vision, real-time techniques, image databases, virtual reality and visualization. Papers must include a significant experimental validation component.
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