Robot frame compliance has a large negative effect on the global accuracy of the system when large external forces/torques are exerted. This phenomenon is particularly problematic in applications where the robot is required to achieve ultrahigh (micron level) accuracy under very large external loads, e.g., in biomechanical testing and high precision machining. To ensure the positioning accuracy of the robot in these applications, the authors proposed a novel Stewart platform-based manipulator with decoupled sensor–actuator locations. The unique mechanism has the sensor locations fully decoupled from the actuator locations for the purpose of passively compensating for the load frame compliance, as a result improving the effective stiffness of the manipulator in six degrees of freedom (6DOF). In this paper, the stiffness of the proposed manipulator is quantified via a simplified method, which combines both an analytical model (robot kinematics error model) and a numerical model [finite element analysis (FEA) model] in the analysis. This method can be used to design systems with specific stiffness requirements. In the control aspect, the noncollocated positions of the sensors and actuators lead to a suboptimal control structure, which is addressed in the paper using a simple Jacobian-based decoupling method under both kinematics- and dynamics-based control. Simulation results demonstrate that the proposed manipulator configuration has an effective stiffness that is increased by a factor of greater than 15 compared to a general design. Experimental results show that the Jacobian-based decoupling method effectively increases the dynamic tracking performance of the manipulator by 25% on average over a conventional method.
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November 2014
Research-Article
Stiffness Analysis and Control of a Stewart Platform-Based Manipulator With Decoupled Sensor–Actuator Locations for Ultrahigh Accuracy Positioning Under Large External Loads
Boyin Ding,
Boyin Ding
1
School of Mechanical Engineering,
e-mail: boyin.ding@adelaide.edu.au
University of Adelaide
,Adelaide, SA 5005
, Australia
e-mail: boyin.ding@adelaide.edu.au
1Corresponding author.
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Benjamin S. Cazzolato,
Benjamin S. Cazzolato
School of Mechanical Engineering,
University of Adelaide
,Adelaide, SA 5005
, Australia
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Richard M. Stanley,
Richard M. Stanley
Biomechanics and Implants Research Group,
Medical Device Research Institute
and School of Computer Science,
Engineering and Mathematics,
Medical Device Research Institute
and School of Computer Science,
Engineering and Mathematics,
Flinders University
,Bedford Park, SA 5042
, Australia
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Steven Grainger,
Steven Grainger
School of Mechanical Engineering,
University of Adelaide
,Adelaide, SA 5005
, Australia
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John J. Costi
John J. Costi
Biomechanics and Implants Research Group,
Medical Device Research Institute
and School of Computer Science,
Engineering and Mathematics,
e-mail: john.costi@flinders.edu.au
Medical Device Research Institute
and School of Computer Science,
Engineering and Mathematics,
Flinders University
,Bedford Park, SA 5042
, Australia
e-mail: john.costi@flinders.edu.au
Search for other works by this author on:
Boyin Ding
School of Mechanical Engineering,
e-mail: boyin.ding@adelaide.edu.au
University of Adelaide
,Adelaide, SA 5005
, Australia
e-mail: boyin.ding@adelaide.edu.au
Benjamin S. Cazzolato
School of Mechanical Engineering,
University of Adelaide
,Adelaide, SA 5005
, Australia
Richard M. Stanley
Biomechanics and Implants Research Group,
Medical Device Research Institute
and School of Computer Science,
Engineering and Mathematics,
Medical Device Research Institute
and School of Computer Science,
Engineering and Mathematics,
Flinders University
,Bedford Park, SA 5042
, Australia
Steven Grainger
School of Mechanical Engineering,
University of Adelaide
,Adelaide, SA 5005
, Australia
John J. Costi
Biomechanics and Implants Research Group,
Medical Device Research Institute
and School of Computer Science,
Engineering and Mathematics,
e-mail: john.costi@flinders.edu.au
Medical Device Research Institute
and School of Computer Science,
Engineering and Mathematics,
Flinders University
,Bedford Park, SA 5042
, Australia
e-mail: john.costi@flinders.edu.au
1Corresponding author.
Contributed by the Dynamic Systems Division of ASME for publication in the JOURNAL OF DYNAMIC SYSTEMS, MEASUREMENT, AND CONTROL. Manuscript received January 23, 2013; final manuscript received June 25, 2014; published online August 8, 2014. Assoc. Editor: Nariman Sepehri.
J. Dyn. Sys., Meas., Control. Nov 2014, 136(6): 061008 (12 pages)
Published Online: August 8, 2014
Article history
Received:
January 23, 2013
Revision Received:
June 25, 2014
Citation
Ding, B., Cazzolato, B. S., Stanley, R. M., Grainger, S., and Costi, J. J. (August 8, 2014). "Stiffness Analysis and Control of a Stewart Platform-Based Manipulator With Decoupled Sensor–Actuator Locations for Ultrahigh Accuracy Positioning Under Large External Loads." ASME. J. Dyn. Sys., Meas., Control. November 2014; 136(6): 061008. https://doi.org/10.1115/1.4027945
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