Deep Learning for Image-Based Plant Growth Monitoring: A Review

Tong, Yin-Syuen; Lee, Tou-Hong; Yen, Kin-Sam

doi:10.46604/ijeti.2022.8865

Cited by 10 publications

(3 citation statements)

References 117 publications

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“…Consequently, it has tremendous potential in predicting plant growth, estimating yield, detecting maturity, and perceiving biotic/abiotic stresses. However, deep learning algorithms require a large amount of labeled data ( Cordts et al., 2016 ), and data acquisition comes at a high cost, especially when identifying numerous categories ( Tong et al., 2022 ) or subtle differences between categories ( Taghavi Namin et al., 2018 ). Furthermore, collecting phenotype data faces additional obstacles of severe occlusion and various lighting conditions ( Scharr et al., 2016 ), which increase the time required for obtaining the necessary annotations.…”

Section: Challenges and Prospectsmentioning

confidence: 99%

Deep learning-empowered crop breeding: intelligent, efficient and promising

Wang,

Zeng,

Lin

et al. 2023

Front. Plant Sci.

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Crop breeding is one of the main approaches to increase crop yield and improve crop quality. However, the breeding process faces challenges such as complex data, difficulties in data acquisition, and low prediction accuracy, resulting in low breeding efficiency and long cycle. Deep learning-based crop breeding is a strategy that applies deep learning techniques to improve and optimize the breeding process, leading to accelerated crop improvement, enhanced breeding efficiency, and the development of higher-yielding, more adaptive, and disease-resistant varieties for agricultural production. This perspective briefly discusses the mechanisms, key applications, and impact of deep learning in crop breeding. We also highlight the current challenges associated with this topic and provide insights into its future application prospects.

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Section: Challenges and Prospectsmentioning

confidence: 99%

Deep learning-empowered crop breeding: intelligent, efficient and promising

Wang,

Zeng,

Lin

et al. 2023

Front. Plant Sci.

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“…Similarly, sequential models, using long short-term memory (LSTM) or recurrent neural networks (RNNs), capture temporal dependencies in plant growth using time sequence data. A recent survey [7] has identified a total of 23 published works proposing deep learning models for plant monitoring applications, from which 15 were for horticulture crops, with most of the works published between 2017 to 2021 using either CNN/R-CNN with spatial data or convolutional LSTM/RNN with spatiotemporal data. All of these works were primarily focused on either of the three objective tasks: (i) plant growth classification, (ii) instance segmentation and object detection for growth stage identification, and (iii) regression for plant growth analysis.…”

Section: Current State Of Computer Vision In Horticulturementioning

confidence: 99%

Current State, Data Requirements and Generative AI Solution for Learning-based Computer Vision in Horticulture

Baniya¹,

Lee²,

Eklund³

et al. 2023

Preprint

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The use of visual signals in horticulture has attracted significant attention and encompassed a wide range of data types such as 2D images, videos, hyperspectral images, and 3D point clouds. These visual signals have proven to be valuable in developing cutting-edge computer vision systems for various applications in horticulture, enabling plant growth monitoring, pest and disease detection, quality and yield estimation, and automated harvesting. However, unlike other sectors, developing deep learning computer vision systems for horticulture encounters unique challenges due to the limited availability of high-quality training and evaluation datasets necessary for deep learning models. This paper investigates the current status of vision systems and available data in order to identify the high-quality data requirements specific to horticultural applications. We analyse the impact of the quality of visual signals on the information content and features that can be extracted from these signals. To address the identified data quality requirements, we explore the usage of a deep learning-based super-resolution model for generative quality enhancement of visual signals. Furthermore, we discuss how these can be applied to meet the growing requirements around data quality for learning-based vision systems. We also present a detailed analysis of the competitive quality generated by the proposed solution compared to cost-intensive hardware-based alternatives. This work aims to guide the development of efficient computer vision models in horticulture by overcoming existing data challenges and paving a pathway forward for contemporary data acquisition.

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“…Despite the use of DL methods in agriculture-related applications has been reported to be on the rise since 2016, the work to exploit the potential of DL methods in analyzing plant growth traits is still lacking in general compared to other applications in agriculture such as species classification, stress detection, and yield estimation [7]. Specifically, growth monitoring studies constitute only 14.08% of the 71 studies as reported by Yang and Xu [8].…”

Section: Introductionmentioning

confidence: 99%

Recognition of Ginger Seed Growth Stages Using a Two-Stage Deep Learning Approach

Yin-Syuen Tong,

Tou-Hong Lee,

Kin-Sam Yen

2024

Proc. eng. technol. innov.

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Monitoring the growth of ginger seed relies on human experts due to the lack of salient features for effective recognition. In this study, a region-based convolutional neural network (R-CNN) hybrid detector-classifier model is developed to address the natural variations in ginger sprouts, enabling automatic recognition into three growth stages. Out of 1,746 images containing 2,277 sprout instances, the model predictions revealed significant confusion between growth stages, aligning with the human perception in data annotation, as indicated by Cohen’s Kappa scores. The developed hybrid detector-classifier model achieved an 85.50% mean average precision (mAP) at 0.5 intersections over union (IoU), tested with 402 images containing 561 sprout instances, with an inference time of 0.383 seconds per image. The results confirm the potential of the hybrid model as an alternative to current manual operations. This study serves as a practical case, for extensions to other applications within plant phenotyping communities.

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Deep Learning for Image-Based Plant Growth Monitoring: A Review

Cited by 10 publications

References 117 publications

Deep learning-empowered crop breeding: intelligent, efficient and promising

Deep learning-empowered crop breeding: intelligent, efficient and promising

Current State, Data Requirements and Generative AI Solution for Learning-based Computer Vision in Horticulture

Recognition of Ginger Seed Growth Stages Using a Two-Stage Deep Learning Approach

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