References

vavilov

Вавиловский журнал генетики и селекции

Vavilov Journal of Genetics and Breeding

2500-3259

Institute of Cytology and Genetics of Siberian Branch of the RAS

10.18699/vjgb-26-09

vavilov-4977

Research Article

БИОИНФОРМАТИКА И СИСТЕМНАЯ БИОЛОГИЯ

BIOINFORMATICS AND SYSTEMS BIOLOGY

Детекция колосков в колосе пшеницы на RGB-изображениях с использованием глубокого машинного обучения

Wheat spikelet detection on RGB images using deep machine learning

https://orcid.org/0000-0001-7607-4151

Генаев

М. А.

Genaev

M. A.

Новосибирск

Novosibirsk

mag@bionet.nsc.ru

Бусов

И. Д.

Busov

I. D.

Новосибирск

Novosibirsk

https://orcid.org/0000-0002-1084-9521

Кручинина

Ю. В.

Kruchinina

Yu. V.

Новосибирск

Novosibirsk

Коваль

В. С.

Koval

V. S.

Новосибирск

Novosibirsk

Гончаров

Н. П.

Goncharov

N. P.

Новосибирск

Novosibirsk

Федеральный исследовательский центр Институт цитологии и генетики Сибирского отделения Российской академии наук; Курчатовский геномный центр ИЦиГ СО РАНРоссияInstitute of Cytology and Genetics of the Siberian Branch of the Russian Academy of Sciences; Kurchatov Genomic Center of ICG SB RASRussian Federation

Федеральный исследовательский центр Институт цитологии и генетики Сибирского отделения Российской академии наук; Новосибирский национальный исследовательский государственный университетРоссияInstitute of Cytology and Genetics of the Siberian Branch of the Russian Academy of Sciences; Novosibirsk State UniversityRussian Federation

2026

05032026

3012735

2026

Генаев М.А., Бусов И.Д., Кручинина Ю.В., Коваль В.С., Гончаров Н.П.

Genaev M.A., Busov I.D., Kruchinina Y.V., Koval V.S., Goncharov N.P.

This work is licensed under a Creative Commons Attribution 4.0 License.

https://vavilov.elpub.ru/jour/article/view/4977

В работе рассматривается задача автоматизированного высокопроизводительного фенотипирования признаков колоса пшеницы с использованием современных методов компьютерного зрения и глубокого обучения. Точная оценка числа колосков является важным компонентом анализа продуктивности растения, однако традиционные методы ручной разметки и подсчета крайне трудоемки, плохо масштабируются и требуют значительных временных затрат. В исследовании предложен подход для эффективной детекции колосков, основанный на использовании упрощенной точечной разметки, при которой эксперт отмечает только центры колосков, без необходимости формировать трудоемкие пиксельные маски или ограничивающие рамки. Такая схема позволяет существенно снизить стоимость подготовки обучающей выборки и ускорить процесс аннотации. Для определения оптимального способа обработки упрощенной разметки были исследованы три метода: сегментация бинарных масок с помощью архитектуры U-Net, регрессия плотностных карт на основе двумерного нормального распределения и функции дивергенции Кульбака–Лейблера, а также детекция областей фиксированного размера с использованием модели YOLOv8. Проведено сравнение точности методов по количественным (MAE, MAPE) и пространственным метрикам (Precision, Recall, F1) на тестовых наборах изображений. Анализ результатов показал, что подходы, основанные на U-Net, обеспечивают высокую точность локализации и подсчета колосков при минимальных затратах на разметку данных, тогда как метод YOLOv8 менее устойчив к геометрической вариативности реальных объектов. Предложенный подход демонстрирует, что комбинация точечной разметки и современных моделей сегментации является эффективным инструментом для автоматизации фенотипирования, что может значительно ускорить селекционные исследования и расширить возможности высокопроизводительного анализа морфологических признаков растений.

This study addresses the challenge of automated high-throughput phenotyping of wheat spike characteristics using modern computer vision and deep learning methods. Accurate estimation of spikelet number is a key indicator of plant productivity, yet traditional manual counting approaches are labor-intensive, slow, and difficult to scale to large breeding datasets. To overcome these limitations, we propose a spikelet detection strategy based on simplified point annotations, where an expert marks only the centers of spikelets rather than drawing detailed segmentation masks or bounding boxes. This significantly reduces annotation time and lowers the overall cost of preparing training datasets for machine learning models. To determine the most effective way of utilizing such simplified annotations, three computational methods were explored: segmentation of binary masks using a U-Net architecture, density regression based on two-dimensional Gaussian distributions optimized via Kullback–Leibler divergence, and detection of fixed-size bounding regions using the YOLOv8 object detection framework. The models were evaluated on dedicated test datasets using both quantitative metrics (MAE, MAPE) and spatial localization metrics (Precision, Recall, F1 score). The results demonstrate that U-Net-based approaches provide consistently high accuracy in spikelet localization and counting while maintaining robustness to annotation imperfections. In contrast, the YOLOv8-based method showed reduced performance, likely due to the geometric mismatch between fixed-size boxes and the natural elongated shape of spikelets. Overall, the proposed methodology highlights the effectiveness of combining minimalistic point-level annotation with advanced segmentation models for automating phenotyping workflows. This approach has the potential to accelerate breeding programs, enhance the efficiency of largescale phenotypic data collection, and support further development of robust computer-vision tools for plant science applications.

компьютерное зрениеглубокое обучениепшеницаколосчисло колосковфенотипированиедетекция объектов

computer visiondeep learningwheatspikespikelets per spikephenotypingobject detection

Data preparation, development and verification of the algorithm were carried out with the support of the Russian Science Foundation, project No. 23-14-00150.

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The authors declare that there are no conflicts of interest present.