Potted Phalaenopsis Grading: Precise Bloom and Bud Counting with the PA-YOLO Algorithm and Multiviewpoint Imaging

The accurate detection and counting of flowers ensure the grading quality of the ornamental plants. In automated potted flower grading scenarios, low detection precision, occlusions and overlaps impact counting accuracy. This study proposed a counting method combining a deep learning algorithm with...

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Bibliographic Details
Published inAgronomy (Basel) Vol. 14; no. 1; p. 115
Main Authors Yang, Yi, Zhang, Guankang, Ma, Shutao, Wang, Zaihua, Liu, Houcheng, Gu, Song
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.01.2024
Subjects
Algorithms
Cameras
Clustering
Data mining
Datasets
Deep learning
flower counting
flower detection
Flowers
Flowers & plants
Machine learning
machine vision
multiple viewpoints
Neural networks
Object recognition
Occlusion
Optimization
Ornamental plants
Phalaenopsis
Plants (botany)
potted Phalaenopsis
Vision systems
China
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Summary:The accurate detection and counting of flowers ensure the grading quality of the ornamental plants. In automated potted flower grading scenarios, low detection precision, occlusions and overlaps impact counting accuracy. This study proposed a counting method combining a deep learning algorithm with multiple viewpoints. Firstly, a flower detection model, PA-YOLO, was developed based on YOLOv5 by designing a two-scale detection branch, optimizing the number of bottlenecks and integrating a dynamic head framework. Next, PA-YOLO was used to detect grouped 360-viewpoint images of each potted plant to determine the optimal number of viewpoints for counting. The detection results indicated that PA-YOLO achieved a mean average precision (mAP) of 95.4% and an average precision (AP) of 91.9% for occluded blooms on our Phalaenopsis flower dataset. For the optimal number of viewpoints, the average counting accuracy of buds and blooms was highest at three viewpoints, with scores of 96.25% and 93.33%, respectively. The final counting accuracy reached 95.56% in flower counting tests conducted from three viewpoints. The overall results suggest that the proposed method can effectively detect and count flowers in complex occlusion and overlap environments, providing guidance for designing and implementing the vision component in an automated potted flower grading system.
ISSN:2073-4395
2073-4395
DOI:10.3390/agronomy14010115