Proof of Concept: Autonomous Machine Vision Software for Botanical Identification.

Nathan Stern, Jonathan Leidig, Gregory Wolffe
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Abstract

Background: HPTLC is a widely used and accepted technique for identification of botanicals. Current best practices involve subjective comparison of HPTLC-generated images between test samples and certified botanical reference materials based on specific bands.

Objective: This research was designed to evaluate the potential of cutting-edge machine vision-based machine learning techniques to automate identification of botanicals using native HPTLC image data.

Method: HPTLC images from Ginger and its closely related species and common adulterants were used to create large, synthetic datasets using a deep conditional generative adversarial network. This synthetic dataset was used to train and validate a deep convolutional neural network capable of automatically identifying new HPTLC image data. Performance of both neural networks was evaluated over time using appropriate loss functions as an indicator of their progress during learning. Validation of the overall system was measured via the accuracy of the learned model when applied to real HPTLC data.

Results: The machine vision system was able to generate realistic synthetic HPTLC images that were successfully used to train a deep convolutional neural network. The resulting learned model achieved high-accuracy identification from HPTLC images corresponding to Ginger and six other related species.

Conclusions: A proof-of-concept HPTLC image-based machine vision system for the identification of botanicals was proven to be feasible and a fully working prototype was validated for several species related to Ginger.

Highlights: This use of an autonomous machine-vision system for botanical identification removed the subjectivity inherent to human-based evaluation. The learned model also accurately evaluated botanical HPTLC images significantly faster than its human counterpart, which could save both time and resources.

概念验证:用于植物鉴定的自主机器视觉软件。
背景:HPTLC 是一种被广泛使用和接受的植物药鉴定技术。目前的最佳做法是根据特定条带,主观比较测试样品和经认证的植物参考材料之间 HPTLC 生成的图像:本研究旨在评估基于机器视觉的前沿机器学习技术的潜力,以便使用本地 HPTLC 图像数据自动识别植物药:方法:使用深度条件生成式对抗网络,将生姜及其近缘物种和常见掺杂物的 HPTLC 图像用于创建大型合成数据集。该合成数据集被用于训练和验证能够自动识别新 HPTLC 图像数据的深度卷积神经网络。使用适当的损失函数来评估这两个神经网络的性能,作为它们在学习过程中取得进步的指标。整个系统的验证是通过将所学模型应用于真实 HPTLC 数据时的准确性来衡量的:结果:机器视觉系统能够生成逼真的合成 HPTLC 图像,并成功用于训练深度卷积神经网络。结果:机器视觉系统能够生成逼真的合成 HPTLC 图像,并成功地将其用于训练深度卷积神经网络,由此产生的学习模型能够从 HPTLC 图像中高精度地识别生姜和其他六个相关物种:结论:基于 HPTLC 图像的机器视觉系统用于植物药鉴定的概念验证被证明是可行的,并且对生姜相关的几个物种验证了完全工作的原型:使用自主机器视觉系统进行植物鉴定消除了人为评估固有的主观性。学习到的模型对植物 HPTLC 图像的准确评估速度也明显快于人工评估,从而节省了时间和资源。
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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