Gain Tuned Internal Model Control for Handling Saturation in Actuators

1. Gain Tuned Internal Model Control for Handling Saturation in Actuators 學生: 吳政達 授課老師：曾慶耀 教授 2007/11/15

2. Abstract In this paper, a new approach to handling actuator saturation based on Internal Model Control (IMC) is proposed. a gain term and first-order exponential filter are tuned to desaturate the actuator. Examples show the simplicity of design and the validity of proposed framework.

3. Introduction The existence of control signal saturation within a practical control system may result in instability. The research in control signal saturation has reached the level of maturity where ad-hoc compensation schemes are widely available.

4. Introduction Internal Model Control (IMC) is a control technique that guarantees system stability while offering good tracking performance.

5. Introduction The only restrictions on the IMC scheme are that the plant needs to be open loop stable and minimum phase. The proposed method not only reduces the complexity of currently available saturation compensation schemes, but also guarantees global stability for bounded input bounded output (BIBO) systems.

6. Restructured IMC A. Single-degree-of-freedom IMC with Saturation

7. Restructured IMC The following equation relating the inputs and outputs can be derived

8. Restructured IMC

9. Restructured IMC

10. Restructured IMC B.Two-degrees-of-freedom IMC A typical discrete-time teo-degrees-of-freedom IMC structure is shown in Fig. 2.

11. Restructured IMC C.Proposed IMC Framework The proposed IMC structure with control input saturation is thus constructed in accordance with this proposition with the saturated input fed into the plant and model.

12. Inverse Model Controller First order exponential filter Restructured IMC C.Proposed IMC Framework

13. Restructured IMC The saturation function is given by： A single static saturation non-linearity function defined by (6) can be characterized by：

14. Restructured IMC

15. Restructured IMC

16. Stability Analysis The closed-loop system remains globally stable as long as the plant model is equal to the nominal model (Gp=Gm).

17. Stability Analysis The following equations can be derived from Fig. 3：

18. Stability Analysis

19. Stability Analysis

20. Stability Analysis Consider a single-input-single-output nonlinear system represented by the feedback connection as shown in Fig. 5

21. Stability Analysis

22. Stability Analysis

23. Examples and Simulation Results

24. Examples and Simulation Results

25. Examples and Simulation Results

26. Examples and Simulation Results

27. Examples and Simulation Results

28. Examples and Simulation Results

29. Examples and Simulation Results

30. Examples and Simulation Results

31. Examples and Simulation Results

32. Conclusion Overshoot can be eliminated by increasing gain, K. The stability analysis in section III showed that the proposed IMC structure is globally asymptotic stable. The modified IMC synthesis can be used for the handling of other sector-bounded non-linearities.

33. Thanks for your attention