TY - JOUR
T1 - Cross-coupled iterative learning control of systems with dissimilar dynamics
T2 - Design and implementation
AU - Barton, Kira L.
AU - Hoelzle, David J.
AU - Alleyne, Andrew G.
AU - Johnson, Amy J.Wagoner
PY - 2011/7
Y1 - 2011/7
N2 - Cross-coupled iterative learning control has previously been applied to contour tracking problems with planar manufacturing robots in which both axes can be characterised as similar systems; having similar dynamics and identical hardware. However, there are many repetitive applications in which dynamically dissimilar systems cooperate to pursue a primary performance objective. This article introduces a novel framework to couple dynamically dissimilar systems while applying iterative learning control, showing the ability to noncausally compensate for a slow system with a fast system. In this framework, performance requirements for a primary objective can more readily be achieved by emphasising an underutilised fast system instead of straining a less-capable slow system. The controller is applied to a micro-robotic deposition manufacturing system to coordinate a slow extrusion system axis and a fast positioning system axis to pursue the primary performance objective, dimensional accuracy of a fabricated part. Experimental results show a 14% improvement in fabrication-dimensional accuracy with only marginal changes in actuator effort, as compared to independently controlled axes.
AB - Cross-coupled iterative learning control has previously been applied to contour tracking problems with planar manufacturing robots in which both axes can be characterised as similar systems; having similar dynamics and identical hardware. However, there are many repetitive applications in which dynamically dissimilar systems cooperate to pursue a primary performance objective. This article introduces a novel framework to couple dynamically dissimilar systems while applying iterative learning control, showing the ability to noncausally compensate for a slow system with a fast system. In this framework, performance requirements for a primary objective can more readily be achieved by emphasising an underutilised fast system instead of straining a less-capable slow system. The controller is applied to a micro-robotic deposition manufacturing system to coordinate a slow extrusion system axis and a fast positioning system axis to pursue the primary performance objective, dimensional accuracy of a fabricated part. Experimental results show a 14% improvement in fabrication-dimensional accuracy with only marginal changes in actuator effort, as compared to independently controlled axes.
KW - coupled systems
KW - cross-coupled control
KW - dissimilar dynamics
KW - Iterative learning control
KW - manufacturing applications
KW - micro-robotic deposition
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U2 - 10.1080/00207179.2010.500334
DO - 10.1080/00207179.2010.500334
M3 - Article
AN - SCOPUS:79961148120
SN - 0020-7179
VL - 84
SP - 1223
EP - 1233
JO - International Journal of Control
JF - International Journal of Control
IS - 7
ER -