Earbox, an open tool for high-throughput measurement of the spatial organization of maize ears and inference of novel traits

Oury, Vincent; Leroux, Timothe; Turc, Olivier; Chapuis, Roland; Palaffre, Carine; Tardieu, François; Prado, Santiago Alvarez; Welcker, Claude; Lacube, Sébastien

doi:10.1101/2021.12.20.473433

Cited by 2 publications

(1 citation statement)

References 54 publications

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“…For example, most of the time required to photograph ears is spent dehusking, removing silks, and detaching shanks. Several researchers have used infrared radiation to phenotype kernel chemical composition, kernel fungal contamination, and viability (Agelet et al, 2012;Oury et al, 2021;Wang et al, 2015;Yao et al, 2013). Using cameras to capture signals outside the visible spectrum has the potential to be used for phenotyping ears without removing husks.…”

Section: Limitations and Future Workmentioning

confidence: 99%

EarCV: An open‐source, computer vision package for maize ear phenotyping

González

Ghosh

Colantonio

et al. 2022

The Plant Phenome Journal

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Fresh market sweet corn (Zea mays L.) is a row crop commercialized as a vegetable, resulting in strict expectations for ear size, color, and shape. Ear phenotyping in breeding programs is typically done manually and can be subjective, time consuming, and unreliable. Computer vision tools have enabled an inexpensive, high‐throughput, and quantitative alternative to phenotyping in agriculture. Here we present a computer vision tool using open‐source Python and OpenCV to measure yield component and quality traits relevant to sweet corn from photographs. This tool increases accuracy and efficiency in phenotyping through high‐throughput, quantitative feature extraction of traits typically measured qualitatively. EarCV worked in variable lighting and background conditions, such as under full sun and shade and against grass and dirt backgrounds. The package compares ears in images taken at varying distances and accurately measures ear length and ear width. It can measure traits that were previously difficult to quantify such as color, tip fill, taper, and curvature. EarCV allows users to phenotype any number of ears, dried or fresh, in any orientation while tolerating some debris and silk noise. The tool can categorize husked ears according to the predefined USDA quality grades based on length and tip fill. We show that the information generated from this computer vision approach can be incorporated into breeding programs by analyzing hybrid ears, capturing heritability of yield component traits, and detecting phenotypic differences between cultivars that conventional yield measurements cannot. Ultimately, computer vision can reduce the cost and resources dedicated to phenotyping in breeding programs.

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Section: Limitations and Future Workmentioning

confidence: 99%

EarCV: An open‐source, computer vision package for maize ear phenotyping

González

Ghosh

Colantonio

et al. 2022

The Plant Phenome Journal

View full text Add to dashboard Cite

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A Systematic Review of Effective Hardware and Software Factors Affecting High-Throughput Plant Phenotyping

et al. 2023

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Plant phenotyping studies the complex characteristics of plants, with the aim of evaluating and assessing their condition and finding better exemplars. Recently, a new branch emerged in the phenotyping field, namely, high-throughput phenotyping (HTP). Specifically, HTP exploits modern data sampling techniques to gather a high amount of data that can be used to improve the effectiveness of phenotyping. Hence, HTP combines the knowledge derived from the phenotyping domain with computer science, engineering, and data analysis techniques. In this scenario, machine learning (ML) and deep learning (DL) algorithms have been successfully integrated with noninvasive imaging techniques, playing a key role in automation, standardization, and quantitative data analysis. This study aims to systematically review two main areas of interest for HTP: hardware and software. For each of these areas, two influential factors were identified: for hardware, platforms and sensing equipment were analyzed; for software, the focus was on algorithms and new trends. The study was conducted following the PRISMA protocol, which allowed the refinement of the research on a wide selection of papers by extracting a meaningful dataset of 32 articles of interest. The analysis highlighted the diffusion of ground platforms, which were used in about 47% of reviewed methods, and RGB sensors, mainly due to their competitive costs, high compatibility, and versatility. Furthermore, DL-based algorithms accounted for the larger share (about 69%) of reviewed approaches, mainly due to their effectiveness and the focus posed by the scientific community over the last few years. Future research will focus on improving DL models to better handle hardware-generated data. The final aim is to create integrated, user-friendly, and scalable tools that can be directly deployed and used on the field to improve the overall crop yield.

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Earbox, an open tool for high-throughput measurement of the spatial organization of maize ears and inference of novel traits

Cited by 2 publications

References 54 publications

EarCV: An open‐source, computer vision package for maize ear phenotyping

EarCV: An open‐source, computer vision package for maize ear phenotyping

A Systematic Review of Effective Hardware and Software Factors Affecting High-Throughput Plant Phenotyping

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