Enhanced control of a flexure-jointed micromanipulation system using a vision-based servoing approach

Enhanced control of a flexure-jointed micromanipulation system using a vision-based servoing approach

© Published under licence by IOP Publishing Ltd. This paper describes a high-precision motion control implementation for a flexure-jointed micromanipulator. A desktop experimental motion platform has been created based on a 3RUU parallel kinematic mechanism, driven by rotary voice coil actuators. Th...

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Main Authors: T. Chuthai, M. O.T. Cole, T. Wongratanaphisan, P. Puangmali
Format: Conference Proceeding
Published: 2018
Subjects:
Engineering
Materials Science
Online Access:https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=85046283387&origin=inward
http://cmuir.cmu.ac.th/jspui/handle/6653943832/58690
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Institution: Chiang Mai University
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spelling th-cmuir.6653943832-586902018-09-05T04:31:41Z Enhanced control of a flexure-jointed micromanipulation system using a vision-based servoing approach T. Chuthai M. O.T. Cole T. Wongratanaphisan P. Puangmali Engineering Materials Science © Published under licence by IOP Publishing Ltd. This paper describes a high-precision motion control implementation for a flexure-jointed micromanipulator. A desktop experimental motion platform has been created based on a 3RUU parallel kinematic mechanism, driven by rotary voice coil actuators. The three arms supporting the platform have rigid links with compact flexure joints as integrated parts and are made by single-process 3D printing. The mechanism overall size is approximately 250x250x100 mm. The workspace is relatively large for a flexure-jointed mechanism, being approximately 20x20x6 mm. A servo-control implementation based on pseudo-rigid-body models (PRBM) of kinematic behavior combined with nonlinear-PID control has been developed. This is shown to achieve fast response with good noise-rejection and platform stability. However, large errors in absolute positioning occur due to deficiencies in the PRBM kinematics, which cannot accurately capture flexure compliance behavior. To overcome this problem, visual servoing is employed, where a digital microscopy system is used to directly measure the platform position by image processing. By adopting nonlinear PID feedback of measured angles for the actuated joints as inner control loops, combined with auxiliary feedback of vision-based measurements, the absolute positioning error can be eliminated. With controller gain tuning, fast dynamic response and low residual vibration of the end platform can be achieved with absolute positioning accuracy within ±1 micron. 2018-09-05T04:28:40Z 2018-09-05T04:28:40Z 2018-02-07 Conference Proceeding 1757899X 17578981 2-s2.0-85046283387 10.1088/1757-899X/297/1/012046 https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=85046283387&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/58690
institution Chiang Mai University
building Chiang Mai University Library
country Thailand
collection CMU Intellectual Repository
topic Engineering
Materials Science
spellingShingle Engineering
Materials Science
T. Chuthai
M. O.T. Cole
T. Wongratanaphisan
P. Puangmali
Enhanced control of a flexure-jointed micromanipulation system using a vision-based servoing approach
description © Published under licence by IOP Publishing Ltd. This paper describes a high-precision motion control implementation for a flexure-jointed micromanipulator. A desktop experimental motion platform has been created based on a 3RUU parallel kinematic mechanism, driven by rotary voice coil actuators. The three arms supporting the platform have rigid links with compact flexure joints as integrated parts and are made by single-process 3D printing. The mechanism overall size is approximately 250x250x100 mm. The workspace is relatively large for a flexure-jointed mechanism, being approximately 20x20x6 mm. A servo-control implementation based on pseudo-rigid-body models (PRBM) of kinematic behavior combined with nonlinear-PID control has been developed. This is shown to achieve fast response with good noise-rejection and platform stability. However, large errors in absolute positioning occur due to deficiencies in the PRBM kinematics, which cannot accurately capture flexure compliance behavior. To overcome this problem, visual servoing is employed, where a digital microscopy system is used to directly measure the platform position by image processing. By adopting nonlinear PID feedback of measured angles for the actuated joints as inner control loops, combined with auxiliary feedback of vision-based measurements, the absolute positioning error can be eliminated. With controller gain tuning, fast dynamic response and low residual vibration of the end platform can be achieved with absolute positioning accuracy within ±1 micron.
format Conference Proceeding
author T. Chuthai
M. O.T. Cole
T. Wongratanaphisan
P. Puangmali
author_facet T. Chuthai
M. O.T. Cole
T. Wongratanaphisan
P. Puangmali
author_sort T. Chuthai
title Enhanced control of a flexure-jointed micromanipulation system using a vision-based servoing approach
title_short Enhanced control of a flexure-jointed micromanipulation system using a vision-based servoing approach
title_full Enhanced control of a flexure-jointed micromanipulation system using a vision-based servoing approach
title_fullStr Enhanced control of a flexure-jointed micromanipulation system using a vision-based servoing approach
title_full_unstemmed Enhanced control of a flexure-jointed micromanipulation system using a vision-based servoing approach
title_sort enhanced control of a flexure-jointed micromanipulation system using a vision-based servoing approach
publishDate 2018
url https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=85046283387&origin=inward
http://cmuir.cmu.ac.th/jspui/handle/6653943832/58690
_version_ 1681425112598839296

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