Investigation of Fusarium damage in wheat using hyperspectral imaging: An independent component analysis approach

IF 1.6 4区化学 Q3 CHEMISTRY, APPLIED

Journal of Near Infrared Spectroscopy Pub Date : 2023-09-26 DOI:10.1177/09670335231202258

Mohammad Nadimi, Fernando AM Saccon, Ahmed Elrewainy, Dennis Parcey, Sherif S Sherif, Jitendra Paliwal

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引用次数: 0

Abstract

With the continuously growing world population in the 21st century, the agri-food industry is in dire need of adopting rapid, eco-friendly, and reliable technologies to improve the quantity, quality, and safety of agri-food products to fulfill the world's future food needs. Hyperspectral imaging (HSI), a technique to glean a sample's spectral and spatial information, is an emerging non-destructive technique that can characterize the quality parameters of agri-food products such as Fusarium damage. Despite its vast potential, HSI systems suffer from enormous data sizes, requiring high computational time and power. One potential solution to overcome the aforementioned challenge is to reduce the data size by removing redundant information. However, detecting small optimum features from a large dataset is not trivial. To this end, an exploratory novel HSI data reduction and analysis technique was investigated and validated to identify Fusarium damage in wheat kernels. Wheat samples at three moisture contents (19, 27, and 35%, wet basis) and seven infection levels (ranging from 0 to 56 days after infection) were imaged at 256 equally spaced wavelengths from 820 to 1666 nm. Firstly, complete HSI data was utilized to successfully characterize sound and Fusarium-damaged wheat kernels using independent component analysis (ICA) algorithm. Then, a genetic algorithm optimization approach was used to reduce the data to ten wavelengths for ICA-based analysis. This data reduction approach reduced the computation time to approximately 1.31% of the original time taken for analyzing the full HSI data without compromising the performance of the system. This preliminary study suggests that such wavelength tailoring could reduce the complexity and price of the imaging hardware, e.g., the use of inexpensive non-tunable filters, and less expensive computational hardware, thereby enabling fast and affordable real-time exploration and sorting of grains. This study, while exploratory, fosters advancements in HSI data processing and identifies certain limitations that open new avenues for future research.

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利用高光谱成像研究小麦镰刀菌危害:独立成分分析方法

随着21世纪世界人口的不断增长，农业食品行业迫切需要采用快速、环保、可靠的技术来提高农产品的数量、质量和安全性，以满足未来世界对粮食的需求。高光谱成像技术(HSI)是一种新兴的非破坏性技术，可以收集样品的光谱和空间信息，可以表征农产品的质量参数，如镰刀菌损伤。尽管具有巨大的潜力，但HSI系统受到巨大数据量的影响，需要高计算时间和高功率。克服上述挑战的一个潜在解决方案是通过删除冗余信息来减小数据大小。然而，从大型数据集中检测小的最优特征并不是微不足道的。为此，研究并验证了一种探索性的新型HSI数据还原和分析技术，以确定小麦籽粒中镰刀菌的危害。在820 ~ 1666 nm的256个等间隔波长下，对3种含水量(19、27和35%，湿基)和7种感染水平(感染后0 ~ 56天)的小麦样品进行成像。首先，利用完整的HSI数据，利用独立分量分析(ICA)算法成功地表征了小麦籽粒的声音和镰刀菌损伤。然后，采用遗传算法优化方法将数据减少到10个波长，进行基于ica的分析。这种数据缩减方法在不影响系统性能的情况下，将计算时间减少到原始分析整个HSI数据所需时间的1.31%左右。这项初步研究表明，这种波长裁剪可以降低成像硬件的复杂性和价格，例如，使用廉价的不可调谐滤波器，以及更便宜的计算硬件，从而实现快速和负担得起的实时探测和分选谷物。本研究虽然是探索性的，但促进了恒生指数数据处理的进步，并确定了为未来研究开辟新途径的某些限制。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Near Infrared Spectroscopy 物理-光谱学

CiteScore

3.30

自引率

5.60%

发文量

审稿时长

6 months

期刊介绍： JNIRS — Journal of Near Infrared Spectroscopy is a peer reviewed journal, publishing original research papers, short communications, review articles and letters concerned with near infrared spectroscopy and technology, its application, new instrumentation and the use of chemometric and data handling techniques within NIR.