Autonomous Crop Row Guidance Using Adaptive Multi-ROI in Strawberry Fields

Ponnambalam, Vignesh Raja; Bakken, Marianne; Moore, Richard J. D.; Gjevestad, Jon Glenn Omholt; From, Pål Johan

doi:10.3390/s20185249

Cited by 46 publications

(23 citation statements)

References 23 publications

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“…. n k − 1), and the average distance between all these adjacent feature points is expressed as d k,avg , as shown in Equation (24).…”

Section: Crop Row Detectionmentioning

confidence: 99%

“…Adhikari et al [23] trained a deep convolutional encoder decoder network to detect crop lines using semantic graphics. Ponnambalam et al [24] designed a convolution neural network to segment input images based on red, green and blue color system (RGB) into crop and non-crop regions. Although these approaches achieved good results, there is still no superiority of stereo vision and deep learning over traditional architecture in terms of time consumption, and this will cause a significant burden for computation devices.…”

Section: Introductionmentioning

confidence: 99%

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Crop Row Segmentation and Detection in Paddy Fields Based on Treble-Classification Otsu and Double-Dimensional Clustering Method

Bao

Wang

et al. 2021

Remote Sensing

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Visual navigation is developing rapidly and is of great significance to improve agricultural automation. The most important issue involved in visual navigation is extracting a guidance path from agricultural field images. Traditional image segmentation methods may fail to work in paddy field, for the colors of weed, duckweed, and eutrophic water surface are very similar to those of real rice seedings. To deal with these problems, a crop row segmentation and detection algorithm, designed for complex paddy fields, is proposed. Firstly, the original image is transformed to the grayscale image and then the treble-classification Otsu method classifies the pixels in the grayscale image into three clusters according to their gray values. Secondly, the binary image is divided into several horizontal strips, and feature points representing green plants are extracted. Lastly, the proposed double-dimensional adaptive clustering method, which can deal with gaps inside a single crop row and misleading points between real crop rows, is applied to obtain the clusters of real crop rows and the corresponding fitting line. Quantitative validation tests of efficiency and accuracy have proven that the combination of these two methods constitutes a new robust integrated solution, with attitude error and distance error within 0.02° and 10 pixels, respectively. The proposed method achieved better quantitative results than the detection method based on typical Otsu under various conditions.

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“…. n k − 1), and the average distance between all these adjacent feature points is expressed as d k,avg , as shown in Equation (24).…”

Section: Crop Row Detectionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Crop Row Segmentation and Detection in Paddy Fields Based on Treble-Classification Otsu and Double-Dimensional Clustering Method

Bao

Wang

et al. 2021

Remote Sensing

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“…Kraemer et al [20] used a deep learning approach to reconcile the PSEP features by exploiting the likelihood maps of a deep neural networks (DNN). Also utilising DNNs, [21] proposed a convolutional neural network (CNN) for strawberry crop-row detection with accurate navigation. Lin et al [22] also showcase the potential of CNNs to reliably navigate a tea field by classifying tea rows.…”

Section: Related Workmentioning

confidence: 99%

Towards Autonomous Visual Navigation in Arable Fields

Ahmadi¹,

Halstead²,

McCool³

2021

Preprint

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Autonomous navigation of a robot in agricultural fields is essential for every task from crop monitoring through to weed management and fertilizer application. Many current approaches rely on accurate GPS, however, such technology is expensive and also prone to failure (e.g. through lack of coverage). As such, navigation through sensors that can interpret their environment (such as cameras) is important to achieve the goal of autonomy in agriculture.In this paper we introduce a purely vision based navigation scheme which is able to reliably guide the robot through rowcrop fields. Independent of any global localization or mapping, this approach is able to accurately follow the crop-rows and switch between the rows, only using on-board cameras. With the help of a novel crop-row detection and a novel crop-row switching technique, our navigation scheme can be deployed in a wide range of fields with different canopy types in various growth stages. We have extensively tested our approach in five different fields under various illumination conditions using our agricultural robotic platform (BonnBot-I). And our evaluations show that we have achieved a navigation accuracy of 3.82cm over five different crop fields.

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“…Valada et al [13] collect data with RGB, NIR and depth from forest roads, and fuse these modalities in a CNN for segmentation that shows good results in challenging light conditions and appearance variations. Recently, learningbased semantic segmentation has also been applied for row following in agri-cultural environments, like tea plantations [3], and our earlier work in strawberry fields [14]. These works all relied on large quantities of manually-labelled training images to learn the different semantic classes.…”

Section: Related Workmentioning

confidence: 99%

Robot-supervised Learning of Crop Row Segmentation

Bakken

Ponnambalam

Moore

et al. 2021

2021 IEEE International Conference on Robotics and Automation (ICRA)

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We propose an approach for robot-supervised learning that automates label generation for semantic segmentation with Convolutional Neural Networks (CNNs) for crop row detection in a field. Using a training robot equipped with RTK GNSS and RGB camera, we train a neural network that can later be used for pure vision-based navigation. We test our approach on an agri-robot in a strawberry field and successfully train crop row segmentation without any hand-drawn image labels. Our main finding is that the resulting segmentation output of the CNN shows better performance than the noisy labels it was trained on. Finally, we conduct open-loop field trials with our agri-robot and show that row-following based on the segmentation result is likely accurate enough for closedloop guidance. We conclude that automatically generating noisy segmentation labels is a promising approach for vision-based row following that can be quickly and easily adapted to new scenes.

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Autonomous Crop Row Guidance Using Adaptive Multi-ROI in Strawberry Fields

Cited by 46 publications

References 23 publications

Crop Row Segmentation and Detection in Paddy Fields Based on Treble-Classification Otsu and Double-Dimensional Clustering Method

Crop Row Segmentation and Detection in Paddy Fields Based on Treble-Classification Otsu and Double-Dimensional Clustering Method

Towards Autonomous Visual Navigation in Arable Fields

Robot-supervised Learning of Crop Row Segmentation

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