Deep Semantic Segmentation of 3D Plant Point Clouds

Heiwolt, Karoline; Duckett, Tom; Cielniak, Grzegorz

doi:10.1007/978-3-030-89177-0_4

Cited by 4 publications

(4 citation statements)

References 17 publications

(17 reference statements)

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“…Heiwolt et al [301] applied the PointNet++ architecture, adjusted for point-wise segmentation applications, on tomato plants and showed that this network was able to successfully predict per-point semantic annotations for soil, leaves, and stems directly from point cloud data.…”

Section: Point-based Methodsmentioning

confidence: 99%

“…Deep Learning (DL) Banana [90] Maize (Corn) [160,299,310,313] Rice [311] Rosebush [264] Rosette plants [1] Sorghum [276] Thale cress (Arabidopsis) [17] Tobacco [276] Tomato [2,160,276,301] DL is a very commonly employed algorithm in the ML algorithms, and it is derived from the conventional neural network but considerably outperforms its predecessors. DL employs transformations and graph technologies simultaneously in order to build up multi-layer learning models.…”

Section: Machine Learning Techniquesmentioning

confidence: 99%

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How to make sense of 3D representations for plant phenotyping: a compendium of processing and analysis techniques

Harandi

Vandenberghe²,

Vankerschaver

et al. 2023

Plant Methods

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Computer vision technology is moving more and more towards a three-dimensional approach, and plant phenotyping is following this trend. However, despite its potential, the complexity of the analysis of 3D representations has been the main bottleneck hindering the wider deployment of 3D plant phenotyping. In this review we provide an overview of typical steps for the processing and analysis of 3D representations of plants, to offer potential users of 3D phenotyping a first gateway into its application, and to stimulate its further development. We focus on plant phenotyping applications where the goal is to measure characteristics of single plants or crop canopies on a small scale in research settings, as opposed to large scale crop monitoring in the field.

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Section: Point-based Methodsmentioning

confidence: 99%

Section: Machine Learning Techniquesmentioning

confidence: 99%

How to make sense of 3D representations for plant phenotyping: a compendium of processing and analysis techniques

Harandi

Vandenberghe²,

Vankerschaver

et al. 2023

Plant Methods

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show abstract

“…Segmentation of plants into organs is an essential step prior to the extraction of phenotypic traits. Deep learning methods such as PointNet++ variants have shown promise for this in the context of tomato plants, performing 3D semantic segmentation of synthetically generated plants without prior knowledge of species and sensor setup (Heiwolt et al., 2021). In comparison to cereal crops, such as wheat, both the complex growth habit of the strawberry plants, as well as their relatively small size, increase the phenotyping complexity (Zheng et al., 2021).…”

Section: Current Status Challenges and Prospects Of Automated Strawbe...mentioning

confidence: 99%

High‐throughput phenotyping for breeding targets—Current status and future directions of strawberry trait automation

James

Whitehouse

Cielniak

2022

Plants People Planet

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Strawberry breeders are faced with increasing demands by propagators, growers, retailers and consumers for particular agronomic traits. This and the volume of plants requiring assessment during selection constrain breeders to rapid and qualitative rating methods. High-throughput systems for assessing these traits automatically could indicate which families, or individual genotypes, should be singled out for further, more thorough evaluation, thus significantly increasing the selection intensity and accuracy. This review assesses the current status of and future potential for automated phenotyping in strawberry crops, highlighting key advances and the gaps which need to be addressed to facilitate the development of such technology.

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“…More recently, Chebrolu et al (2021) achieved leaf and stem segmentation using a support vector machine (SVM) based on fast point feature histograms (FPFH). However, these methods rely on human work to provide discriminative features for segmentation, a process which is sensitive to natural variations of plants even within a same cultivar, resulting in poor generalization (Heiwolt et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

3D data-augmentation methods for semantic segmentation of tomato plant parts

et al. 2023

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Introduction3D semantic segmentation of plant point clouds is an important step towards automatic plant phenotyping and crop modeling. Since traditional hand-designed methods for point-cloud processing face challenges in generalisation, current methods are based on deep neural network that learn to perform the 3D segmentation based on training data. However, these methods require a large annotated training set to perform well. Especially for 3D semantic segmentation, the collection of training data is highly labour intensitive and time consuming. Data augmentation has been shown to improve training on small training sets. However, it is unclear which data-augmentation methods are effective for 3D plant-part segmentation.MethodsIn the proposed work, five novel data-augmentation methods (global cropping, brightness adjustment, leaf translation, leaf rotation, and leaf crossover) were proposed and compared to five existing methods (online down sampling, global jittering, global scaling, global rotation, and global translation). The methods were applied to PointNet++ for 3D semantic segmentation of the point clouds of three cultivars of tomato plants (Merlice, Brioso, and Gardener Delight). The point clouds were segmented into soil base, stick, stemwork, and other bio-structures.Results and disccusionAmong the data augmentation methods being proposed in this paper, leaf crossover indicated the most promising result which outperformed the existing ones. Leaf rotation (around Z axis), leaf translation, and cropping also performed well on the 3D tomato plant point clouds, which outperformed most of the existing work apart from global jittering. The proposed 3D data augmentation approaches significantly improve the overfitting caused by the limited training data. The improved plant-part segmentation further enables a more accurate reconstruction of the plant architecture.

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Deep Semantic Segmentation of 3D Plant Point Clouds

Cited by 4 publications

References 17 publications

How to make sense of 3D representations for plant phenotyping: a compendium of processing and analysis techniques

How to make sense of 3D representations for plant phenotyping: a compendium of processing and analysis techniques

High‐throughput phenotyping for breeding targets—Current status and future directions of strawberry trait automation

3D data-augmentation methods for semantic segmentation of tomato plant parts

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