Automatic Bunch Detection in White Grape Varieties Using YOLOv3, YOLOv4, and YOLOv5 Deep Learning Algorithms

Sozzi, Marco; Cantalamessa, Silvia; Cogato, Alessia; Kayad, Ahmed; Marinello, Francesco

doi:10.3390/agronomy12020319

Cited by 153 publications

(94 citation statements)

References 58 publications

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“…For this purpose, their model reached an inference time of only 12 ms per image on an Nvidia GTX 1050Ti GPU. Similarly, a counting error of 13.3% was reported in the work of Sozzi et al [112] with a Yolov5x model. The performance obtained by Aguiar et al [94] seems to be closer to the natural condition of many vineyards: their SSD-MobileNet model reached 49.85 and 53.34% mAP on grapes before veraison, without defoliation, and at two different phenological stages.…”

Section: Performance Comparisonsupporting

confidence: 67%

Computer Vision and Deep Learning for Precision Viticulture

Mohimont

Alin

Rondeau³

et al. 2022

Agronomy

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During the last decades, researchers have developed novel computing methods to help viticulturists solve their problems, primarily those linked to yield estimation of their crops. This article aims to summarize the existing research associated with computer vision and viticulture. It focuses on approaches that use RGB images directly obtained from parcels, ranging from classic image analysis methods to Machine Learning, including novel Deep Learning techniques. We intend to produce a complete analysis accessible to everyone, including non-specialized readers, to discuss the recent progress of artificial intelligence (AI) in viticulture. To this purpose, we present work focusing on detecting grapevine flowers, grapes, and berries in the first sections of this article. In the last sections, we present different methods for yield estimation and the problems that arise with this task.

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Section: Performance Comparisonsupporting

confidence: 67%

Computer Vision and Deep Learning for Precision Viticulture

Mohimont

Alin

Rondeau³

et al. 2022

Agronomy

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“…While many previous studies have focused on berry counting, some have examined bunch detection using the YOLO model. Sozzi et al [21] demonstrated an AP value of 0.76 with YOLOv5. However, grape bunches visualized in the study appear in higher resolution, with less occlusion than seen in the present work.…”

Section: Saliency Mapping and Model Visualizationmentioning

confidence: 97%

“…Much of the previous work has been performed in orchard crops, such as apples [11,14], oranges [15], and mangos [16]. Studies in other specialty crops, including tomatoes [9,17] and grapes [18,19,20,13,21] have also been conducted. In vineyards, much of the existing literature in yield estimation from proximal imagery have consisted of methods leveraging feature engineering and computer vision to count individual grape berries [22,2,23], although pixel count has also been related to grapevine yield [1].…”

Section: Introductionmentioning

confidence: 99%

“…In vineyards, much of the existing literature in yield estimation from proximal imagery have consisted of methods leveraging feature engineering and computer vision to count individual grape berries [22,2,23], although pixel count has also been related to grapevine yield [1]. In very recent years, studies on proximal imaging for fruit detection have moved away from hand-crafted feature and algorithm development towards deep learning methods [12,18,24,13,21]. Deep learning methods used for fruit detection reduce the bias involved in model development via their flexibility in learning both the optimal features and optimal relationships between features to converge to the desired result.…”

Section: Introductionmentioning

confidence: 99%

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End-to-end deep learning for directly estimating grape yield from ground-based imagery

Olenskyj,

Sams,

Fei

et al. 2022

Preprint

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Yield estimation prior to harvest is a powerful tool in vineyard management, as it allows growers to fine-tune management practices to optimize yield and quality. However, yield estimation is currently performed using manual sampling, which is time-consuming and imprecise. This study demonstrates the applicability of nondestructive proximal imaging combined with deep learning for yield estimation in vineyards. Continuous image data collection using a vehicle-mounted sensing kit combined with collection of ground truth yield data at harvest using a commercial yield monitor allowed for the generation of a large dataset of 23,581 yield points and 107,933 images. Moreover, this study was conducted in a commercial vineyard which was mechanically managed, representing a challenging environment for image analysis but a common set of conditions in the California Central Valley. Three model architectures were tested: object detection, CNN regression, and transformer models. The object detection model was trained on hand-labeled images to localize grape bunches, and detections were either counted or their pixel count was summed to obtain a metric which was correlated to grape yield. Conversely, regression models were trained end-to-end to directly predict grape yield from image data without the need for hand labeling. Results demonstrated that both a transformer model as well as the object detection model with pixel area processing performed comparably, with a mean absolute percent error of 18% and 18.5%, respectively on a representative holdout dataset. Saliency mapping was used to demonstrate the attention of the CNN regression model was localized near the predicted location of grape bunches, as well as on the top of the grapevine canopy. Overall, the study demonstrated the applicability of proximal imaging and deep learning for prediction of grapevine yield on a large scale. Additionally, the end-to-end modeling approach was able to perform comparably to the object detection approach while eliminating the need for hand-labeling.

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“…A deep neural network is utilized to build the predictive model. DNN is an artificial neural network (ANN) algorithm with several hidden layers [30,31]. The proposed DNN model in this paper has four hidden layers.…”

Section: Deep Learningmentioning

confidence: 99%

A Deep Learning-Based Model to Reduce Costs and Increase Productivity in the Case of Small Datasets: A Case Study in Cotton Cultivation

Amani

Marinello

2022

Agriculture

Self Cite

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In this paper, a deep-learning model is proposed as a viable approach to optimize the information on soil parameters and agricultural variables’ effect in cotton cultivation, even in the case of small datasets. In this study, soil is analyzed to reduce the planting costs by determining the various combinations of soil components and nutrients’ precise amounts. Such factors are essential for cotton cultivation, since their amounts are often not precisely defined, and especially traditional farming methods are characterized by excessive distribution volumes producing significant economic and environmental impact. Not only can artificial intelligence decrease the charges, but it also increases productivity and profits. For this purpose, a deep learning algorithm was selected among other machine learning algorithms by comparison based on the accuracy metric to build the predictive model. This model gets the combination of the factors amounts as input and predicts whether the cotton growth will be successful or not. The predictive model was built by this algorithm based on 13 physical and chemical factors has 98.8% accuracy.

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Automatic Bunch Detection in White Grape Varieties Using YOLOv3, YOLOv4, and YOLOv5 Deep Learning Algorithms

Cited by 153 publications

References 58 publications

Computer Vision and Deep Learning for Precision Viticulture

Computer Vision and Deep Learning for Precision Viticulture

End-to-end deep learning for directly estimating grape yield from ground-based imagery

A Deep Learning-Based Model to Reduce Costs and Increase Productivity in the Case of Small Datasets: A Case Study in Cotton Cultivation

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