Filter-based iterative learning control for linear large-scale industrial processes
- 57 Downloads
- 3 Citations
Abstract:
In the procedure of the steady-state hierarchical optimization with feedback for large-scale industrial processes, a sequence of set-point changes with different magnitudes is carried out on the optimization layer. To improve the dynamic performance of transient response driven by the set-point changes, a filter-based iterative learning control strategy is proposed. In the proposed updating law, a local-symmetric-integral operator is adopted for eliminating the measurement noise of output information, a set of desired trajectories are specified according to the set-point changes sequence, the current control input is iteratively achieved by utilizing smoothed output error to modify its control input at previous iteration, to which the amplified coefficients related to the different magnitudes of set-point changes are introduced. The convergence of the algorithm is conducted by incorporating frequency-domain technique into time-domain analysis. Numerical simulation demonstrates the effectiveness of the proposed strategy.
Keywords
Iterative learning control Large-scale industrial processes Steady-state optimization Dynamic performancePreview
Unable to display preview. Download preview PDF.
References
- [1]W. Findeisen, F. Bailey, M. Brdys, K. Malinovski, P. Tatjewski, A. Woznialk, Control and Coordination in Hierarchical Systems, John Wiley and Sons,U.K. 1980.MATHGoogle Scholar
- [2]F. Q. Shao, P.D. Roberts, A price correction mechanism with global feedback for hierarchical control of steady-state systems, Large Scale Systems, Vol.4, pp. 67–80,1983.MATHGoogle Scholar
- [3]P. D. Roberts, B.W. Wan, J. Lin, Steady-state hierarchical control of large-scale industrial process, A Survey, 1FAC/IFORS/ IMACS Symposium Large-scale Systems: Theory and Applications, Preprints, Beijing, Vol. 1, pp. 1–10, Aug. 1992.Google Scholar
- [4]J. C. Gu, B. W. Wan, Steady-state hierarchical optimizing control for large-scale industrial processes with fuzzy parameters, IEEE Trans. Systems, Man and Cybernetics, Part C: Applications and Reviews, Vol.31, No. 3,pp. 352–360,2001.CrossRefGoogle Scholar
- [5]J. Lin,C. Han,P.D. Roberts,B.W. Wan,New approach to stochastic optimizing control of steady-state systems using dynamic information, Int.J. Control, Vol. 50, No.6, pp. 2205–2235,1989.MATHCrossRefGoogle Scholar
- [6]H. Xu, D. Huang, On-line optimization and hydrogen/nitrogen ratio analysis of large-scale ammonia plant, Proc. of 3rd Symposium of Chinese Association of Automation on Process Control, Tsinghua University Press,Beijing,pp. 206–212,1989.Google Scholar
- [7]G.J.Silva, A.Datta,S. P.Bhattacharyya,New results on the synthesis of PID controller, IEEE Trans. on Automatic Control, Vol.47, No.2, pp. 241–252,2002.CrossRefGoogle Scholar
- [8]X. Ruan, N. Yu, B.W. Wan, H. Gao, The iterative learning control and convergence analysis for nonlinear industrial process control systems, Proc. of the Third World Congress on intelligent Control and Automation, Hefei, pp. 3285–3289, 2000.Google Scholar
- [9]X. Ruan, B. W. Wan, H. Gao, The iterative learning control for saturated nonlinear industrial control systems with delay, Acta Automatica Sinica, Vol.27, No.2, pp. 219–223,2001.Google Scholar
- [10]Y. Q. Chen, K. L. Moore, Improved path following for an omnidirectional vehicle via practical iterative learning control using local-symmetrical-double-integration, Proc. of the 3rd Asian Control Conf., Shanghai,pp. 1818–1883,2000.Google Scholar