基于改进YOLOv9的蓝莓果实成熟度检测方法

doi:10.11707/j.1001-7488.LYKX20240822

摘要/Abstract

摘要：

目的: 针对现有蓝莓果实成熟度检测方法在复杂自然环境下的检测性能不佳，且对实际采摘作业中镜头离焦模糊和多角度成像的鲁棒性不足，导致收集的果实中生果混杂率高、收获质量难以保障的问题，提出一种改进的YOLOv9检测方法，旨在实现高精度的成熟度识别，为基于视觉的采摘转速动态调控提供算法支撑。方法: 以YOLOv9模型为基础，将MobileNetV4引入YOLOv9模型中作为骨干特征提取网络，减少网络的参数量和计算负担；在YOLOv9的颈部网络中引入GAM注意力机制模块，调整每个特征的权重，使模型更好地聚焦在对目标检测最重要的特征区域，进而增强模型对关键区域的识别能力，提高检测的准确性和鲁棒性；采用WIoU作为损失函数，优化模型的定位精度，提升边界框预测的准确性，加快网络收敛速度。利用蓝莓采摘试验台进行采摘试验，验证模型是否满足蓝莓采摘机器的精度和速度要求，并得到采摘装置采摘不同成熟果实比例的蓝莓植株时的最佳转速。结果: 改进后的YOLOv9模型在测试集上的精确率为98.0%，召回率为97.2%，平均精度均值（mAP）为98.2%，检测帧速率为86.5 fps，对比SSD、Faster R-CNN、YOLOv5和YOLOv8模型，平均精度均值分别提升6.8、5.6、4.0、2.7个百分点。改进后的模型满足采摘系统要求，在蓝莓植株的成熟果实比例为90%~ 100%、85%~ 90%和80%~ 85%时，采摘装置最佳转速分别为125 r·min^?1、130 r·min^?1和140 r·min^?1。结论: 改进后的YOLOv9模型较原模型提高了检测性能，通过蓝莓采摘试验得到的最佳转速能够降低生果率，为蓝莓果实智能化采摘提供强有力技术支持。

关键词: 蓝莓成熟度检测, YOLOv9, MobileNetV4, GAM, WIoU

Abstract:

Objective: The existing blueberry fruit ripeness detection methods exhibit poor performance in complex natural environments and insufficient robustness against lens defocus blur and multi-angle imaging in actual harvesting operations, resulting in high contamination rates of unripe fruits and difficulties in ensuring harvest quality. Aiming at the above issues, an improved YOLOv9 detection method is proposed to achieve high-precision ripeness recognition, providing algorithmic support for vision-based dynamic adjustment of harvesting speed. Method: Based on the YOLOv9 model, MobileNetV4 was introduced into the YOLOv9 model as the backbone feature extraction network to reduce the number of parameters and computational burden of the network. Additionally, a GAM attention module was integrated into the neck network of YOLOv9, and the weight of each feature was adjusted to enable the model to better focus on the most important feature areas for target detection, thereby enhancing its ability to recognize key regions and improving detection accuracy and robustness. WIoU was employed as the loss function to optimize the model's localization accuracy, improve boundary box prediction accuracy, and accelerate network convergence. Blueberry harvesting experiments were conducted on a picking test platform to verify whether the model meets the precision and speed requirements for blueberry harvesters, and to determine the optimal harvesting speed when harvesting blueberries with different fruit maturity ratios. Result: The improved YOLOv9 model achieved a precision of 98.0%, recall of 97.2%, an average precision mean (mAP) of 98.2%, and a detection frame rate of 86.5 fps on the test set. Compared with SSD, Faster R-CNN, YOLOv5, and YOLOv8 models, the average precision mean improved by 6.8, 5.6, 4.0, and 2.7 percentage points, respectively. The improved model met the requirements of the harvesting system. When the proportion of mature fruits on blueberry plants was 90%~100%, 85%~90%, and 80%~85%, the optimal harvesting speeds were 125 r·min^?1, 130 r·min^?1, and 140 r·min^?1, respectively. Conclusion: The improved YOLOv9 model has significantly enhanced detection performance compared to the original model. The optimal harvesting speeds obtained through blueberry harvesting tests can reduce the rate of unripe fruits, providing strong technical support for the intelligent harvesting of blueberries.

Key words: blueberry maturity detection, YOLOv9, MobileNetV4, GAM, WIoU

中图分类号:

S776
S663.9

王海滨,沈钦星,马鹏伟,宋佳音. 基于改进YOLOv9的蓝莓果实成熟度检测方法[J]. 林业科学, 2026, 62(1): 144-155.

Haibin Wang,Qinxing Shen,Pengwei Ma,Jiayin Song. Fruit Ripeness Detection Method of Blueberry Based on Improved YOLOv9[J]. Scientia Silvae Sinicae, 2026, 62(1): 144-155.

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场景 Scenarios	样本数量 Number of samples	果实数量 Number of fruits
不同距离 Different rangs	125	3 542
枝叶遮挡 Foliage obstruction	210	2 684
逆光 Backlighting	145	2 030
果实重叠 Fruit overlap	232	6 496
不聚焦 Out of focus	168	1 512
不同角度 Different Angles	120	1 683

成熟度 Maturity	精确率 Precision	召回率 Recall	平均精度均值 Average precision mean
成熟 Ripe	98.1	97.6	98.6
半成熟 Half-ripe	98.3	96.7	97.9
未成熟 Unripe	97.6	97.3	98.1
平均值 Average	98.0	97.2	98.2

模型 model	精确率 Precision （%）	召回率 Recall （%）	平均精度均值 Average precision mean (%)	内存占用量 Memory usage/MB	帧率Frame rate/ (fps·s^–1)
YOLOv9	95.9	94.8	96.7	58.7	75.3
YOLOv9M	96.4	94.1	96.3	42.3	96.2
YOLOv9G	97.1	96.3	97.4	62.4	70.6
YOLOv9W	96.2	94.9	96.9	58.8	78.3
YOLOv9MG	97.3	95.8	97.6	46.6	84.4
YOLOv9MW	96.5	94.6	96.8	42.4	97.6
YOLOv9GW	96.9	96.0	97.2	62.6	72.5
YOLOv9MGW	98.0	97.2	98.2	46.8	86.5

模型 model	精确率 Precision （%）	召回率 Recall （%）	平均精度均值 Mean average precision（%）	内存占用量 Memory usage/MB	帧率 Frame rate/ (fps·s^–1)
Faster R-CNN	90.2	88.2	92.6	149.5	14.1
SSD	89.3	87.5	91.4	87.3	54.6
YOLOv5	92.5	91.6	94.2	56.2	76.2
YOLOv8	94.7	93.4	95.5	40.5	95.6
YOLOv9	95.9	94.8	96.7	58.7	75.3
YOLOv9MGW	98.0	97.2	98.2	46.8	86.5

成熟果实比例 Mature fruit proportion（%）	采摘装置转速 Harvesting device rotation speed/(r·min^?1)	采净率 Harvest efficiency（%）	未成熟果实脱落率 Immature fruit drop rate（%）	果实损伤率 Fruit damage rate（%）	最佳转速 Optimal rotation speed/(r·min^?1)
≥90	120	97.2	1.94	1.36	125
	125	98.4	2.15	1.48
	130	98.7	2.40	1.62
85～90	125	97.5	2.20	1.60	130
	130	98.3	2.32	1.72
	135	98.6	2.56	1.85
80～85	135	98.0	2.40	1.86	140
	140	98.3	2.60	2.02
	145	98.5	2.78	2.24