State estimation and feedforward tremor suppression for a handheld micromanipulator with a Kalman filter
Conference Paper, Proceedings of (IROS) IEEE/RSJ International Conference on Intelligent Robots and Systems, pp. 5160 - 5165, September, 2011
Abstract
Active compensation of physiological tremor for handheld micromanipulators depends on fast control and actuation responses. Because of real-world latencies, real-time compensation is usually not completely effective at eliminating unwanted hand motion. By modeling tremor, more effective cancellation is possible by anticipating future hand motion. We propose a feedforward control strategy that utilizes tremor velocity from a state-estimating Kalman filter. We demonstrate that estimating hand motion in a feedforward controller overcomes real-world latencies in micromanipulator actuation. In hold-still tasks with a fully handheld micromanipulator, the proposed feedforward approach improves tremor rejection by over 50%.
BibTeX
@conference{Becker-2011-7366,author = {Brian Becker and Robert MacLachlan and Cameron Riviere},
title = {State estimation and feedforward tremor suppression for a handheld micromanipulator with a Kalman filter},
booktitle = {Proceedings of (IROS) IEEE/RSJ International Conference on Intelligent Robots and Systems},
year = {2011},
month = {September},
pages = {5160 - 5165},
keywords = {medical robotics, micromanipulator, Kalman filter},
}
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