Computer vision neural networks in support systems for making decision on a smart farm

Capa

Citar

Texto integral

Acesso aberto Acesso aberto
Acesso é fechado Acesso está concedido
Acesso é fechado Somente assinantes

Resumo

The creation of smart farms and urban farms (city farm) has become one of the development trends in recent years, both in agroengineering and in urban construction. A high level of automation significantly reduces the degree of human participation in the production processes of a smart farm. As a result, the requirements for the experience and professional knowledge in the field of agriculture of the owner and staff of such a farm are reduced. The article discusses the issues of creating intelligent decision support systems for a “smart” agricultural farm, in particular, for urban, city farms. In such systems, artificial neural networks (ANN) of computer vision are used to process the results of observations and recognize situations requiring human intervention. Using the example of an urban farm for growing strawberries, a number of applied tasks are formulated (detection of fruits classified by maturity, detection and classification of diseases, detection of stolons). The results of an experimental study of computer vision systems for these tasks are presented. The research methodology included the use of pre-trained neural network models with their additional training on their own sets of images and subsequent assessment of the accuracy of detection and classification. Neural networks configured for such tasks in decision support systems are complemented by algorithms working with knowledge bases and computational and logical models. Thus, a hardware and software complex is being created that allows not only to automate the execution of current business tasks, but also to recommend solutions in case of difficult situations that normally require a lot of professional experience and knowledge from the staff. The study was conducted on the basis of the agrobiotechnical complex of Tyumen State University.

Texto integral

Acesso é fechado

Sobre autores

I. Glukhikh

University of Tyumen

Autor responsável pela correspondência
Email: i.n.glukhikh@utmn.ru

Grand PhD in Engineering Sciences, Professor

Rússia, Tyumen

A. Prokhoshin

University of Tyumen

Email: i.n.glukhikh@utmn.ru

Project Manager

Rússia, Tyumen

D. Glukhikh

University of Tyumen

Email: i.n.glukhikh@utmn.ru

PhD Student

Rússia, Tyumen

T. Filatova

University of Tyumen

Email: i.n.glukhikh@utmn.ru

Laboratory Assistant

Rússia, Tyumen

Bibliografia

  1. Agrobiotekhkompleks budushchego sozdan v TyumGU. Elektronnyj resurs: [sajt]. – URL: https://www.utmn.ru/x-bio/novosti/nauka-i-innovatsii/1182531/ (data obrashcheniya: 26.10.2023).
  2. Butorina D.A., Ahtyamov I.I. Ob”ekt gorodskogo fermerstva kak novoe obshchestvennoe prostranstvo v sovremennoj Rossii // Izvestiya KGASU. 2022. № 4(62). S. 163–176. doi: 10.52409/20731523_2022_4_163. EDN: VTAGZC.
  3. Gluhih I.N., Prohoshin A.S., Gluhih D.I. Sravnenie i otbor situacij v sistemah vyvoda reshenij na precedentah dlya «umnoj» fermy // Informatika i avtomatizaciya. 2023. T. 22. № 4. S. 853–879. doi: 10.15622/ia.22.4.6.
  4. Zhuravleva L.A. Siti-fermerstvo kak perspektivnoe napravlenie razvitiya agroproizvodstva // Nauchnaya zhizn’. 2020. T. 15. № 4. S. 492–503. doi: 10.35679/1991-9476-2020-15-4-492-503.
  5. Mahmudul Hasan A., Md Rakib Ul Islam R., Avinash K. Klassifikaciya boleznej list’ev yabloni s ispol’zovaniem nabora dannyh izobrazhenij: podhod mnogoslojnoj svertochnoj nejronnoj seti // Informatika i avtomatizaciya. 2022. T. 21. № 4. C. 710–728. doi: 10.15622/ia.21.4.3.
  6. Rutkin N.M., Lagutkin O.Yu., Lagutkina L.Yu. Urbanizirovannoe agroproizvodstvo (siti-fermerstvo) kak perspektivnoe napravlenie razvitiya mirovogo agroproizvodstva i sposob povysheniya prodovol’stvennoj bezopasnosti gorodov//Vestnik Astrahanskogo gosudarstvennogo tekhnicheskogo universiteta. Seriya: rybnoe hozyajstvo. 2017. T. 2017. № 4. S. 95–108.
  7. Aamodt A., Plaza E. Case-Based Reasoning: Foundational Issues, Methodological Variations, and System Approaches. AI Communications. 2001. Vol. 7. PP. 39–59. doi: 10.3233/AIC-1994-7104.
  8. Afzaal U., Bhattarai B., Pandeya Y.R., Lee J. An Instance Segmentation Model for Strawberry Diseases Based on Mask R-CNN. Sensors. 2021, 21, 6565.
  9. Bhujel A., Kim N.-E., Arulmozhi E., Basak J.K. et al. A Lightweight Attention-Based Convolutional Neural Networks for Tomato Leaf Disease Classification. Agriculture. 2022. № 12(2). P. 228. doi: 10.3390/agriculture12020228. doi:10.3390/ agriculture12020228.
  10. Detection tasks / [Elektronnyj resurs] // Ul’tralitiks : [sajt]. – URL: https://docs.ultralytics.com/tasks/detect/ (data obrashcheniya: 26.10.2023).
  11. Elhariri E., El-Bendary N., Saleh S.M., Strawberry-DS: Dataset of annotated strawberry fruits images with various developmental stages. Data in Brief. 2023. Vol. 48, 109165. doi: 10.1016/j.dib.2023.109165.
  12. Hu W.-C., Chen L.-B., Huang B.-K., Lin H.-M. A Computer Vision-Based Intelligent Fish Feeding System Using Deep Learning Techniques for Aquaculture. IEEE Sensors Journal. 2022. Vol. 22. № 7. PP. 7185–7194. doi: 10.1109/JSEN.2022.3151777.
  13. Juan Terven, Diana Cordova-Esparza. A Comprehensive Review of YOLO: From YOLOv1 and Beyond. 2023. URL: https://doi.org/10.48550/arXiv.2304.00501.
  14. Martin M., Molin E. Environmental Assessment of an Urban Vertical Hydroponic Farming System in Sweden // Sustainability. 2019. Vol. 11(15). № 4124. doi: 10.3390/su11154124.

Arquivos suplementares

Arquivos suplementares
Ação
1. JATS XML
Baixar
2. Figures for the article by Glukhikh I.N. et al. "Neural networks of computer vision in decision support systems on a smart farm" (p. 53)

Baixar (410KB)
Metadados

Declaração de direitos autorais © Russian Academy of Sciences, 2024

Este site utiliza cookies

Ao continuar usando nosso site, você concorda com o procedimento de cookies que mantêm o site funcionando normalmente.

Informação sobre cookies