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SGSNet:一种用于草莓生长阶段检测的轻量级深度学习模型。

SGSNet: a lightweight deep learning model for strawberry growth stage detection.

作者信息

Li Zhiyu, Wang Jianping, Gao Guohong, Lei Yufeng, Zhao Chenping, Wang Yan, Bai Haofan, Liu Yuqing, Guo Xiaojuan, Li Qian

机构信息

School of Computer Science and Technology, Henan Institute of Science and Technology, Xinxiang, China.

出版信息

Front Plant Sci. 2024 Dec 2;15:1491706. doi: 10.3389/fpls.2024.1491706. eCollection 2024.

DOI:10.3389/fpls.2024.1491706
PMID:39717733
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11664550/
Abstract

INTRODUCTION

Detecting strawberry growth stages is crucial for optimizing production management. Precise monitoring enables farmers to adjust management strategies based on the specific growth needs of strawberries, thereby improving yield and quality. However, dense planting patterns and complex environments within greenhouses present challenges for accurately detecting growth stages. Traditional methods that rely on large-scale equipment are impractical in confined spaces. Thus, the development of lightweight detection technologies suitable for portable devices has become essential.

METHODS

This paper presents SGSNet, a lightweight deep learning model designed for the fast and accurate detection of various strawberry growth stages. A comprehensive dataset covering the entire strawberry growth cycle is constructed to serve as the foundation for model training and testing. An innovative lightweight convolutional neural network, named GrowthNet, is designed as the backbone of SGSNet, facilitating efficient feature extraction while significantly reducing model parameters and computational complexity. The DySample adaptive upsampling structure is employed to dynamically adjust sampling point locations, thereby enhancing the detection capability for objects at different scales. The RepNCSPELAN4 module is optimized with the iRMB lightweight attention mechanism to achieve efficient multi-scale feature fusion, significantly improving the accuracy of detecting small targets from long-distance images. Finally, the Inner-IoU optimization loss function is applied to accelerate model convergence and enhance detection accuracy.

RESULTS

Testing results indicate that SGSNet performs exceptionally well across key metrics, achieving 98.83% precision, 99.45% recall, 99.14% F1 score, 99.50% mAP@0.5, and a loss value of 0.3534. It surpasses popular models such as Faster R-CNN, YOLOv10, and RT-DETR. Furthermore, SGSNet has a computational cost of only 14.7 GFLOPs and a parameter count as low as 5.86 million, demonstrating an effective balance between high performance and resource efficiency.

DISCUSSION

Lightweight deep learning model SGSNet not only exceeds the mainstream model in detection accuracy, but also greatly reduces the need for computing resources and is suitable for portable devices. In the future, the model can be extended to detect the growth stage of other crops, further advancing smart agricultural management.

摘要

引言

检测草莓生长阶段对于优化生产管理至关重要。精确监测能使农民根据草莓的特定生长需求调整管理策略,从而提高产量和品质。然而,温室中密集的种植模式和复杂的环境给准确检测生长阶段带来了挑战。依赖大型设备的传统方法在有限空间内不切实际。因此,开发适用于便携式设备的轻量级检测技术变得至关重要。

方法

本文提出了SGSNet,一种轻量级深度学习模型,旨在快速准确地检测草莓的各个生长阶段。构建了一个涵盖草莓整个生长周期的综合数据集,作为模型训练和测试的基础。设计了一种名为GrowthNet的创新轻量级卷积神经网络作为SGSNet的主干,在显著减少模型参数和计算复杂度的同时促进高效特征提取。采用DySample自适应上采样结构动态调整采样点位置,从而增强对不同尺度物体的检测能力。使用iRMB轻量级注意力机制对RepNCSPELAN4模块进行优化,以实现高效的多尺度特征融合,显著提高从远距离图像中检测小目标的准确性。最后,应用Inner-IoU优化损失函数加速模型收敛并提高检测精度。

结果

测试结果表明,SGSNet在关键指标上表现出色,精度达到98.83%,召回率为99.45%,F1分数为99.14%,mAP@0.5为99.50%,损失值为0.3534。它超过了Faster R-CNN、YOLOv10和RT-DETR等流行模型。此外,SGSNet的计算成本仅为14.7 GFLOPs,参数数量低至586万,在高性能和资源效率之间实现了有效平衡。

讨论

轻量级深度学习模型SGSNet不仅在检测精度上超过了主流模型,还大大减少了对计算资源的需求,适用于便携式设备。未来,该模型可扩展用于检测其他作物的生长阶段,进一步推动智能农业管理发展。

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