You are here: Home Аrchive of articles (from 2017 till now) 2025 №3 List of Article 04 Pronin S. P., Zryumova A. G., Piletsky A. А., Belyaev V. I. Intelligent Assessment of Wheat Yield through the Variable Potential of Seeds

PDF To download article.

DOI: 10.15507/2658-4123.035.202503.443-464

 

Intelligent Assessment of Wheat Yield through the Variable Potential of Seeds

 

Sergey P. Pronin
Dr.Sci. (Eng.), Professor of the Department of Information Technology, Polzunov Altai State Technical University (46 Lenin Ave., Barnaul 656038, Russian Federation), ORCID: https://orcid.org/0000-0001-5066-2609, Scopus ID: 6701475629, SPIN-code: 2745-4983, This email address is being protected from spambots. You need JavaScript enabled to view it.

Anastasia G. Zryumova
Cand.Sci. (Eng.), Head of the Department of Information Technology, Polzunov Altai State Technical University (46 Lenin Ave., Barnaul 656038, Russian Federation), ORCID: https://orcid.org/0009-0005-1289-6099, This email address is being protected from spambots. You need JavaScript enabled to view it.

Alexander A. Piletsky
Postgraduate Student of the Department of Information Technology, Polzunov Altai State Technical University (46 Lenin Ave., Barnaul 656038, Russian Federation), ORCID: https://orcid.org/0009-0001-2134-2662, This email address is being protected from spambots. You need JavaScript enabled to view it.

Vladimir I. Belyaev
Dr.Sci. (Eng.), Head of the Department of Agricultural Machinery and Technology, Altai State Agricultural University (98 Krasnoarmeyskiy Ave., Barnaul 656049, Russian Federation), ORCID: https://orcid.org/0000-0003-4396-2202, This email address is being protected from spambots. You need JavaScript enabled to view it.

 

Abstract
Introduction. Evaluation of wheat seed quality is an integral part of the technological process of its production since it increases the yield. The yield is affected by many different factors. The evaluation methods are constantly being improved taking into account new factors, physical methods and technical means. Currently seeds and crops sowing quality intelligent evaluation methods are developing very rapidly. The electrophysical method allows evaluating the soil influence on seeds by the variable potential.
Aim of the Study. The study is aimed at examining changes in the variable potential of wheat seeds of a known crop yields during seed swelling in solutions with different potassium and sodium ratios and creating a convolutional neural network to estimate potential crop yields through the variable potential and known potassium and sodium ratios.
Materials and Methods. The studies were carried out using seeds of two varieties of spring wheat with different yields. To simulate soil quality, there were used solutions with different potassium chloride and sodium chloride ratios. The variable potential was measured using a device based on the data acquisition board LA50-USB. The yield was estimated using wavelet transform and deep convolutional neural network with ResNet groups.
Results. There have been developed the experimental graphs of the variable potential change depending on the potassium and sodium ratio in a solution simulating soil quality. The neural network was used to classify the potential yield of wheat seeds through wavelet transforms of the variable potential, and potassium and sodium ratios. There has been compiled a table of neural network responses to test variable potentials.
Discussion and Conclusion. The developed graphs of the variable potential change depending on potassium change in the external environment were compared with the results of studies by other authors. The results qualitatively coincide. The developed neural network can classify the potential yield of wheat seeds through the variable potential, and potassium and sodium ratios. The conducted study is useful for agricultural enterprises and farmers. The proposed methodology for assessing potential crop yields through variable potential and water extract will allow optimizing the process of potassium application to the soil.

Keywords: variable potential, wheat, potassium and sodium ratio, neural network, yield

Conflict of interest: The authors declare that there is no conflict of interest.

For citation: Pronin S.P., Zryumova A.G., Piletsky A.А., Belyaev V.I. Intelligent Assessment of Wheat Yield through the Variable Potential of Seeds. Engineering Technologies and Systems.2025;35(3):443–464. https://doi.org/10.15507/2658-4123.035.202503.443-464

Authors contribution:
S. P. Pronin – formulating the study, aims and objectives; conducting the study, including the executing and describing the experiments, collecting and analyzing the; using statistical, mathematical, computational and other formal methods for analyzing the study data; preparing of the manuscript: critical analysis of the draft manuscript, comments and corrections made by members of the research group, including at the stages before and after publication.
A. G. Zryumova – conducting the study, describing existing control methods, executing the experiments and collecting the data; preparing the manuscript; visualizing the study results and data obtained.
A. A. Piletsky – conducting the study including the development of a neural network, its training, data processing, description of the neural network architecture, performing experiments and collecting data; preparing a manuscript: visualizing the study results and data obtained.
V. I. Belyaev – conducting the study, including the preparation of wheat seeds, consultations on the yield of varieties; preparing the manuscript: visualizing the study results and the data obtained.

All authors have read and approved the final manuscript.

Submitted 17.01.2025;
revised 13.02.2025;
accepted 25.02.2025

 

REFERENCES

  1. Rahman A., Cho B.-K. Assessment of Seed Quality Using Non-Destructive Measurement Techniques: A Review. Seed Science Research. 2016;26(4):285–305. https://doi.org/10.1017/S0960258516000234
  2. Fazel-Niari Z., Afkari-Sayyah A.H., Abbaspour-Gilandeh Y., Herrera-Miranda I., Hernández-Hernández J.L., Hernández-Hernández M. Quality Assessment of Components of Wheat Seed Using Different Classifications Models. Applied Sciences. 2022;12(9):4133. https://doi.org/10.3390/app12094133
  3. Priyatkin N.S., Arkhipov M.V., Shchukina P.A., Mirskaya G.V., Chesnokov Yu.V. Evaluation of Heterogeneity and Hidden Defects of Wheat (Triticum Aestivum L.) Seeds by Instrumental Physical Methods. Agricultural Biology. 2022;57(5):911–920. (In Russ., abstract in Eng.) https://doi.org/10.15389/agrobiology.2022.5.911rus
  4. Shen Y., Li G., Li Z., Ai M., Wang L., Xiong X. Discrimination of Wheat Varieties by Terahertz Time-domain Spectroscopy and Convolutional Neural Network. Research Article. 2023;1. https://doi.org/10.21203/rs.3.rs-3020250/v1
  5. Barysheva N.N., Pronin S.P., Baryshev D.D., Belyaev V.I. Comparing the Membrane Potential of Wheat Grains of Different Varieties and Productivity Divided into Fractions According to Their Aerodynamic Properties. Engineering Technologies and Systems. 2020;30(4):550–575. (In Russ., abstract in Eng.) https://doi.org/10.15507/2658-4123.030.202004.550-575
  6. Kovalev A.V., Isaeva A.S. Evaluation of Wheat Seed Quality Using a Convolu-Tional Neural Network. Engineering Bulletin of the Don. 2021;(12). (In Russ., abstract in Eng.) Available at: http://www.ivdon.ru/ru/magazine/archive/n12y2021/7354 (accessed 01.12.2024).
  7. Yao J., Liu J., Zhang Y., Wang H. Identification of Winter Wheat Pests And Diseases Based on Improved Convolutional Neural Network. Open Life Sciences. 2023;18(1):20220632. https://doi.org/10.1515/biol-2022-0632
  8. Li Y., Cao G., Liu D., Zhang J., Li L., Chen C. Determination of Wheat Heading Stage Using Convolutional Neural Networks on Multispectral UAV Imaging Data. Computational Intelligence and Neuroscience. 2022;(1):3655804. https://doi.org/10.1155/2022/3655804
  9. Dong Y., Liu Y., Kang H., Li C., Liu P., Liu Z. Lightweight and Efficient Neural Network with SPSA Attention for Wheat Ear Detection. PeerJ Computer Science. 2022;8:e931. https://doi.org/10.7717/peerj-cs.931
  10. Hasan M.M., Chopin J.P., Laga H., Miklavcic S.J. Detection and Analysis of Wheat Spikes Using Convolutional Neural Networks. Plant Methods. 2018;14:100. https://doi.org/10.1186/s13007-018-0366-8
  11. Sun X., Li Y., Li G., Jin S., Zhao W., Liang Z., et al. SCGNet: Efficient Sparsely Connected Group Convolution Network for Wheat Grains Classification. Frontiers in Plant Science. 2023;14:1304962. https://doi.org/10.3389/fpls.2023.1304962
  12. Zhang W., Li Z., Li G., Zhuang P., Hou G., Zhang Q., et al. GACNet: Generate Adversarial-Driven Cross-Aware Network for Hyperspectral Wheat Variety Identification. IEEE Transactions on Geoscience and Remote Sensing. 2023;62. https://doi.org/10.1109/TGRS.2023.3347745
  13. Nithyasundari B., Ilakya R., Nissa M., Prabhas D., Kishore K., Kumar K.K. HNNL: Experimental Analysis of Wheat Crop Disease Detection Using Hyper Neural Network Based Learning Methodology. In: 2024 International Conference on Advances in Computing, Communication and Applied Informatics (ACCAI). Chennai, India, 2024:1–7. https://doi.org/10.1109/ACCAI61061.2024.10602195
  14. Tolba A., Talal N. An Interpretable Deep Learning for Early Detection and Diagnosis of Wheat Leaf Diseases. Optimization in Agriculture. 2024;1:81–93. https://doi.org/10.61356/j.oia.2024.1257
  15. Sonmez M.E., Sabanci K., Aydin N. Convolutional Neural Network-Support Vector Machine-Based Approach for Identification of Wheat Hybrids. European Food Research and Technology. 2024;250:1353–1362. https://doi.org/10.1007/s00217-024-04473-4
  16. Zhuang T., Zhang Yu, Li D., Schmidhalter U., Ata-UI-Karim S.T., Cheng T. Coupling Continuous Wavelet Transform with Machine Learning to Improve Water Status Prediction in Winter Wheat. Precision Agriculture. 2023;24:2171–2199. https://doi.org/10.1007/s11119-023-10036-6
  17. Li C., Li X., Meng X., Xiao Z., Wu X., Wang X., et al. Hyperspectral Estimation of Nitrogen Content in Wheat Based on Fractional Difference and Continuous Wavelet Transform. Agriculture. 2023;13(5):1017. https://doi.org/10.3390/agriculture13051017
  18. Molin A.E., Blekanov I.S., Mitrofanov E.P., Mitrofanova O.A. Synthetic Data Generation Methods for Training Neural Networks in the Task of Segmenting the Level of Crop Nitrogen Status on UAV Images of Agricultural Fields. Vestnik of Saint Petersburg University. Applied Mathematics. Computer Science. Control Processes. 2024;20(1):20–33. (In Russ., abstract in Eng.) https://doi.org/10.21638/11701/spbu10.2024.103
  19. Gierz Ł., Przybył K. Texture Analysis and Artificial Neural Networks for Identification of Cereals-Case Study: Wheat, Barley and Rape Seeds. Scientific Reports. 2022;12:19316. https://doi.org/10.1038/s41598-022-23838-x
  20. Zang H., Su X., Wang Y., Li G., Zhang J., Zheng G., et al. Automatic Grading Evaluation of Winter Wheat Lodging Based on Deep Learning. Frontiers in Plant Science. 2024;15. https://doi.org/10.3389/fpls.2024.1284861
  21. Bischokov R.M. Analysis, Modelling and Forecasting of Crop Yields Using Artificial Neural Networks. RUDN Journal of Agronomy and Animal Industries. 2022;17(2):146–157. (In Russ., abstract in Eng.) https://doi.org/10.22363/2312-797X-2022-17-2-146-157
  22. Barysheva N.N., Guner M.V., Baryshev D.D., Pronin S.P. Neural Network Research of Data about the Quality of Wheat Seed Material by Bioelectric Signals. High-Perfomance Computing Systems and Technologies. 2020;4(1):179–183. (In Russ., abstract in Eng.) https://elibrary.ru/zrnits
  23. Baryshev D.D., Barysheva N.N., Pronin S.P. [Preparation of a Training Sample for Classifying Seeds by Their Yield Properties]. AIC of Russia. 2020;27(3):440–446. (In Russ.) https://elibrary.ru/iqnneh
  24. Kazak E.V., Parfenyuk V.I. Physicochemical Regularities of Ionic (Na+,K+) Permeability of a Functional Membrane I. Dependence of Ionic Flows Through the Membrane on Time and Concentration of Solutions. Chemistry and Chemical Technology. 2005;48(2):27–34. (In Russ., abstract in Eng.) Available at: https://main.isuct.ru/files/journal/t48_v2_full.pdf (accessed 21.10.2024).
  25. Pronin S.P., Belyaev V.I., Zryumova A.G., Petrova I.I. Spring Wheat Yield Comparison at Different Sodium and Potassium Concentrations in the Soil and Different Seed Membrane Potentia. Bulletin of the Altai State Agrarian University. 2022;(9):16–24. (In Russ., abstract in Eng.) https://elibrary.ru/kjilvh
  26. Alimagadov K.A., Umnyashkin S.V. Data Augmentation Based on Wavelet Filtration During Neural Network Training. In: GraphiCon 2023 : Proceedings of the 33rd International Confe-rence on Computer Graphics and Machine Vision (2023 September 19–21, Moscow). 2023:437–442. (In Russ., abstract in Eng.) https://doi.org/10.20948/graphicon-2023-437-442
  27. Stefanidi A.F., Priorov A.L., Topnikov A.I., Khryashchev V.V. The Problem of Personality Recognition Using Facial Images and Audio Signals with Speech Recordings. Digital Signal Processing. 2020;(2):52–58. (In Russ., abstract in Eng.) Available at: http://www.dspa.ru/articles/year2020/jour20_2/art20_2_7.pdf (accessed 03.12.2024).
  28. Bharati S., Podder P., Mondal M.R., Prasath S. CO-ResNet: Optimized ResNet Model for COVID-19 Diagnosis from X-ray Images. International Journal of Hybrid Intelligent Systems. 2021;17(1–2):71–85. https://doi.org/10.3233/HIS-210008
  29. Wen L., Li X., Gao L. A Transfer Convolutional Neural Network for Fault Diagnosis Based on ResNet-50. Neural Computing and Applications. 2020;32:6111–6124. https://doi.org/10.1007/s00521-019-04097-w
  30. Hodgkin A.L., Huxley A.F. A Quantitative Description of Membrane Current and its Application To Conduction And Excitation in Nerve. Bulletin of Mathematical Biology. 1990;52:25–71. https://doi.org/10.1007/BF02459568
  31. Kan A.G., Romanenko S.V. [Filtering of Voltammetric Signals Using Wavelet Transform]. Bulletin of Tomsk Polytechnic University. 2006;309(8):52–54. (In Russ.) Available at: https://earchive.tpu.ru/handle/11683/1448 (accessed 21.10.2024).

 

 

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

Details
Hits: 8
Joomla templates by a4joomla