Title :
Integration of an Empirical Mode Decomposition Algorithm With Iterative Learning Control for High-Precision Machining
Author :
Meng-Shiun Tsai ; Chung-Liang Yen ; Hong-Tzong Yau
Author_Institution :
Dept. of Mech. Eng., Nat. Chung Cheng Univ., Chiayi, Taiwan
Abstract :
In this paper, a novel algorithm (ILC-EMD) that integrates iterative learning control (ILC) with empirical mode decomposition (EMD) is proposed to improve learning process. To explain the divergence behavior under the conventional ILC, the EMD is utilized to decompose the tracking error signal into 11 intrinsic mode functions (IMFs). By observing the root mean square and the correlation values of the IMFs during iterations, the first IMF is determined to be the undesired signal which could not be reduced by learning process. Furthermore, the command containing the first IMF could further excite the machine tool due to the resonance effects and cause the amplification of the error signal. The ILC-EMD can filter out the undesired signal and prevent the amplification effect. Experimental results on tracking the butterfly and dragon nonuniform rational B-spline curves validate the effectiveness of the ILC-EMD algorithm.
Keywords :
iterative methods; learning systems; machine tools; machining; mean square error methods; splines (mathematics); ILC-EMD algorithm; IMF; amplification effect; butterfly nonuniform rational B-spline curves; dragon nonuniform rational B-spline curves; empirical mode decomposition algorithm; high-precision machining; intrinsic mode functions; iterative learning control; machine tool; resonance effects; root mean square; tracking error signal; Bandwidth; Convergence; Frequency domain analysis; Machine tools; Servomotors; Transfer functions; Empirical mode decomposition (EMD); intrinsic mode function (IMF); iterative learning control (ILC); resonance; zero-phase filtering;
Journal_Title :
Mechatronics, IEEE/ASME Transactions on
DOI :
10.1109/TMECH.2012.2194162
