SLIDING MODE CONTROLLED CLOSED LOOP QB-CONVERTER -TPIS FED PMSM DRIVE WITH ENHANCED RESPONSE
DOI:
https://doi.org/10.59277/RRST-EE.2025.3.8Keywords:
Quadratic boost converter (QBC), Three phase inverter system (TPIS), Permanent magnet synchronous motor (PMSM), Proportional-integral (PI) and sliding mode (SM) controllerAbstract
The primary goal of this work is to identify the most appropriate controller for a QBC-TPIS fed PMSMD used high performance drives. A drive requires fast dynamic response and accurate control for its operation.
This effort deals with the design, analysis &simulation of Closed loop- Quadratic Boost (QB) Converter-TPIS (Three Phase Inverter System) fed PMSM (Permanent Magnet Synchronous Motors) with Proportional-Integral (PI) & SM (Sliding mode) controller outcomes are presented. In this work duty cycle optimization of Q-Boost Converter was done by control input of SM controller. The-consequences are related in terms of-time-domain aspects like –rise-time,-peak-time,-settling-time&- steady state error. Settling time is lowered to 2s and steady-state error in speed is also reduced to 1.98rpm in Sliding Mode (SM) control. The consequence denotes the-better outcomes of Closed- loop-Quadratic-BC-TPIS fed PMSMD with SM controller.
References
(1) R. Krishnan, A.J. Beutler, Performance and design of an axial field PM synchronous motor servo drive, in Conf. Rec. IEEE-IAS Annul. Meeting, pp. 634–640 (1985)
(2) P. Pillay, Application characteristics of permanent magnet synchronous and brushless DC motors for servo drives, IEEE Transactions on Industry Applications, 21, 5, pp.986–996 (1991)
(3) E. Sreeshobha, G. Sree Lakshmi, Performance analysis and comparison of P.I. controller and ANN controller of bidirectional DC/DC converter for hybrid electric vehicle system, 2022 International Conference on Breakthrough in Heuristics and Reciprocation of Advanced Technologies (BHARAT), Visakhapatnam, India (2022).
(4) S. Li, W. Xie, K. Ma-Smedley, A family of an automatic interleaved Dickson switched-capacitor converter and its ZVS resonant configuration, IEEE Trans. Ind. Electron. 66, 11, pp. 255-264 (2019).
(5) C.Y Chan, An improved voltage-mode controller for the quadratic boost converter, IEEE Transactions on Circuits and Systems II: Express Briefs. 69, 2, pp.454-458 (2022).
(6) S.H. Chin Cholkar, C.Y Chan, Design of fixed-frequency pulse width-modulation-based sliding-mode controllers for the quadratic boost converter, IEEE Transactions on Circuits and Systems II: Express Briefs, 64, 1, pp. 2014–2018 (2017).
(7) M. Vahedpour, A.R. Noei, H.A. Kholerdi, Comparison between performance of conventional, fuzzy and fractional order PID controllers in practical speed control of induction motor, 2015 2nd International Conference on Knowledge-Based Engineering and Innovation (KBEI), Tehran, pp. 912–916 (2015).
(8) S. Bhavani, A. Sivaprakasam, Dual mode symmetrical proportional resonant controlled quadratic boost converter for PMSM- Drive, Symmetry,15,1, pp.147 (2023).
(9) A. Sivaprakasam, A new approach to reduce torque ripple and noise in twelve sector based direct torque controller fed permanent magnet synchronous motor drive: Simulation and experimental results, Noise Control Eng. Journal, 65, 6, pp .531–548 (2017).
(10) A. Sivaprakasam, T. Manigandan, An alternative scheme to reduce torque ripple and mechanical vibration in direct torque controlled permanent magnet synchronous motor. Journal of Vibration and Control, 21, 5, pp. 855-871 (2013).
(11) B. Mokhtari, Enhancement Ripples of a direct torque control applied to a permanent magnet synchronous motor by using a four-level multicellular inverter and a new reduced switching table, Rev. Roum. Sci. Techn. – Électrotechn. Et Énerg., 69, 2, pp. 207–212 (2024).
(12) A. Sivaprakasam, J.D. Anunciya, A survey on matrix converter-fed direct torque control techniques for AC machines, IETE Journal of Research, 68, 1, pp. 1–17, (2019).
(13) S. Bhavani, A. Sivaprakasam, Hysteretic controlled quadratic boost converter-3 phase inverter fed PMSM for E-car with enhanced time response, 9th International Conference on Electrical Energy System (ICEES), (2023).
(14) A. Mechernene, M. Loucif, M. Zerikat, Induction motor control based on a fuzzy sliding mode approach. Rev. Roum. Sci. Techn.– Électrotechn. et Énerg., 64, 1, pp.39–44 (2019).
(15) R. Rouabhi, A.G Herizi, S. Djeriou, A. Zemmit, Hybrid type-1 and 2 fuzzy sliding mode control of the Induction motor, Rev. Roum. Sci. Techn.– Électrotechn. et Énerg., 69, 2, pp.147–152 (2024).
(16) W. Gao, J.C. Hung, Variable structure control of nonlinear systems: a new approach, IEEE Transactions on Industrial Electronics, 40, 1, pp. 45– 55 (1993).
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