The precision positioning systems generally need a good controller to achieve a fast response, high accuracy and robustness. In addition, ease, simplicity of controller design structure and high motion control performance are very important for practical applications. For satisfying these requirements, nominal characteristic trajectory (NCT) with proportional integral (PI) and notch filter (NF) as a compensator has been proposed as a practical control method for two-mass rotary PTP positioning systems. However, the effect of the actuator saturation cannot be completely compensated due to integrator windup when the object parameter varies. This paper presents a method to further improve nominal characteristic trajectory following (NCTF) controller to overcome the problem of integrator windup by adopting PI anti-windup schemes. The improved NCTF controller is evaluated experimentally using two-mass rotary positioning systems. The effect of the design parameters on the robustness of the improved NCTF with anti-windup integrator controller is evaluated and compared with NCTF without anti-windup integrator and the equivalent PID controller. The results show that the improved NCTF controller is effective to compensate the effect of integrator windup.

Amstrong-Helouvry B, Dupont P, De Witt C. A Survey of Models, Analysis Tools and Compensation Method for the Control of Machines with Friction. Automatica. 1994; 30: 1083-1138.

Kempf C, Kobayashi S. Disturbance Observer and Feedforward Design for a High speed direct-drive Positioning Table. IEEE Trans. On Control systems Technology. 1999; 7(5): 513-526.

Park MH, Won CY. Time Optimal Control for Induction Motor servo System. IEEE Trans. On Power Electronics. 1991; 6(3): 514-524.

Li YF, Erikson B, Wilkander J. Sliding Mode Control of Two-mass Positioning systems. 14th Triennaial World Congress IFAC. Beijing, China. 1999: 151-156.

Shieh MY, Li TH. Design and Implementation of Integrated Fuzzy Logic Controller for a servo motor system. Mechatronic. 1998; 8: 217-240.

Horgh JH. Neural Adaptive tracking control of a DC motor. Information sciences. 1999; 118: 1-13.

How to work with mechanical resonance in motion control systems. Control Engineering. 2000; 47(4): 5.

Sato K, Wahyudi, Shimokohbe A. Design and Characteristics of Practical Control system for PTP Positioning. Trans of the Japan Society of Mechanical Engineers. 2001; 67(664): 222-228.

Fitri MY, Wahyudi, R Akmeliawati. Improved NCTF Control Method for a Two Mass Point to Point Positioning System. IEEE 3rd International Conference on Intelligent and Advanced systems (ICIAS 2010). Kuala Lumpur. Jun 2010.

Wahyudi, Albagul A. Performance improvement of practical control method for positioning system in the presence of actuator saturation. IEEE International Conference on Control Applications. Taipei. 2004; 296-302.

K Astrom, T Hagglund. PID Controllers: Theory, Design, and Tuning. Handbook. Instrument Society of America. 1995; 82-90.

W Gharier. Fuzzy intervention in PID Controller design. ISIE. Pusan, Korea. 2001; 1639-1643.

Wahyudi, Sato K, Shimokohbe A. Robustness Evaluation of New Practical Control Method for PTP Postioning Systems. IEEE/ASME International Conference on Advanced Intelligent Mechatronics. 2001; 843-848.

Oppenheim A.V. & Schafer R.W, Discrete Time Signal Processing. Englewood Cliffs, Prentice Hall. 1999.

Fitri MY, Wahyudi, R Akmeliawati. Performance Evaluation of Improved Practical Control Method of Two-Mass PTP Positioning System. IEEE Symposium on Industrial Electronics & Applications (ISIEA 2010). Penang. 2010; 550-555.

William East & Brian Lantz, Notch Filter Design. August 29, 2005.

S Crawshaw, G Vinnicombe. Anti-windup synthesis for guaranteed L2 performance.Proc. IEEE Conference on Decision and Control. 2000.

Bohn C, Atherton DP. A SIMULINK Package for Comparative Studies of PID Anti-windup strategies. IEEE Joint Sysposium on Computer-Aided Control System Design. 1994; 447-452.