Multi-Altitude Corn Tassel Detection and Counting Based on UAV RGB Imagery and Deep Learning

Drones Pub Date : 2024-05-14 DOI:10.3390/drones8050198

Shanwei Niu, Zhigang Nie, Guang Li, Wenyu Zhu

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Abstract

In the context of rapidly advancing agricultural technology, precise and efficient methods for crop detection and counting play a crucial role in enhancing productivity and efficiency in crop management. Monitoring corn tassels is key to assessing plant characteristics, tracking plant health, predicting yield, and addressing issues such as pests, diseases, and nutrient deficiencies promptly. This ultimately ensures robust and high-yielding corn growth. This study introduces a method for the recognition and counting of corn tassels, using RGB imagery captured by unmanned aerial vehicles (UAVs) and the YOLOv8 model. The model incorporates the Pconv local convolution module, enabling a lightweight design and rapid detection speed. The ACmix module is added to the backbone section to improve feature extraction capabilities for corn tassels. Moreover, the CTAM module is integrated into the neck section to enhance semantic information exchange between channels, allowing for precise and efficient positioning of corn tassels. To optimize the learning rate strategy, the sparrow search algorithm (SSA) is utilized. Significant improvements in recognition accuracy, detection efficiency, and robustness are observed across various UAV flight altitudes. Experimental results show that, compared to the original YOLOv8 model, the proposed model exhibits an increase in accuracy of 3.27 percentage points to 97.59% and an increase in recall of 2.85 percentage points to 94.40% at a height of 5 m. Furthermore, the model optimizes frames per second (FPS), parameters (params), and GFLOPs (giga floating point operations per second) by 7.12%, 11.5%, and 8.94%, respectively, achieving values of 40.62 FPS, 14.62 MB, and 11.21 GFLOPs. At heights of 10, 15, and 20 m, the model maintains stable accuracies of 90.36%, 88.34%, and 84.32%, respectively. This study offers technical support for the automated detection of corn tassels, advancing the intelligence and precision of agricultural production and significantly contributing to the development of modern agricultural technology.

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基于无人机 RGB 图像和深度学习的多高度玉米穗检测与计数

在农业技术飞速发展的背景下，精确高效的作物检测和计数方法在提高生产力和作物管理效率方面发挥着至关重要的作用。监测玉米抽穗是评估植物特征、跟踪植物健康状况、预测产量以及及时处理病虫害和营养缺乏等问题的关键。这最终可确保玉米生长健壮和高产。本研究介绍了一种利用无人飞行器 (UAV) 拍摄的 RGB 图像和 YOLOv8 模型识别和计算玉米穗的方法。该模型采用 Pconv 局部卷积模块，设计轻巧，检测速度快。主干部分添加了 ACmix 模块，以提高玉米穗的特征提取能力。此外，颈部还集成了 CTAM 模块，以加强通道之间的语义信息交换，从而实现对玉米穗的精确、高效定位。为了优化学习率策略，采用了麻雀搜索算法（SSA）。在不同的无人机飞行高度下，识别准确率、检测效率和鲁棒性都有显著提高。实验结果表明，与最初的 YOLOv8 模型相比，所提出的模型在 5 米高度上的准确率提高了 3.27 个百分点，达到 97.59%，召回率提高了 2.85 个百分点，达到 94.40%。此外，该模型优化了每秒帧数 (FPS)、参数 (params) 和 GFLOPs（每秒千兆浮点运算），分别提高了 7.12%、11.5% 和 8.94%，实现了 40.62 FPS、14.62 MB 和 11.21 GFLOPs 的数值。在 10 米、15 米和 20 米的高度上，模型的精确度分别稳定在 90.36%、88.34% 和 84.32%。这项研究为玉米抽穗的自动检测提供了技术支持，提高了农业生产的智能化和精确度，极大地促进了现代农业技术的发展。

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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