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从原型到推理:一种在高粱穗检测中应用深度学习的流程

From Prototype to Inference: A Pipeline to Apply Deep Learning in Sorghum Panicle Detection.

作者信息

James Chrisbin, Gu Yanyang, Potgieter Andries, David Etienne, Madec Simon, Guo Wei, Baret Frédéric, Eriksson Anders, Chapman Scott

机构信息

School of Agriculture and Food Sciences, The University of Queensland, Brisbane, Australia.

School of Information Technology and Electrical Engineering, The University of Queensland, Brisbane, Australia.

出版信息

Plant Phenomics. 2023;5:0017. doi: 10.34133/plantphenomics.0017. Epub 2023 Jan 16.

DOI:10.34133/plantphenomics.0017
PMID:37040294
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10076054/
Abstract

Head (panicle) density is a major component in understanding crop yield, especially in crops that produce variable numbers of tillers such as sorghum and wheat. Use of panicle density both in plant breeding and in the agronomy scouting of commercial crops typically relies on manual counts observation, which is an inefficient and tedious process. Because of the easy availability of red-green-blue images, machine learning approaches have been applied to replacing manual counting. However, much of this research focuses on detection per se in limited testing conditions and does not provide a general protocol to utilize deep-learning-based counting. In this paper, we provide a comprehensive pipeline from data collection to model deployment in deep-learning-assisted panicle yield estimation for sorghum. This pipeline provides a basis from data collection and model training, to model validation and model deployment in commercial fields. Accurate model training is the foundation of the pipeline. However, in natural environments, the deployment dataset is frequently different from the training data (domain shift) causing the model to fail, so a robust model is essential to build a reliable solution. Although we demonstrate our pipeline in a sorghum field, the pipeline can be generalized to other grain species. Our pipeline provides a high-resolution head density map that can be utilized for diagnosis of agronomic variability within a field, in a pipeline built without commercial software.

摘要

穗密度是理解作物产量的一个主要因素,尤其是对于像高粱和小麦这种分蘖数可变的作物。在植物育种和商业作物的农艺学监测中,穗密度的测定通常依赖人工计数观察,这是一个低效且繁琐的过程。由于红-绿-蓝图像易于获取,机器学习方法已被用于取代人工计数。然而,大部分此类研究集中在有限测试条件下的检测本身,并未提供利用基于深度学习的计数的通用方案。在本文中,我们提供了一个从数据收集到模型部署的全面流程,用于在深度学习辅助下估算高粱的穗产量。该流程为从数据收集和模型训练到模型验证及在商业领域的模型部署提供了基础。准确的模型训练是该流程的基础。然而,在自然环境中,部署数据集常常与训练数据不同(域转移),导致模型失效,因此一个稳健的模型对于构建可靠的解决方案至关重要。尽管我们在高粱田展示了我们的流程,但该流程可推广到其他谷物品种。我们的流程提供了一个高分辨率的穗密度图,可用于在不使用商业软件构建的流程中诊断田间农艺变异性。

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