Predictive Functional Control With Reduced-Order Observer Design Using Particle Swarm Optimization For Pneumatic System
The pneumatic actuator is widely used in the automation industry and the field of automatic control, especially in positioning control, is highly in demand. However, the pneumatic actuator has difficulties to control due to the nonlinear factors such as air compressibility and friction. Therefore, t...
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T Technology (General) TJ Mechanical engineering and machinery Abd Rahman, Azira Predictive Functional Control With Reduced-Order Observer Design Using Particle Swarm Optimization For Pneumatic System |
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The pneumatic actuator is widely used in the automation industry and the field of automatic control, especially in positioning control, is highly in demand. However, the pneumatic actuator has difficulties to control due to the nonlinear factors such as air compressibility and friction. Therefore, this research will design a controller that focused on positioning control of Intelligent Pneumatic Actuator (IPA). This research aimed to develop a Predictive Functional Control using Reduced-Order Observer (PFC-ROO) to reduce the complexity of the pneumatic system. An optimization technique will be implemented in this project using Particle Swarm Optimization (PSO) algorithm. PSO is used to tuning the value of parameter time constant in Predictive Functional Control (PFC) to solve the problem for manual tuning. PSO will identify the best value of the parameter time constant associated with PFC for both PFC-ROO and PFC-FOO. Development of PFC-ROO algorithm is considered as a new control strategy for Intelligent Pneumatic Actuator (IPA) system for position control. This research is used the MATLAB/Simulink as a platform. The simulation results for both controllers will then be evaluated and validated using Data Acquisition (DAQ) card with a real-time experiment. In the real-time experiment, the horizontal position will be tested with different loads. Then, the result has been compared and validated the performance based on transient response analysis with existing controller Predictive Functional Control with Full-order Observer (PFC-FOO). The development will be analyzed in terms of smaller steady-state error (ess), 0 overshoot (%OS), faster settling time (Ts) and rise time (Tr) in simulation and real-time experiment. The result shows that the new development of PFC-ROO with optimization technique offers better performance compared to existing controller PFC-FOO with PSO. The best result for PFC-ROO, ess is 0.11 mm, %OS is 0%, Ts is 0.9247 seconds and Tr is 0.6620 seconds when time constant equal to 0.9023 where the best result for PFC-FOO when time constant equal to 0.9062 the ess is 0.25 mm, OS is 0%, Ts is 0.9192 seconds and Tr is 0.6638 seconds. The results revealed that the new method can reduce error by up to 56% of steady-state error. |
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Abd Rahman, Azira |
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Predictive Functional Control With Reduced-Order Observer Design Using Particle Swarm Optimization For Pneumatic System |
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Predictive Functional Control With Reduced-Order Observer Design Using Particle Swarm Optimization For Pneumatic System |
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Predictive Functional Control With Reduced-Order Observer Design Using Particle Swarm Optimization For Pneumatic System |
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Predictive Functional Control With Reduced-Order Observer Design Using Particle Swarm Optimization For Pneumatic System |
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Predictive Functional Control With Reduced-Order Observer Design Using Particle Swarm Optimization For Pneumatic System |
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predictive functional control with reduced-order observer design using particle swarm optimization for pneumatic system |
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Universiti Teknikal Malaysia Melaka |
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Faculty of Electronics and Computer Engineering |
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2020 |
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my-utem-ep.254522021-12-12T22:33:34Z Predictive Functional Control With Reduced-Order Observer Design Using Particle Swarm Optimization For Pneumatic System 2020 Abd Rahman, Azira T Technology (General) TJ Mechanical engineering and machinery The pneumatic actuator is widely used in the automation industry and the field of automatic control, especially in positioning control, is highly in demand. However, the pneumatic actuator has difficulties to control due to the nonlinear factors such as air compressibility and friction. Therefore, this research will design a controller that focused on positioning control of Intelligent Pneumatic Actuator (IPA). This research aimed to develop a Predictive Functional Control using Reduced-Order Observer (PFC-ROO) to reduce the complexity of the pneumatic system. An optimization technique will be implemented in this project using Particle Swarm Optimization (PSO) algorithm. PSO is used to tuning the value of parameter time constant in Predictive Functional Control (PFC) to solve the problem for manual tuning. PSO will identify the best value of the parameter time constant associated with PFC for both PFC-ROO and PFC-FOO. Development of PFC-ROO algorithm is considered as a new control strategy for Intelligent Pneumatic Actuator (IPA) system for position control. This research is used the MATLAB/Simulink as a platform. The simulation results for both controllers will then be evaluated and validated using Data Acquisition (DAQ) card with a real-time experiment. In the real-time experiment, the horizontal position will be tested with different loads. Then, the result has been compared and validated the performance based on transient response analysis with existing controller Predictive Functional Control with Full-order Observer (PFC-FOO). The development will be analyzed in terms of smaller steady-state error (ess), 0 overshoot (%OS), faster settling time (Ts) and rise time (Tr) in simulation and real-time experiment. The result shows that the new development of PFC-ROO with optimization technique offers better performance compared to existing controller PFC-FOO with PSO. The best result for PFC-ROO, ess is 0.11 mm, %OS is 0%, Ts is 0.9247 seconds and Tr is 0.6620 seconds when time constant equal to 0.9023 where the best result for PFC-FOO when time constant equal to 0.9062 the ess is 0.25 mm, OS is 0%, Ts is 0.9192 seconds and Tr is 0.6638 seconds. The results revealed that the new method can reduce error by up to 56% of steady-state error. 2020 Thesis http://eprints.utem.edu.my/id/eprint/25452/ http://eprints.utem.edu.my/id/eprint/25452/1/Predictive%20Functional%20Control%20With%20Reduced-Order%20Observer%20Design%20Using%20Particle%20Swarm%20Optimization%20For%20Pneumatic%20System.pdf text en public http://eprints.utem.edu.my/id/eprint/25452/2/Predictive%20Functional%20Control%20With%20Reduced-Order%20Observer%20Design%20Using%20Particle%20Swarm%20Optimization%20For%20Pneumatic%20System.pdf text en validuser https://plh.utem.edu.my/cgi-bin/koha/opac-detail.pl?biblionumber=119758 mphil masters Universiti Teknikal Malaysia Melaka Faculty of Electronics and Computer Engineering Osman, Khairuddin 1. Adam, A., Faiz, A., Abidin, Z., Ibrahim, Z., Husain, A. R., Yusof, Z. and Ibrahim, I., 2010. A Particle Swarm Optimization Approach to Robotic Drill Route Optimization. In: AMS2010: Asia Modelling Symposium 2010 - 4th International Conference on Mathematical Modelling and Computer Simulation, pp. 60–64. doi: 10.1109/AMS.2010.25. 2. Ali, H. I., Bahari, S., Noor, B. M., Bashi, S. M. and Marhaban, M. H., 2009. A Review of Pneumatic Actuators (Modeling and Control), Australian Journal of Basic and Applied Sciences, 3(2), pp. 440–454. 3. Ali, H. I., Bahari, S., Noor, B. M., Bashi, S. M. and Marhaban, M. H., 2009. Mathematical and Intelligent Modeling of Electropneumatic Servo Actuator Systems, Australian Journal of Basic and Applied Sciences, 3(4), pp. 3663–3671. 4. Ayob, M. N., Yusof, Z., Adam, A., Faiz, A., Abidin, Z., Ibrahim, I., Ibrahim, Z., Sudin, S. and Hani, M. K., 2010. A Particle Swarm Optimization Approach for Routing in VLSI, In: 2nd International Conference on Computational Intelligence, Communication Systems and Networks, Liverpool, UK, 28-30 July 2010, pp. 49–53. doi: 10.1109/CICSyN.2010.42. 5. Bonfiglio, A. and Invernizzi, M., 2018. Model Predictive Control Application for the Control of a Grid-Connected Synchronous Generator, 2018 International Electrical Engineering Congress (iEECON). IEEE, pp. 1–4. 6. Cui, Z., Zeng, J. and Yin, Y., 2008. An improved PSO with time-varying accelerator coefficients. In: Eighth International Conference on Intelligent Systems Design and Applications, Kaohsiung, Taiwan, 26-28 Nov 2008, IEEE doi: 10.1109/ISDA.2008.86. 7. Fang, G., Kwok, N. M. and Ha, Q., 2008. Automatic fuzzy membership function tuning using the particle swarm optimisation. Proceedings - 2008 Pacific-Asia Workshop on Computational Intelligence and Industrial Application, PACIIA 2008, 2, pp. 324–328. doi: 10.1109/PACIIA.2008.105. 8. Fatimah, S., Rahmat, M. F., Athif, A., Faudzi, M. and Osman, K., 2015. Design of Unconstrained and Constrained Model Predictive Control for Pneumatic Actuator System : Set-Point Tracking, 2015 IEEE Conference on Systems, Process and Control (ICSPC 2015), December 2014, pp. 18–20. doi: 10.1109/SPC.2015.7473569. 9. Faudzi, M., Suzomori. K., 2010. Programmable System on Chip Distributed Communication and Control Approach for Human Adaptive Mechanical System, Department of Intelligent Mechanical Systems, Graduate School of Natural Science and Technology, 6(8), pp. 852–861. Available at: http://link.springer.com/10.1007/978-1- 84882-493-5. 10. Faudzi, A.A.M, Osman., 2013. Real-time position control of intelligent pneumatic actuator (IPA) system using optical encoder and pressure sensor, Sensor Review, No. 4, pp. 341– 351. doi: 10.1108/SR-09-2012-692. 11. Faudzi, A.AM., Osman, K., Rahmat, M. F., Mustafa, D., Azman, M. A. and Suzumori, K., 2012. Nonlinear Mathematical Model of an Intelligent Pneumatic Actuator (IPA) Systems: Position and Force Controls, In: IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM), Kachsiung, Taiwan, 11-14 July 2012, pp. 1105–1110, doi: 10.1109/AIM.2012.6266014. 12. Faudzi, A. A. M., Suzumori, K. and Wakimoto, S., 2010. Development of an intelligent chair tool system applying new intelligent pneumatic actuators, Advanced Robotics, 24(10), pp. 1503–1528. doi: 10.1163/016918610X505602. 13. Faudzi, A. A. M., Suzumori, K. and Wakimoto, S., 2008. Distributed physical human machine interaction using intelligent pneumatic cylinders, 2008 International Symposium on Micro-NanoMechatronics and Human Science, MHS 2008, pp. 249–254. doi: 10.1109/MHS.2008.4752458. 14. Faudzi, A. A. M., Osman, K. Bin, Rahmat, M. F., Mustafa, N. D., Azman, M. A. and Suzumori, K., 2012. Controller design for simulation control of Intelligent Pneumatic Actuators (IPA) system, Procedia Engineering, 41(Iris), pp. 593–599. doi: 10.1016/j.proeng.2012.07.217. 15. Gu, D., Zhang, J. and Gu, J., 2015. Brushless DC motor speed control based on predictive functional control, Proceedings of the 2015 27th Chinese Control and Decision Conference, CCDC 2015, (4), pp. 3456–3458. doi: 10.1109/CCDC.2015.7162520. 16. Gopal, M., 2003. Digital Control and State Variable Methods, 2nd ed. Tata McGraw-Hill, pp. 998. 17. Haber, R., Schmitz, U. and Zabet, K., 2014. Implementation of PFC (Predictive Functional Control) in a petrochemical plant, IFAC Proceedings Volumes (IFAC-PapersOnline). IFAC. doi: 10.3182/20140824-6-ZA-1003.02440. 18. Hashizume, S., 2015. Development of a Predictive Functional Control Technique and Practical Applications to to Chemical Processes, In: Production & Safety Fundamental Technology Center, R&D Report, Sumitomo Kagaku”, vol. 2015, pp. 1–9. 19. Hurel, J., Mandow, A. and Garcia-Cerezo, A., 2012. Tuning a fuzzy controller by particle swarm optimization for an active suspension system, IECON 2012 - 38th Annual Conference on IEEE Industrial Electronics Society, pp. 2524–2529. doi: 10.1109/IECON.2012.6388697. 20. Izzuddin, N. H., Faudzi, A. ’Athif M., Johari, M. R. and Osman, K., 2015. System identification and predictive functional control for electro-hydraulic actuator system, 2015 IEEE International Symposium on Robotics and Intelligent Sensors (IRIS), (1), pp. 138– 143. doi: 10.1109/IRIS.2015.7451600. 21. Kaitwanidvilai, S. and Olranthichachat, P., 2011. Mechatronics Robust loop shaping – fuzzy gain scheduling control of a servo-pneumatic system using particle swarm optimization approach, Mechatronics. Elsevier Ltd, 21(1), pp. 11–21. doi: 10.1016/j.mechatronics.2010.07.010. 22. Khairuddin I, Ahmad Dahalan A, Abidin A, Lai Y, Nordin N, Sulaiman S, Jaafar H, Mohamad S, Amer N., 2014. Modeling and Simulation of Swarm Intelligence Algorithms for Parameters Tuning of PID Controller in Industrial Couple Tank System, Advanced Materials Research, 903 pp. 321–326. doi:10.4028/www.scientific.net/AMR.903.321. 23. K. Osman., Athif, A., Faudzi, M., Rahmat, M. F., Mustafa, D., Azman, M. A. Suzumori, K., 2012. System Identification Model for an Intelligent Pneumatic Actuator (IPA) System, In: IEEE/RSJ International Conference on Intelligent Robots and Systems, Vilamoura, Portugal, 7-12 Oct 2012, doi:10.1109/IROS.2012.6385751. 24. Ljung, L., 2015. System Identification Toolbox TM User ’ s Guide, The MathWorks, Inc, R2015a. 25. Lai, J.-Y., Menq, C.-H. and Singh, R., 1990. Accurate Position Control of a Pneumatic Actuator, Journal of Dynamic Systems, Measurement, and Control, 112(4), pp. 734-739. doi: 10.1115/1.2896202. 26. Liu, Y., Tong, S., Wang, D., Li, T. and Chen, C. L. P., 2011. Adaptive Neural Output Feedback Controller Design with Reduced-Order Observer for a Class of Uncertain Nonlinear SISO Systems. In: IEEE Transactions on Neural Networks , 22(8), pp. 1328– 1334. doi: 10.1109/TNN.2011.2159865. 27. Liu, Y. J., Tong, S. and Chen, C. L. P., 2013. Adaptive fuzzy control via observer design for uncertain nonlinear systems with unmodeled dynamics, IEEE Transactions on Fuzzy Systems, 21(2), pp. 275–288. doi: 10.1109/TFUZZ.2012.2212200. 28. Meghrajani, P. K. and Munje, R. K., 2018. Conceptualizing Full and Reduced Order Linear Observers Using MATLAB GUI, 2018 International Conference On Advances in Communication and Computing Technology, ICACCT 2018. IEEE, (3), pp. 1–6. doi: 10.1109/ICACCT.2018.8529332. 29. Najib, S., Salim, S., Fuad, M., Athif, A., Faudzi, M., Ismail, Z. H. and Sunar, N., 2014. Position Control of Pneumatic Actuator Using Self-Regulation Nonlinear PID, IN: Mathematical Problems in Engineering, 2014, Article ID 957041. 30. Osman, K., Mustafa, D. and Suzumori, K., 2013. Predictive Functional Controller Design for Pneumatic Actuator with Stiffness Characteristic, Proceedings of the 2013 IEEE/SICE International Symposium on System Integration, Kobe, Japan, 15-17 Dec. 2013, pp. 641– 646. doi: 10.1109/SII.2013.6776700. 31. Osman, K., Faudzi, A. ’Athif M., Rahmat, M. F., Hikmat, O. F. and Suzumori, K., 2014. Predictive Functional Control with Observer (PFC-O) Design and Loading Effects Performance for a Pneumatic System, Arabian Journal for Science and Engineering, 40(2), pp. 633–643. doi: 10.1007/s13369-014-1421-z. 32. Osman, K., Mohd Faudzi, A. A., Rahmat, M. F. and Suzumori, K., 2014. System identification and embedded controller design for pneumatic actuator with stiffness characteristic, Mathematical Problems in Engineering, 2014. doi: 10.1155/2014/271741. 33. Osman, M. S. and Abo-sinna, M. A., 2005. A combined genetic algorithm-fuzzy logic controller (GA–FLC) in nonlinear programming, 170, pp. 821–840. doi:10.1016/j.amc.2004.12.023. 34. Patel, M. and Pratap, B., 2018. Nonlinear Reduced Order Observer Based Controller Design for High-Speed Trains, 2017 14th IEEE India Council International Conference, INDICON 2017, pp. 0–5. doi: 10.1109/INDICON.2017.8487921. 35. Poli, R., Kennedy, J. and Blackwell, T., 2007. Particle swarm optimization, Swarm Intelligence, Springer, 1(1), pp. 33–57. doi: 10.1007/s11721-007-0002-0. 36. Qiang, S. and Fang, L., 2006. Improved control of a pneumatic actuator pulsed with PWM, Proceedings of the 2nd IEEE/ASME International Conference on Mechatronic and Embedded Systems and Applications, MESA 2006, 2(2), pp. 1–4. doi: 10.1109/MESA.2006.297011. 37. Rajeswari, K. and Lakshmi, P., 2010. PSO optimized fuzzy logic controller for active suspension system, Proceedings - 2nd International Conference on Advances in Recent Technologies in Communication and Computing, ARTCom 2010, pp. 278–283. doi: 10.1109/ARTCom.2010.22. 38. Rossiter, J. A., 2003. Model- Based Predictive Control - A practical approach. Rao, S. S., 2009. Engineering Optimization. doi: 10.1002/9780470549124. 39. Richalet, J. and O’Donovan, D., 2009. Predictive Functional Control, Motivation and Emotion. Springer London 2019, doi: 10.1007/978-1-84882-493-5. 40. Rossiter, J.A, G.Valencia-Palomo., 1993. Comparison between an auto-tuned PI controller, a predictive controller and a predictive functional controller in elementary dynamic systems. In: Automatic Control and Systems Engineering, University of Sheffield, UK. 41. Robert. H. Bishop, Dorf R.C., 2010. Modern Control Systems, 12th ed, Prentice Hall. 42. Salleh, S. Rahmat, M. F. Othman, S. M., 2011. Review on modeling and controller design of hydraulic actuator systems, International Journal on Smart Sensing and Intelligent Systems, 8(1), pp. 338–367. doi: 10.21307/ijssis-2017-762. 43. Satoh, T., 2011. Performance Improvement of Predictive Functional Control : A Disturbance Observer Approach, In: IECON 2011 - 37th Annual Conference of the IEEE Industrial Electronics Society, Melbourne, VIC, Australia, 7-10 Nov. 2011, pp. 669–674. doi: 10.1109/IECON.2011.6119390. 44. Shamsudin, M. A., Ibrahim, Z., Nawawi, S. W., Husain, A. R. and Abdulla, J., 2011. An Adaptive Control of Two Wheel Inverted Pendulum Robot based on Particle Swarm Optimization, In: The 5th International Conference on Automation, Robotics and Applications, Wellington, New Zealand, 6-8 Dec. 2011, pp. 151–156. doi: 10.1109/ICARA.2011.6144873. 45. Shih, M., 1998. Position control of a pneumatic cylinder using fuzzy PWM control method, Department of Mechanical Engineering, National Cheng-Kung University, 700, Tainan, Taiwan, pp. 241–253. 46. Suzumori, K., Tanaka, J. and Kanda, T., 2005. Development of an intelligent pneumatic cylinder and its application to pneumatic servo mechanism, In: Proceedings, 2005 IEEE/ASME International Conference on Advanced Intelligent Mechatronics, Monterey, CA, USA, 24-28 July 2005, pp. 479–484. doi: 10.1109/aim.2005.1511028. 47. Shi, Y. and Eberhart, R., 1998. A Modified Particle Swarm Optimizer, In: IEEE International Conference on Evolutionary Computation Proceedings. IEEE World Congress on Computational Intelligence, Anchorage, AK, USA, USA, 4-9 May 1998 pp. 69–73.doi: 10.1109/ICEC.1998.699146. 48. Toni Tuovinen, Marko Hinkkanen, Lennart Harnefors, Jorma Luomi., 2012. Comparison of a Reduced-Order Observer and a Full-Order Observer for Sensorless Synchronous Motor Drives, In: IEEE Transactions on Industry Applications, 48(6), pp. 1959–1967. doi: 10.1109/TIA.2012.2226200. 49. Van Varseveld, R. B. and Bone, G. M., 1997. Accurate position control of a pneumatic actuator using on/off solenoid valves, IEEE/ASME Transactions on Mechatronics, 2(3), pp. 195–204. doi: 10.1109/3516.622972. 50. Wang, L., 2009. Model Predictive Control System Design and Implementation Using MATLAB, Engineering. Springer, London, doi: 10.1007/978-1-84882-331-0. 51. Waghmare, A. V. and Kannaiyan, S., 2018. Real Time Heat Exchanger Control Using Predictive Functional Control, 2018 9th International Conference on Computing, Communication and Networking Technologies, ICCCNT 2018. IEEE, pp. 1–5. doi: 10.1109/ICCCNT.2018.8494114. 52. Yang, Y., Leping, Bu., Ii, Xia., and Ke, Li Hong., 2015. Research on Networked Predictive Functional Controller Based on Particle Swarm Optimization, (1), pp. 1571–1574. |