access icon free Discrete-time speed servo system design – a comparative study: proportional–integral versus integral sliding mode control

© The Institution of Engineering and Technology
Received 29/11/2016, Accepted 08/07/2017, Revised 04/06/2017, Published 10/07/2017

This work presents a comparative study of two approaches for design of high performance discrete-time velocity servo systems with induction motors (IMs). The first approach uses the conventional proportional–integral controller with one-step delayed disturbance compensator (OSDC). The OSDC is based on measurements of the control input and plant states. The second approach uses the discrete-time integral sliding mode (DISM) controller with a first-order disturbance compensator, which is based on switching function signal measurement only. The controlled plant, consisting of IM in the commonly used indirect field-oriented control (IFOC) scheme, is approximated by first-order dynamic model for control design purpose. Comparisons are conducted through simulations considering an ideal case (without unmodelled dynamics) and a regular one, using MATLAB/Simulink models of real IFOC structure elements. The experimental investigation is conducted as well. The performed tests show that both controllers enhanced with the corresponding disturbance compensators are suitable for high-performance control systems design if speed measurement is near noise-free case, with better performance from DISM. If Euler backward difference is applied for speed detection, both control systems need some retuning in order to make a compromise between chattering and tracking accuracy.

Inspec keywords: discrete time systems; induction motors; variable structure systems; machine vector control; control system synthesis; PI control

Other keywords: IM; one-step delayed disturbance compensator; proportional-integral control; discrete-time speed servo system design; IFOC scheme; speed detection; MATLAB; indirect field-oriented control; IFOC structure elements; discrete-time integral sliding mode controller; Simulink models; Euler backward difference; switching function signal measurement; induction motors; disturbance compensators; first-order disturbance compensator; DISM controller; OSDC

Subjects: Control system analysis and synthesis methods; Multivariable control systems; Asynchronous machines; Control of electric power systems; Discrete control systems

References

    1. 1)
      • 5. Fujimoto, H., Hori, Y., Kawamura, A.: ‘Perfect tracking control based on multirate feedforward control with generalized sampling periods’, IEEE Trans Ind. Electron., 2001, 48, (3), pp. 636644.
    2. 2)
      • 13. Lin, S., Cai, Y., Yang, B., et al: ‘Electrical line-shafting control for motor speed synchronization using sliding mode controller and disturbance observer’, IET Control Theory Appl., 2016, 11, (2), pp. 205212.
    3. 3)
      • 14. Barambones, O., Garrido, A.J., Maseda, F.J.: ‘Integral sliding-mode controller for induction motor based on field-oriented control theory’, IET Control Theory Appl., 2007, 1, (3), pp. 786794.
    4. 4)
      • 10. Topalov, A.V., Cascella, G.L., Giordano, V., et al: ‘Sliding mode neuro-adaptive control of electrical drives’, IEEE Trans. Ind. Electron., 2007, 54, (1), pp. 671679.
    5. 5)
      • 3. Hikita, H.: ‘Servomechanisms based on sliding mode control’, Int. J. Control, 1988, 48, (2), pp. 435447.
    6. 6)
      • 8. Precup, R.E., Preitl, S.: ‘PI-Fuzzy controllers for integral plants to ensure robust stability’, Inf. Sci., 2007, 177, (20), pp. 44104429.
    7. 7)
      • 31. Lee, J.H.: ‘A new robust digital sliding mode control with disturbance observer for uncertain discrete time systems’, J. IKEEE, 2006, 15, (2), pp. 3744.
    8. 8)
      • 28. Draženović, B.: ‘The invariance conditions in variable structure systems’, Automatica, 1969, 5, (3) pp. 287295.
    9. 9)
      • 21. Milosavljević, Č., Perunicić-Draženović, B., Veselić, B.: ‘Discrete-time velocity servo system design using sliding mode control approach with disturbance compensation’, IEEE Trans. Ind. Inf., 2013, 9, (2), pp. 920927.
    10. 10)
      • 16. Kommuri, S.K., Rath, J.J., Veluvolu, K.C., et al: ‘Decoupled current control and sensor fault detection with second-order sliding mode for induction motor’, IET Control Theory Appl., 2015, 9, (4), pp. 608617.
    11. 11)
      • 18. Ferrara, A.: ‘Discussion on: ‘An adaptive variable structure control law for sensorless induction motors’, Eur. J. Control, 2007, 13, (4), pp. 393397.
    12. 12)
      • 15. Angulo, M.T., Carrillo-Serrano, R.V.: ‘Estimating rotor parameters in induction motors using high-order sliding mode algorithms’, IET Control Theory Appl., 2015, 9, (4), pp. 573578.
    13. 13)
      • 20. Su, W.C., Drakunov, S.V., Ozguner, U.: ‘An 0(T2) boundary layer in sliding mode for sampled-data systems’, IEEE Trans. Autom. Control, 2000, 45, (3), pp. 482485.
    14. 14)
      • 27. Veselić, B., Peruničić, B., Milosavljević, Č.: ‘High-performance position control of induction motor using discrete-time sliding mode control’, IEEE Trans. Ind. Electron., 2008, 55, (11), pp. 38093817.
    15. 15)
      • 12. Utkin, V.I.: ‘Sliding modes in control optimization’ (Springer, Berlin Heidelberg, New York, 1992).
    16. 16)
      • 11. Utkin, V.I.: ‘Sliding mode control design principles and application to electric drives’, IEEE Trans. Ind. Electron., 1993, 40, (1), pp. 2336.
    17. 17)
      • 24. Golo, G., Milosavljević, Č.: ‘Robust discrete-time chattering free sliding mode control’, Syst. Control Lett., 2000, 41, (1), pp. 1928.
    18. 18)
      • 22. Abidi, K., Xu, J.X., Yu, X.: ‘On the discrete-time integral sliding mode control’, IEEE Trans. Autom. Control, 2007, 52, (4), pp. 709715.
    19. 19)
      • 19. Li, X.L., Park, J.G., Shin, H.B.: ‘Comparison and evaluation of anti-windup PI controllers’, J. Power Electron., 2011, 11, (1), pp. 4550.
    20. 20)
      • 30. Shao, X., Sun, D.: ‘Development of a new robot controller architecture with FPGA-based IC design for improved high-speed performance’, IEEE Trans. Ind. Inf., 2007, 3, (4), pp. 312321.
    21. 21)
      • 6. Jin, Q.B., Liu, Q.: ‘IMC-PID design based on model matching approach and closed-loop shaping’, ISA Trans., 2014, 53, (2), pp. 462473.
    22. 22)
      • 7. Ting, C.S., Chang, Y.N., Shi, B.W., et al: ‘Adaptive back stepping control for permanent magnet linear synchronous motor servo drive’, IET Electr. Power Appl., 2015, 9, (3), pp. 265279.
    23. 23)
      • 26. Lješnjanin, M., Peruničić, B., Milosavljević, Č., et al: ‘Disturbance compensation in digital sliding mode’. Int. Conf. EUROCON, Lisboa, Portugal, 27–29 April 2011, CD, paper 171.
    24. 24)
      • 17. Oliveira, C.M., Aguiar, M.L., Monteiro, J.R., et al: ‘Vector control of induction motor using an integral sliding mode controller with anti-windup’, J. Control Autom. Electr. Syst., 2016, 27, (2), pp. 169178.
    25. 25)
      • 25. Milosavljević, Č., Peruničić-Draženović, B., Veselić, B., et al: ‘A new design of servomechanisms with digital sliding mode’, Electr. Eng., 2007, 89, (3), pp. 233244.
    26. 26)
      • 9. Lino, P., Maione, G., Stasi, S., et al: ‘Synthesis of fractional-order PI controllers and fractional-order filters for industrial electrical drives’, IEEE/CAA J. Autom. Sinica, 2017, 4, (1), pp. 5868.
    27. 27)
      • 32. Milosavljević, Č., Perunicić-Draženović, B., Veselić, B., et al: ‘High-performance discrete-time chattering-free sliding mode-based speed control of induction motor’, Electr. Eng., 2017, 99, (2), pp. 583593.
    28. 28)
      • 23. Bartolini, G., Ferrara, A., Utkin, V.I.: ‘Adaptive sliding mode control in discrete time systems’, Automatica, 1995, 31, (5), pp. 769773.
    29. 29)
      • 1. Eun, Y., Kim, J.H, Kim, K., et al: ‘Discrete-time variable structure controller with a decoupled disturbance compensator and its application to a CNC servomechanism’, IEEE Trans. Control Syst. Technol., 1999, 7, (4), pp. 414423.
    30. 30)
      • 4. Dorf, R.C., Bishop, R.H.: ‘Modern control systems’ (Pearson Education, New York, 1995, 2010, 12th edn).
    31. 31)
      • 29. Middleton, R.H., Goodwin, G.C.: ‘Improved finite word length characteristics in digital control using delta operators’, IEEE Trans. Autom. Control, 1986, 31, (3), pp. 10151021.
    32. 32)
      • 2. Xi, X.C., Zhao, W.S., Poo, A.N.: ‘Improving CNC contouring accuracy by robust digital integral sliding mode control’, Int. J. Mach. Tools Manuf., 2015, 88, pp. 5161.
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