Synthesis and research of the intelligent automatic control system for a fruit drying apparatus

Authors

  • Avtandil Bardavelidze Akaki Tsereteli State University, Faculty of Exact and Natural Sciences, Department of Computer Technology, 59 Tamar Mepe Str., 4600, Kutaisi, Georgia, Tel.: +995 558 82 99 82 Author https://orcid.org/0000-0001-7972-4711
  • Khatuna Bardavelidze Georgian Technical University, Faculty of Informatics and Control Systems, Department of Interdisciplinary Informatics, 77, Merab Kostava Str., 6th Building, 0117, Tbilisi, Georgia, Tel.: +995 598 15 62 09 Author https://orcid.org/0000-0001-7972-4711
  • Otari Sesikashvili Akaki Tsereteli State University, Faculty of Engineering – Technical, Department of Mechanical Engineering, 59 Tamar Mepe Str., 4600, Kutaisi, Georgia, Tel.: +995 593 96 62 42 Author https://orcid.org/0000-0003-1229-4141

DOI:

https://doi.org/10.5219/scifood.42

Keywords:

fruit, drying, apparatus, intelligent system, computer model, Fuzzy controller, Narma L2 regulator, synthesis

Abstract

Modern drying technologies are essential for extending the shelf life of fruits and vegetables while minimizing energy consumption and maintaining product quality. This study presents the development and implementation of an intelligent automatic control system for a conveyor-type fruit drying apparatus, integrating fuzzy logic and artificial neural network (ANN) methodologies. The novelty of the work lies in the first real-time application of a NARMA L2 neural network controller for regulating the air relative humidity in the drying chamber. Ripe fruits (apples, pears, apricots, and plums) with high moisture content were selected and processed under industrial conditions using a G4-KSK-15 conveyor-type dryer. A dynamic mathematical model of the drying process was constructed by approximating transient characteristics via a second-order transfer function. This model served as the foundation for simulating three control strategies in MATLAB/Simulink: classic PID, PID-Fuzzy, and PID-NARMA L2. Experimental validation demonstrated that the NARMA L2 controller significantly outperformed the other methods, achieving a 57% reduction in settling time and a 74% reduction in overshoot compared to the conventional PID regulator. The improved control response directly contributed to reduced energy consumption during the drying phase. This work confirms that intelligent control systems—particularly those incorporating ANN—enhance process stability, product quality, and energy efficiency in industrial fruit drying operations. The findings provide a foundation for broader application of AI-driven control systems in the food industry.

Metrics

Metrics Loading ...

References

1. Zareiforoush, H., Bakhshipour, A., & Bagheri, I. (2021). Performance Evaluation and Optimization of a Solar-Assisted Multi-Belt Conveyor Dryer Based on Response Surface Methodology. Journal of Renewable Energy and Environment, Online First. https://doi.org/10.30501/jree.2021.285697.1203

2. Kiurchev, S., Verkholantseva, V., Kiurcheva, L., & Dumanskyi, O. (2020). Physical-mathematical modeling of vibrating conveyor drying process of soybeans. In Engineering for Rural Development. 19th International Scientific Conference Engineering for Rural Development. Latvia University of Life Sciences and Technologies, Faculty of Engineering. https://doi.org/10.22616/erdev.2020.19.tf234

3. Calín-Sánchez, Á., Lipan, L., Cano-Lamadrid, M., Kharaghani, A., Masztalerz, K., Carbonell-Barrachina, Á. A., & Figiel, A. (2020). Comparison of Traditional and Novel Drying Techniques and Its Effect on Quality of Fruits, Vegetables and Aromatic Herbs. In Foods (Vol. 9, Issue 9, p. 1261). MDPI AG. https://doi.org/10.3390/foods9091261

4. Bardavelidze, A., & Bardavelidze, Kh. (2024). Development and investigation of algorithm for the synthesis of an automatic control system of the drying process. In International Journal on Information Technologies and Security (Vol. 16, Issue 1, pp. 15–26). International Journal on Information Technologies and Security. https://doi.org/10.59035/ojbv6115

5. Radojčin, M., Pavkov, I., Bursać Kovačević, D., Putnik, P., Wiktor, A., Stamenković, Z., Kešelj, K., & Gere, A. (2021). Effect of Selected Drying Methods and Emerging Drying Intensification Technologies on the Quality of Dried Fruit: A Review. In Processes (Vol. 9, Issue 1, p. 132). MDPI AG. https://doi.org/10.3390/pr9010132

6. Raponi, F., Moscetti, R., Monarca, D., Colantoni, A., & Massantini, R. (2017). Monitoring and Optimization of the Process of Drying Fruits and Vegetables Using Computer Vision: A Review. In Sustainability (Vol. 9, Issue 11, p.2009). MDPI AG. https://doi.org/10.3390/su9112009

7. Dumitru Veleșcu, I., Nicoleta Rațu, R., Arsenoaia, V.-N., Roșca, R., Marian Cârlescu, P., & Țenu, I. (2023). Research on the Process of Convective Drying of Apples and Apricots Using an Original Drying Installation. In Agriculture (Vol. 13, Issue 4, p. 820). MDPI AG. https://doi.org/10.3390/agriculture13040820

8. Krzysztof, P., Krzysztof, K. (2023). Applications MLP and Other Methods in Artificial Intelligence of Fruit and Vegetable in Convective and Spray Drying. In Applied Sciences (Vol. 13, Issue 5, p.2965). MDPI AG. https://doi.org/10.3390/app13052965

9. Tümay, M., & Ünver, H. M. (2021). Design and implementation of smart and automatic oven for food drying. In Measurement and Control (Vol. 54, Issues 3–4, pp. 396–407). SAGE Publications. https://doi.org/10.1177/00202940211000084

10. Sansaniwal, S. K., Kumar, M., Sahdev, R. K., Bhutani, V., & Manchanda, H. (2022). Toward natural convection solar drying of date palm fruits (Phoenix dactylifera L.): An experimental study. In Environmental Progress & Sustainable Energy (Vol. 41, Issue 6). Wiley. https://doi.org/10.1002/ep.13862

11. Kırbas, İ., Tuncer, A. D., Sirin, C., & Usta, H. (2019). Modeling and developing a smart interface for various drying methods of pomelo fruit (Citrus maxima) peel using machine learning approaches. In Computers and Electronics in Agriculture (Vol. 165, p. 104928). Elsevier BV. https://doi.org/10.1016/j.compag.2019.104928

12. Chen, J., Zhang, M., Xu, B., Sun, J., & Mujumdar, A. S. (2020). Artificial intelligence assisted technologies for controlling the drying of fruits and vegetables using physical fields: A review. In Trends in Food Science & Technology (Vol. 105, pp. 251–260). Elsevier BV. https://doi.org/10.1016/j.tifs.2020.08.015

13. Martynenko, A., & Bück, A. (Eds.). (2018). Intelligent Control in Drying. CRC Press. https://doi.org/10.1201/9780429443183

14. Hyder, M. J., Khan, M. J., Khan, M. A., & Saeed, S. (2023). The Design and Development of a Solar Dehydrator for Fruits. In ICAME 2023 (p. 48). ICAME 2023. MDPI. https://doi.org/10.3390/engproc2023045048

15. Yang, T., Zheng, X., Xiao, H., Shan, C., Yao, X., Li, Y., & Zhang, J. (2023). Drying Temperature Precision Control System Based on Improved Neural Network PID Controller and Variable-Temperature Drying Experiment of Cantaloupe Slices. In Plants (Vol. 12, Issue 12, p. 2257). MDPI AG. https://doi.org/10.3390/plants12122257

16. Nafisah,N., Syamsiana, I.N., Putri, R.I., Kusuma, W., Sumari, A.D.W. (2024). Implementa¬tion of fuzzy logic control algorithm for temperature control in robusta rotary dryer coffee bean dryer. MethodsX. (Vol. 12, 102580). https://doi.org/10.1016/j.mex.2024.102580

17. Bardavelidze, A., Bardavelidze, Kh., & Sesikashvili, O. (2025). A cellular dynamic mathematical model of a conveyor dryer as an object of automatic control. In Scifood (Vol. 19, pp. 145–163). HACCP Consulting. https://doi.org/10.5219/scifood.13

18. International Organization for Standardization. (2018). Green coffee – Determination of the moisture content – Basic reference method—Requirements with guidance for use (ISO Standard No. 1446:2018). Retrieved from: https://www.iso.org/standard/34008.html

19. Alkahdery, L. A. (2023). Automated temperatureand humidity control and monitoring system for improving the performance in drying system. In Eurasian Physical Technical Journal (Vol. 20, Issue 2 (44), pp. 32–40). Karagandy University of the name of academician E.A. Buketov. https://doi.org/10.31489/2023no2/32-40

20. Saipan Saipol, H. F., & Alias, N. (2020). Numerical simulation of DIC drying process on matlab distributed computing server. Indonesian Journal of Electrical Engineering and Computer Science, 20(1), 338. https://doi.org/10.11591/ijeecs.v20.i1.pp338-346

21. Duffy, D. G. (2017). Advanced Engineering Mathematics with Matlab. Fourth Edition. CRC Press, Taylor&Francis Group, (1005p.) ISBN-13:978-1-4987-3964-1 Retrieved from: https://industri. fatek.unpatti.ac.id/wp-content/uploads/2019/03/081-Advanced-Engineering-Mathematics -with-MATLAB-Dean-G.-Duffy-Edisi-4-2016.pdf

22. Nuñez Vega, A.-M., Sturm, B., & Hofacker, W. (2016). Simulation of the convective drying process with automatic control of surface temperature. In Journal of Food Engineering (Vol. 170, pp. 16–23). Elsevier BV. https://doi.org/10.1016/j.jfoodeng.2015.08.033

23. Adejumo, O. A., Adebiyi, A. O., Ajiboye, A. T., Oje, K. (2022). Modeled dryer using an automatic control system for agricultural products. CIGR E-Journal/Agricultural Engineering International: The CIGR Journal of Scientific Research and Development (Vol. 24, No. 2, pp. 239-247).

24. Bardavelidze, A., Bardavelidze, Kh. (2024). Algorithm for Development of Artificial Neural System for Evaluation of Teaching Quality. The Internet and Information and Communi¬cation Technologies in Today’s Society. Chapter 13 (pp.103-107). Cambridge Scholars Publishing ISBN:1-0364-0768-3,ISBN13:978-1-0364-0768-1.

25. Mahapatra, M. D., Konar, K., Mahato, S., Kumar, V., & Dey, P. (2024). Fuzzy PID Controller Design for Enhanced Voltage Regulation in Automatic Voltage Regulator System. In 2024 IEEE International Conference on Information Technology, Electronics and Intelligent Communication Systems (ICITEICS) (pp. 1–7). 2024 IEEE International Conference on Information Technology, Electronics and Intelligent Communication Systems (ICITEICS). IEEE. https://doi.org/10.1109/iciteics61368.2024.10625215

26. Bardavelidze, A., Bardavelidze, Kh. (2019). Computer Modeling Of Automation Systems. Lambert Academic Publishing (112 p.) ISBN 10:6139457521

27. Bardavelidze A., Bardavelidze Kh., Sesikashvili, O. (2024). Development and study of a multi-criteria optimal control algorithm for the static mode of the fruit tunnel dehydration process. Journal of Food and Nutrition Research (Vol. 63, No. 1, pp. 69-78) National Agricultural and Food Centre (Slovakia) (ISSN 1336-8672).

28. Bardavelidze, A., Bardavelidze, Kh., Sesikashvili, O. (2023). Mathematical model of the static mode of tunnel dehydrator for fruits as a controlled object. Journal of Food and Nutrition Research (Vol. 62, No. 4, pp. 305-313) National Agricultural and Food Centre (Slovakia) (ISSN 1336-8672).

29. Ben Khedher, N., Ramzi, R., & Alatawi, I. A. (2020). Numerical Comparison of Triangular and Sinusoidal External Vibration Effects on the 3D Porous Drying Process. In Engineering, Technology & Applied Science Research (Vol. 10, Issue 2, pp. 5554–5560). Engineering, Technology & Applied Science Research. https://doi.org/10.48084/etasr.3486

30. Ismoilov, R. (2025). Simulation of fruit drying process in vacuum drying equipment in comsol software. Journal of Applied Science and Social Science, 1(1), 256–262. Current Research Journals

Publisher Retrieved from: https://inlibrary.uz/index.php/jasss/article/view/71849

31. Yerri Veeresh, M., Bhaskar Reddy, V. N., & Kiranmayi, R. (2022). Modeling and Analysis of Time Response Parameters of a PMSM-Based Electric Vehicle with PI and PID Controllers. In Engineering, Technology & Applied Science Research (Vol. 12, Issue 6, pp. 9737–9741). Engineering, Technology & Applied Science Research. https://doi.org/10.48084/etasr.5321

32. Bardavelidze, A., Bardavelidze, Kh. (2017). Research Investigation on Automatic Control System of Drying Apparatus Based on Fuzzy Logic. In Journal of Technical Science and Technologies (Vol. 6, Issue 1). International Black Sea University. https://doi.org/10.31578/jtst.v6i1.119

33. García-Martínez, J. R., Cruz-Miguel, E. E., Carrillo-Serrano, R. V., Mendoza-Mondragón, F., Toledano-Ayala, M., & Rodríguez-Reséndiz, J. (2020). A PID-Type Fuzzy Logic Controller-Based Approach for Motion Control Applications. In Sensors (Vol. 20, Issue 18, p. 5323). MDPI AG. https://doi.org/10.3390/s20185323

34. Gundogdu, A., & Celikel, R. (2021). NARMA-L2 controller for stepper motor used in single link manipulator with low-speed-resonance damping. In Engineering Science and Technology, an International Journal (Vol. 24, Issue 2, pp. 360–371). Elsevier BV. https://doi.org/10.1016/j.jestch.2020.09.008

35. Nayak, J., Vakula, K., Dinesh, P., Naik, B., Pelusi, D. (2020). Intelligent food processing: Journey from artificial neural network to deep learning. Intelligent food processing (Vol. 38, p. 100297). https://doi.org/10.1016/j.cosrev.2020.100297

36. Moysis, L., Tsiaousis, M., Charalampidis, N., Eliadou, M., & Kafetzis, I. (2015). An Introduction to Control Theory Applications with Matlab. Unpublished. https://doi.org/10.13140/RG.2.1.3926.8243

37. Maki, G. I., & Hussain, Z. M. (2021). Deep Learning for Control of Digital Systems. In Journal of Physics: Conference Series (Vol. 1804, Issue 1, p. 012086). IOP Publishing. https://doi.org/10.1088/1742-6596/1804/1/012086

38. Vasilyev, S. N., Kudinov, Yu. I., Pashchenko, F. F., Durgaryan, I. S., Kelina, A. Yu., Kudinov, I. Yu., & Pashchenko, A. F. (2020). Intelligent Control Systems and Fuzzy Controllers. I. Fuzzy Models, Logical-Linguistic and Analytical Regulators. In Automation and Remote Control (Vol. 81, Issue 1, pp. 171–191). Pleiades Publishing Ltd. https://doi.org/10.1134/s0005117920010142

39. Pedraza, L. F., Hernández, H. A., & Hernández, C. A. (2020). Artificial Neural Network Controller for a Modular Robot Using a Software Defined Radio Communication System. In Electronics (Vol. 9, Issue 10, p. 1626). MDPI AG. https://doi.org/10.3390/electronics9101626

40. Nguyen, A.-T., Taniguchi, T., Eciolaza, L., Campos, V., Palhares, R., & Sugeno, M. (2019). Fuzzy Control Systems: Past, Present and Future. In IEEE Computational Intelligence Magazine (Vol. 14, Issue 1, pp. 56–68). Institute of Electrical and Electronics Engineers (IEEE). https://doi.org/10.1109/mci.2018.2881644

41. Yusupbekov, A. N., Sevinov, J. U., Mamirov, U. F., & Botirov, T. V. (2021). Synthesis Algorithms for Neural Network Regulator of Dynamic System Control. In Advances in Intelligent Systems and Computing (pp. 723–730). Springer International Publishing. https://doi.org/10.1007/978-3-030-64058-3_90

42. Bhagya Raj, G. V. S., & Dash, K. K. (2020). Comprehensive study on applications of artificial neural network in food process modeling. Critical Reviews in Food Science and Nutrition, (Vol. 62(10), pp. 2756–2783). https://doi.org/10.1080/10408398.2020.1858398

43. Lisovsky, A. L. (2021). Application of neural network technologies for management development of systems. In Strategic decisions and risk management (Vol. 11, Issue 4, pp. 378–389). Real Economy Publishing. In Russian. https://doi.org/10.17747/2618-947x-923

Downloads

Published

2025-06-04

Issue

Vol. 19 (2025): Scifood

Section

Articles

License

Copyright (c) 2025 Avtandil Bardavelidze, Khatuna Bardavelidze, Otari Sesikashvili (Author)

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

This license permits non-commercial re-use, distribution, and reproduction in any medium, provided the original work is properly cited, and is not altered, transformed, or built upon in any way.

How to Cite

Synthesis and research of the intelligent automatic control system for a fruit drying apparatus. (2025). Scifood, 19(1), 343-359. https://doi.org/10.5219/scifood.42

Most read articles by the same author(s)

Similar Articles

You may also start an advanced similarity search for this article.