A Weakly Supervised Deep Learning Framework for Sorghum Head Detection and Counting

Ghosal, Sambuddha; Zheng, Bangyou; Chapman, Scott C.; Potgieter, Andries; Jordan, David R.; Wang, Xue Min; Singh, Asheesh K.; Hirafuji, Masayuki; Ninomiya, S.; Ganapathysubramanian, Baskar; Sarkar, Soumik; Guo, Wei

doi:10.34133/2019/1525874

Cited by 129 publications

(110 citation statements)

References 42 publications

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“…With the development of deep learning models for point clouds [57,58], compared performance should be achieved from point clouds. Thought not directly comparable, due to the use of different accuracy metrics, the performance achieved here is generally in line to other previous studies that applied image data [34,37,38]. In Olsen et al [34] a 98% counting accuracy and median absolute error (MAE) between 1.88 and 2.66 were achieved for 18 sorghum varieties in the Midwestern United States.…”

Section: Panicle Counting Performance and Field-level Panicle Mappingsupporting

confidence: 87%

“…As highlighted before, this high accuracy came at the expense of significant feature engineering, which we circumvented in this study by applying a deep learning approach. Ghosal et al [38] used 1269 hand-labeled images and achieved an AUC accuracy of 94% by applying an active learning inspired weakly supervised deep learning framework. Similar counting studies on other crops have also reported good performance.…”

Section: Plot Nomentioning

confidence: 99%

“…A similar approach based on learning multiple features for panicle detection is presented in [37]. To reduce the effort spent on manual labeling, Ghosal et al [38] applied a weakly supervised deep learning framework whereby a model was trained on a small training sample but gradually updated through human feedback on object detection results. They demonstrated a significant reduction in human labeling effort without compromising final model performance.…”

Section: Introductionmentioning

confidence: 99%

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A Deep Learning Semantic Segmentation-Based Approach for Field-Level Sorghum Panicle Counting

Malambo

Popescu

et al. 2019

Remote Sensing

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Small unmanned aerial systems (UAS) have emerged as high-throughput platforms for the collection of high-resolution image data over large crop fields to support precision agriculture and plant breeding research. At the same time, the improved efficiency in image capture is leading to massive datasets, which pose analysis challenges in providing needed phenotypic data. To complement these high-throughput platforms, there is an increasing need in crop improvement to develop robust image analysis methods to analyze large amount of image data. Analysis approaches based on deep learning models are currently the most promising and show unparalleled performance in analyzing large image datasets. This study developed and applied an image analysis approach based on a SegNet deep learning semantic segmentation model to estimate sorghum panicles counts, which are critical phenotypic data in sorghum crop improvement, from UAS images over selected sorghum experimental plots. The SegNet model was trained to semantically segment UAS images into sorghum panicles, foliage and the exposed ground using 462, 250 × 250 labeled images, which was then applied to field orthomosaic to generate a field-level semantic segmentation. Individual panicle locations were obtained after post-processing the segmentation output to remove small objects and split merged panicles. A comparison between model panicle count estimates and manually digitized panicle locations in 60 randomly selected plots showed an overall detection accuracy of 94%. A per-plot panicle count comparison also showed high agreement between estimated and reference panicle counts (Spearman correlation ρ = 0.88, mean bias = 0.65). Misclassifications of panicles during the semantic segmentation step and mosaicking errors in the field orthomosaic contributed mainly to panicle detection errors. Overall, the approach based on deep learning semantic segmentation showed good promise and with a larger labeled dataset and extensive hyper-parameter tuning, should provide even more robust and effective characterization of sorghum panicle counts.

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Section: Panicle Counting Performance and Field-level Panicle Mappingsupporting

confidence: 87%

Section: Plot Nomentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A Deep Learning Semantic Segmentation-Based Approach for Field-Level Sorghum Panicle Counting

Malambo

Popescu

et al. 2019

Remote Sensing

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“…State-of-the-art convolutional neural networks have been shown to perform well on a wide variety of phenotyping tasks. The applications of CNNs in plant phenotyping include image classification tasks such as plant species identification [1], stress identification [2], object detection arXiv:1910.01789v2 [cs.CV] 15 Oct 2019 and counting tasks such as panicle or spike detection [3,4,5,6], leaf counting [7], fruit detection [8]; as well as pixel-wise segmentation based tasks such as panicle segmentation [9,10] and crop-weed segmentation [11]. We refer the reader to [12] and [13] for a full treatment of deep learning in agriculture and plant phenotyping tasks.…”

Section: Introductionmentioning

confidence: 99%

Active learning with point supervision for cost-effective panicle detection in cereal crops

et al. 2020

Self Cite

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Background: Panicle density of cereal crops such as wheat and sorghum is one of the main components for plant breeders and agronomists in understanding the yield of their crops. To phenotype the panicle density effectively, researchers agree there is a significant need for computer vision-based object detection techniques. Especially in recent times, research in deep learning-based object detection shows promising results in various agricultural studies. However, training such systems usually requires a lot of bounding-box labeled data. Since crops vary by both environmental and genetic conditions, acquisition of huge amount of labeled image datasets for each crop is expensive and time-consuming. Thus, to catalyze the widespread usage of automatic object detection for crop phenotyping, a cost-effective method to develop such automated systems is essential.Results: We propose a weak supervision based active learning approach for panicle detection in cereal crops. In our approach, the model constantly interacts with a human annotator by iteratively querying the labels for only the most informative images, as opposed to all images in a dataset. Our query method is specifically designed for cereal crops which usually tend to have panicles with low variance in appearance. Our method reduces labeling costs by intelligently leveraging low-cost weak labels (object centers) for picking the most informative images for which strong labels (bounding boxes) are required. We show promising results on two publicly available cereal crop datasets -Sorghum and Wheat. On Sorghum, 6 variants of our proposed method outperform the best baseline method with more than 55% savings in labeling time. Similarly, on Wheat, 3 variants of our proposed methods outperform the best baseline method with more than 50% of savings in labeling time. Conclusion:We proposed a cost effective method to train reliable panicle detectors for cereal crops. A low cost panicle detection method for cereal crops is highly beneficial to both breeders and agronomists. Plant breeders can obtain quick crop yield estimates to make important crop management decisions. Similarly, obtaining real time visual crop analysis is valuable for researchers to analyze the crop's response to various experimental conditions.

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“…image flipping and rotating) have been the most commonly adopted techniques to compensate for the lack of data. More recently, several reports have highlighted the challenges with incorporating active learning or other approaches that loops the annotation and model training to minimize the labor cost 18–20 .…”

Section: Introductionmentioning

confidence: 99%

Learning from Synthetic Dataset for Crop Seed Instance Segmentation

Toda¹,

Okura

Ito

et al. 2019

Preprint

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12 13 *Correspondence should be addressed to Yosuke Toda; tyosuke@aquaseerser.com 14 15Incorporating deep learning in the image analysis pipeline has opened the possibility of introducing precision 16 phenotyping in the field of agriculture. However, to train the neural network, a sufficient amount of training 17 data must be prepared, which requires a time-consuming manual data annotation process that often becomes 18 the limiting step. Here, we show that an instance segmentation neural network (Mask R-CNN) aimed to 19 phenotype the barley seed morphology of various cultivars, can be sufficiently trained purely by a 20 synthetically generated dataset. Our attempt is based on the concept of domain randomization, where a large 21 amount of image is generated by randomly orienting the seed object to a virtual canvas. After training with 22 such a dataset, performance based on recall and the average Precision of the real-world test dataset achieved 23 96% and 95%, respectively. Applying our pipeline enables extraction of morphological parameters at a large 24 scale, enabling precise characterization of the natural variation of barley from a multivariate perspective. 25Importantly, we show that our approach is effective not only for barley seeds but also for various crops 26 including rice, lettuce, oat, and wheat, and thus supporting the fact that the performance benefits of this 27 technique is generic. We propose that constructing and utilizing such synthetic data can be a powerful method 28 to alleviate human labor costs needed to prepare the training dataset for deep learning in the agricultural 29 domain. 30 31 32

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A Weakly Supervised Deep Learning Framework for Sorghum Head Detection and Counting

Cited by 129 publications

References 42 publications

A Deep Learning Semantic Segmentation-Based Approach for Field-Level Sorghum Panicle Counting

A Deep Learning Semantic Segmentation-Based Approach for Field-Level Sorghum Panicle Counting

Active learning with point supervision for cost-effective panicle detection in cereal crops

Learning from Synthetic Dataset for Crop Seed Instance Segmentation

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