解释基于深度学习的叶病识别

IF 3.1 3区 计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Soft Computing Pub Date : 2024-07-29 DOI:10.1007/s00500-024-09939-x
Ankit Rajpal, Rashmi Mishra, Sheetal Rajpal, Kavita, Varnika Bhatia, Naveen Kumar
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引用次数: 0

摘要

农作物病害对农业生产率和质量造成不利影响。这些病害的主要原因是真菌、病毒和细菌等生物压力的存在。要在早期阶段检测出这些病因,需要领域专家的持续监测。机器学习和深度学习方法的技术进步使得通过图像分析自动识别叶片病害的具体症状成为可能。本文提出使用各种基于深度学习的模型对叶片病害进行基于图像的检测。实验是在 PlantVillage 数据集上进行的,该数据集由 54305 张彩色叶片图像(健康和病害)组成,属于 11 种作物,分为 38 类。基于Inception-ResNet-V2的模型的10倍交叉验证准确率达到了(0.9991 \pm 0.002\),超过了其他深度神经架构,并超越了近期最先进作品中现有模型的性能。每个带下划线的模型都在一个独立的队列中进行了验证。基于Inception-ResNet-V2的模型取得了最佳的10倍交叉验证准确率(0.9535 \pm 0.041\),在其他基于深度学习的模型中具有显著的统计学意义。然而,这些深度学习模型被认为是一个黑盒子,因为它们的叶病预测对终端用户来说是不透明的。为了解决这个问题,我们提出了一个局部可解释框架,以标记有助于识别叶病的超像素。这些超像素密切证实了人类专家的注释。
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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Explaining deep learning-based leaf disease identification

Crop diseases adversely affect agricultural productivity and quality. The primary cause of these diseases is the presence of biotic stresses such as fungi, viruses, and bacteria. Detecting these causes at early stages requires constant monitoring by domain experts. Technological advancements in machine learning and deep learning methods have enabled the automated identification of leaf disease-specific symptoms through image analysis. This paper proposes image-based detection of leaf diseases using various deep learning-based models. The experiment was conducted on the PlantVillage dataset, which consists of 54,305 colour leaf images (healthy and diseased) belonging to 11 crop species categorized into 38 classes. The Inception-ResNet-V2-based model achieved a 10-fold cross-validation accuracy of \(0.9991 \pm 0.002\) outperforming the other deep neural architectures and surpassing the performance of existing models in recent state-of-the-art works. Each underlined model is validated on an independent cohort. The Inception-ResNet-V2-based model achieved the best 10-fold cross-validation accuracy of \(0.9535 \pm 0.041\) and was found statistically significant among other deep learning-based models. However, these deep learning models are considered a black box as their leaf disease predictions are opaque to end users. To address this issue, a local interpretable framework is proposed to mark the superpixels that contribute to identifying leaf disease. These superpixels closely confirmed the annotations of the human expert.

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来源期刊
Soft Computing
Soft Computing 工程技术-计算机:跨学科应用
CiteScore
8.10
自引率
9.80%
发文量
927
审稿时长
7.3 months
期刊介绍: Soft Computing is dedicated to system solutions based on soft computing techniques. It provides rapid dissemination of important results in soft computing technologies, a fusion of research in evolutionary algorithms and genetic programming, neural science and neural net systems, fuzzy set theory and fuzzy systems, and chaos theory and chaotic systems. Soft Computing encourages the integration of soft computing techniques and tools into both everyday and advanced applications. By linking the ideas and techniques of soft computing with other disciplines, the journal serves as a unifying platform that fosters comparisons, extensions, and new applications. As a result, the journal is an international forum for all scientists and engineers engaged in research and development in this fast growing field.
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