Fractional-order PID control for elevation and azimuth in a twin rotor system

Wendimu, Abebe Alemu; Matušů, Radek; Shaikh, Ibrahim; Kebede, Zeru Kifle

dc.title	Fractional-order PID control for elevation and azimuth in a twin rotor system	en
dc.contributor.author	Wendimu, Abebe Alemu
dc.contributor.author	Matušů, Radek
dc.contributor.author	Shaikh, Ibrahim
dc.contributor.author	Kebede, Zeru Kifle
dc.relation.ispartof	Scientific Reports
dc.identifier.issn	2045-2322 Scopus Sources, Sherpa/RoMEO, JCR
dc.date.issued	2025
utb.relation.volume	15
utb.relation.issue	1
dc.type	article
dc.language.iso	en
dc.publisher	Nature Research
dc.identifier.doi	10.1038/s41598-025-18763-8
dc.relation.uri	https://www.nature.com/articles/s41598-025-18763-8
dc.relation.uri	https://www.nature.com/articles/s41598-025-18763-8.pdf
dc.subject	FOPID	en
dc.subject	fractional order	en
dc.subject	IOPID	en
dc.subject	identification	en
dc.subject	optimization techniques	en
dc.description.abstract	This paper presents a real-time application of fractional-order PID (FOPID or PID) control for a twin rotor system, optimizing performance beyond conventional PID approaches. A linear model identification is first performed using a black-box approach, with a detailed examination of the system’s static properties. The primary aim is to implement PID control, where the fractional orders and correspond to the integral and derivative components, respectively, offering enhanced flexibility in system dynamics tuning. The proposed control strategy is validated through experiments on a laboratory-scale twin rotor benchmark. Controller parameters are optimized using advanced algorithms, including Particle Swarm Optimization (PSO), Genetic Algorithm (GA), and the Nelder-Mead (NM) method. These algorithms minimize time-domain performance metrics such as Integral of Absolute Error (IAE), Integral of Time-weighted Squared Error (ITSE), Integral of Squared Error (ISE), and Integral of Time-weighted Absolute Error (ITAE). Notably, the optimized GA-based FOPID controller achieves an IAE performance index of 180.33 for the FOPID in elevation. The GA-based FOPID tuning is particularly effective for IAE performance in the azimuth, yielding a value of 109.2, compared to the GA-based IOPID, which results in a value of 247.05. Additionally, the least performance index is observed when comparing the PSO and NM-based FOPID tuning across all performance indexes. These results demonstrate that the FOPID controller significantly enhances control precision and stability in the twin rotor system, highlighting the potential of fractional-order control (FOC) in real-time applications.	en
utb.faculty	Faculty of Applied Informatics
dc.identifier.uri	http://hdl.handle.net/10563/1012749
utb.identifier.obdid	43886429
utb.identifier.scopus	2-s2.0-105017633710
utb.identifier.wok	001586154100036
utb.identifier.pubmed	41023147
utb.source	j-scopus
dc.date.accessioned	2026-02-19T10:08:26Z
dc.date.available	2026-02-19T10:08:26Z
dc.description.sponsorship	This work was supported by the Internal Grant Agency of Tomas Bata University in Zl\u00EDn under project number IGA/CebiaTech/2024/001. The authors would also like to thank the anonymous reviewers and editors for their valuable comments and constructive feedback, which greatly improved the quality of the manuscript.
dc.description.sponsorship	Internal Grant Agency of Tomas Bata University in Zlin [IGA/CebiaTech/2024/001]
dc.rights	Attribution-NonCommercial-NoDerivatives 4.0 International
dc.rights.uri	http://creativecommons.org/licenses/by-nc-nd/4.0/
dc.rights.access	openAccess
utb.ou	Department of Automation and Control Engineering
utb.contributor.internalauthor	Wendimu, Abebe Alemu
utb.contributor.internalauthor	Matušů, Radek
utb.contributor.internalauthor	Shaikh, Ibrahim
utb.fulltext.affiliation	Abebe Alemu Wendimu 1 , Radek Matušů 1✉ , Ibrahim Shaikh 1 & Zeru Kifle Kebede 2 1 Department of Automation and Control Engineering, Faculty of Applied Informatics, Tomas Bata University in Zlín, nám. T. G. Masaryka 5555, 760 01 Zlín, Czech Republic. 2 Faculty of Economics and Administration, Department of System Engineering and Informatics, University of Pardubice, Studentska 84, 532 10 Pardubice, Czech Republic. ✉ email: rmatusu@utb.cz
utb.fulltext.dates	Received: 5 May 2025 Accepted: 3 September 2025 Published online: 29 September 2025
utb.fulltext.references	1. Chen, Y., Petras, I. & Xue, D. Fractional order control-a tutorial. In 2009 American control conference, 1397–1411 (IEEE, 2009). 2. Oustaloup, A., Levron, F., Mathieu, B. & Nanot, F. M. Frequency-band complex noninteger differentiator: characterization and synthesis. IEEE Trans. Circuits Syst. I: Fundamental Theory Appl. 47, 25–39 (2000). 3. Ladaci, S. & Bensafia, Y. Indirect fractional order pole assignment based adaptive control. Eng. Sci. Technol. Int. J. 19, 518–530 (2016). 4. Malek, H., Luo, Y. & Chen, Y. Identification and tuning fractional order proportional integral controllers for time delayed systems with a fractional pole. Mechatronics 23, 746–754 (2013). 5. Razminia, A. & Torres, D. F. Control of a novel chaotic fractional order system using a state feedback technique. Mechatronics 23, 755–763 (2013). 6. Yu, P., Li, J. & Li, J. The active fractional order control for maglev suspension system. Math. Probl. Eng. 2015, 129129 (2015). 7. Kumar, P., Narayan, S. & Raheja, J. Optimal design of robust fractional order pid for the flight control system. Int. J. Comput. Appl. 128, 31–35 (2015). 8. Fei, L., Wang, J., Zhang, L., Ge, Y. & Li, K. Fractional-order pid control of hydraulic thrust system for tunneling boring machine. In Intelligent Robotics and Applications, 470–480 (Springer (eds Lee, J. et al.) (Berlin Heidelberg, Berlin, Heidelberg, 2013). 9. Tejado, I., Valerio, D., Pires, P. & Martins, J. Fractional order human arm dynamics with variability analyses. Mechatronics 23, 805–812 (2013). 10. Silva, M. F., Machado, J. T. & Lopes, A. Fractional order control of a hexapod robot. Nonlinear Dyn. 38, 417–433 (2004). 11. Manabe, S. The non-integer integral and its application to control systems. J. IEE Japan 80, 589–597 (1960). 12. Oustaloup, A., Melchior, P., Lanusse, P., Cois, O. & Dancla, F. The crone toolbox for matlab. In CACSD 2000. IEEE International Symposium on Computer-Aided Control System Design, 190–195 (IEEE, 2000). 13. Lurie, B. J. Three-parameter tunable tilt-integral-derivative (tid) controller. Unpublished technical report or proprietary documentation (1994). 14. Podlubny, I. Fractional-order systems and fractional-order controllers. Inst. Exp. Physics, Slovak Acad. Sci. Kosice 12, 1–18 (1994). 15. Tepljakov, A., Petlenkov, E., Belikov, J. & Finajev, J. Fractional-order controller design and digital implementation using fomcon toolbox for matlab. In 2013 IEEE conference on computer aided control system design (CACSD), 340–345 (IEEE, 2013). 16. Tepljakov, A. & Tepljakov, A. Fomcon: fractional-order modeling and control toolbox. Fractional-order modeling and control of dynamic systems. In 107–129 (2017). 17. Dorcak, L. Numerical models for the simulation of the fractional-order control systems. arXiv preprint arXiv:math/0204108 (2002). 18. Monje, C. A., Vinagre, B. M., Feliu, V. & Chen, Y. Tuning and auto-tuning of fractional order controllers for industry applications. Control Eng. Pract. 16, 798–812 (2008). 19. Rahideh, A., Shaheed, M. H. & Huijberts, H. J. C. Dynamic modelling of a trms using analytical and empirical approaches. Control Eng. Pract. 16, 241–259 (2008). 20. Dragos, C.-A., Precup, R.-E., Preitl, S., Petriu, E. M. & Stinean, A.-I. Takagi-sugeno fuzzy control solutions for mechatronic applications. Int. J. Artif. Intell. 8, 45–65 (2012). 21. Coelho, J. et al. Application of fractional algorithms in the control of a twin rotor multiple input-multiple output system. ENOC 2008, 1–8 (2008). 22. Doğruer, T. & Tan, N. Real time control of twin rotor mimo system with pid and fractional order pid controller. Mugla J. Sci. Technol. 6, 1–9 (2020). 23. Ijaz, S., Hamayun, M. T., Yan, L. & Mumtaz, M. F. Fractional order modeling and control of twin rotor aerodynamic system using nelder-mead optimization. J. Electr. Eng. Technol. 11, 1863–1871 (2016). 24. Hore, A., Kumar, M. R. & Mishra, S. K. Parameter estimation for fractional-order with delay model of twin rotor mimo system. In 2021 IEEE 4th International Conference on Computing, Power and Communication Technologies (GUCON), 1–5 (IEEE, 2021). 25. Jabari, M. et al. An advanced pid tuning method for temperature control in electric furnaces using the artificial rabbits optimization algorithm. Int. J. Dyn. Control 13, 1–15 (2025). 26. Wendimu, A. A. Modeling and fractional-order control of twin rotor mimo system. Master’s thesis, Tomas Bata University in Zlín (2022). 27. Wendimu, A. A., Shaikh, I., Zerdazi, E. W. & Matúšu, R. Modeling, identification and analysis of twin rotor mimo systems. In Computer Science On-line Conference, 457–471 (Springer, 2024). 28. Shahri, M. E., Balochian, S., Balochian, H. & Zhang, Y. Design of fractional order pid controllers for time delay systems using differential evolution algorithm. Indian journal Sci. Technol. 7, 1307–1315 (2014). 29. Rezaei Estakhrouiyeh, M., Gharaveisi, A. & Vali, M. Fractional order proportional-integral-derivative controller parameter selection based on iterative feedback tuning. case study. Ball levitation system. Trans. Inst. Meas. Control 40, 1776–1787 (2018). 30. Jaiswal, S., Suresh Kumar, C., Seepana, M. M. & Babu, G. U. B. Design of fractional order pid controller using genetic algorithm optimization technique for nonlinear system. Chem. Prod. Process Model. 15, 20190072 (2020). 31. Eltayeb, A., Ahmed, G., Imran, I. H., Alyazidi, N. M. & Abubaker, A. Comparative analysis: Fractional pid vs. pid controllers for robotic arm using genetic algorithm optimization. Automation 5, 230–245 (2024). 32. Chakraborty, S. & Mondal, A. Tsa-aided it2flc-(1+ pd)-fopid control for regulating the first-order plus time-delayed non-conventional multi-area power system with deregulation. Electrical Engineering 1–21 https://doi.org/10.1007/s00202-025-03103-w (2025). 33. Mondal, A. & Chakraborty, S. Design of two-loop fopid-fopi controller for inverted cart-pendulum system. Eng. Res. Express 6, 035354 (2024). 34. Idir, A. et al. Pid controller design with a new method based on fractionalized integral gain for cruise control system. In 2024 IEEE International Conference on Environment and Electrical Engineering and 2024 IEEE Industrial and Commercial Power Systems Europe (EEEIC/I &CPS Europe), 1–6 (IEEE, 2024). 35. Abdulwahhab, O. W. Design of a complex fractional order pid controller for a first order plus time delay system. ISA transactions 99, 154–158 (2020). 36. Shah, P., Sekhar, R., Iswanto, I. & Shah, M. Complex order pi a+ jb d c+ jd controller design for a fractional order dc motor system. Adv. Sci. Technol. Eng. Syst. J. 6, 541–551 (2021). 37. Shah, P. & Agashe, S. Experimental analysis of fractional pid controller parameters on time domain specifications. Prog.Fract. Differ. Appl. 3, 141–154 (2017). 38. Mondal, R. & Dey, J. A novel design methodology on cascaded fractional order (fo) pi-pd control and its real time implementation to cart-inverted pendulum system. ISA transactions 130, 565–581 (2022). 39. Shanthini, C., Devi, V. K., Rajendran, S. & Jena, D. Comparative analysis of pid, i-pd and fractional order pi-pd for a dc-dc converter. In 2022 IEEE North Karnataka Subsection Flagship International Conference (NKCon), 1–5 (IEEE, 2022). 40. Muresan, C. I., Dulf, E. H. & Both, R. Vector-based tuning and experimental validation of fractional-order pi/pd controllers. Nonlinear Dyn. 84, 179–188 (2016). 41. Roong, A. S. C., Shin-Homg, C. & Said, M. A. B. Position control of a magnetic levitation system via a pi-pd control with feedforward compensation. In 2017 56th Annual Conference of the Society of Instrument and Control Engineers of Japan (SICE), 73–78 (IEEE, 2017). 42. Bingi, K., Ibrahim, R., Karsiti, M. N., Hassan, S. M. & Harindran, V. R. Real-time control of pressure plant using 2dof fractional-order pid controller. Arab. J. for Sci. Eng. 44, 2091–2102 (2019). 43. Ozyetkin, M. M. A simple tuning method of fractional order pi λ -pd µ controllers for time delay systems. ISA transactions 74, 77–87 (2018). 44. Bin Roslan, M. N., Bingi, K., Devan, P. A. M. & Ibrahim, R. Design and development of complex-order pi-pd controllers: Case studies on pressure and flow process control. Appl. Syst. Innov. 7, 33 (2024). 45. Affenzeller, M. et al. White box vs. black box modeling: On the performance of deep learning, random forests, and symbolic regression in solving regression problems. In International Conference on Computer Aided Systems Theory, 288–295 (Springer, 2019). 46. Bingi, K., Rajanarayan Prusty, B. & Pal Singh, A. A review on fractional-order modelling and control of robotic manipulators. Fractal Fract. 7, 77 (2023). 47. Krell, M. & Hergert, S. The black box approach: Analyzing modeling strategies. In Towards a Competence-Based View on Models and Modeling in Science Education, 147–160 (Springer, 2019). 48. Wendimu, A.A., Matušů, R., Shaikh, I., Wolde, M.K. (2025). Fractional-Order Identification and Analysis of Elevation and Azimuth Dynamics in a Twin Rotor System. In: Arai, K. (eds) Intelligent Systems and Applications. IntelliSys 2025. Lecture Notes in Networks and Systems, vol 1567. Springer, Cham. https://doi.org/10.1007/978-3-032-00071-2_37 49. Eykhoff, P. System identification? a survey. Automatica 7, 123–162 (1971). 50. Åström, K. J. & Hägglund, T. Advanced PID control (Systems and Automation Society, ISA-The Instrumentation, 2006). 51. Podlubny, I. Fractional-order systems and pi/sup/spl lambda//d/sup/spl mu//-controllers. IEEE Trans. Autom. Control 44, 208–214 (1999). 52. Faieghi, M. R. & Nemati, A. On fractional-order pid design. In Applications of MATLAB in Science and Engineering (IntechOpen, 2011). 53. Monje, C. A., Chen, Y., Vinagre, B. M., Xue, D. & Feliu-Batlle, V. Fractional-order systems and controls: fundamentals and applications (Springer Science & Business Media, 2010). 54. Oustaloup, A., Levron, F., Mathieu, B. & Nanot, F. M. Frequency-band complex noninteger differentiator: characterization and synthesis. IEEE Transactions on circuits and systems I: Fundamental theory and applications 47, 25–39 (2002). 55. Xue, D., Zhao, C. & Chen, Y. A modified approximation method of fractional order system. In 2006 international conference on mechatronics and automation, 1043–1048 (IEEE, 2006). 56. Idir, A., Bensafia, Y., Khettab, K. & Canale, L. Performance improvement of aircraft pitch angle control using a new reduced order fractionalized pid controller. Asian J. Control. 25, 2588–2603 (2023). 57. Shah, P., Agashe, S. & Vyawahare, V. System identification with fractional-order models: A comparative study with different model structures. Prog. Fract. Differ. Appl. 4, 533–552 (2019). 58. Ang, K. H., Chong, G. & Li, Y. Pid control system analysis, design, and technology. IEEE Trans. Control Syst. Technol. 13, 559–576 (2005). 59. Normey-Rico, J. E. & Camacho, E. F. Control of dead-time processes (Springer, 2007). 60. Lucus, P., Webber, S. & Chew, J. PAC 2003: Proceedings of the 2003 Particle Accelerator Conference (IEEE, 2003). 61. Vilanova, R. & Visioli, A. PID control in the third millennium, vol. 75 (Springer, 2012). 62. Simpkins, A. System identification: Theory for the user, (ljung, l. 1999)[on the shelf]. IEEE Robot. Autom. Mag. 19, 95–96 (2012). 63. Wendimu, A. A., Shaikh, I., Zerdazi, W., Matušů, R., Silhavy, R., Silhavy, P. Software Engineering Methods Design and Application: Proceedings of 13th Computer Science Online Conference 2024 Volume 1 Modeling Identification and Analysis of Twin Rotor MIMO Systems Springer Nature Switzerland Cham, 457–471 (2024).
utb.fulltext.sponsorship	This work was supported by the Internal Grant Agency of Tomas Bata University in Zlín under project number IGA/CebiaTech/2024/001. The authors would also like to thank the anonymous reviewers and editors for their valuable comments and constructive feedback, which greatly improved the quality of the manuscript.
utb.wos.affiliation	[Wendimu, Abebe Alemu; Matusu, Radek; Shaikh, Ibrahim] Tomas Bata Univ Zlin, Fac Appl Informat, Dept Automat & Control Engn, Nam TG Masaryka 5555, Zlin 76001, Czech Republic; [Kebede, Zeru Kifle] Univ Pardubice, Fac Econ & Adm, Dept Syst Engn & Informat, Studentska 84, Pardubice 53210, Czech Republic
utb.scopus.affiliation	Department of Automation and Control Engineering, Tomas Bata University in Zlin, Zlin, Czech Republic; Institute of System Engineering and Informatics, Univerzita Pardubice, Pardubice, Czech Republic
utb.fulltext.projects	IGA/CebiaTech/2024/001
utb.fulltext.faculty	Faculty of Applied Informatics
utb.fulltext.faculty	Faculty of Applied Informatics
utb.fulltext.faculty	Faculty of Applied Informatics
utb.fulltext.ou	Department of Automation and Control Engineering
utb.fulltext.ou	Department of Automation and Control Engineering
utb.fulltext.ou	Department of Automation and Control Engineering