This paper presents a modified integral sliding surface, sliding mode control law for pneumatic artificial muscles. The cutoff frequency tuning parameter λ is squared to increase the gradient from absement (integral of position) to position and higher derivatives to reflect the more dominant terms in the actuator dynamics. The sliding mode controller is coupled with proportional and integral action compensation. The control system is sufficiently robust so that use of an observer and input-output feedback linearization are not required. Closed-loop control experiments are compared with traditional sliding mode controller designs presented in the literature for pneumatic artificial muscles. Experiments include the tracking of sinusoidal waves at 0.5 and 1 Hz, tracking of square-like waves with seventh-order trajectory transitions at a rate of 0.2 Hz without and with a steady-state period of 10 seconds, as well as a step input response. These experiments indicate that the control law provides similar bandwidth, tracking, and steady-state performance as approaches requiring nonlinear feedback and model observation for pneumatic artificial muscles. Experiments demonstrate an accuracy of 50 μm at steady-state with no overshoot and maximum tracking errors less than 0.4 mm for smooth square-like trajectories.
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ASME/BATH 2017 Symposium on Fluid Power and Motion Control
October 16–19, 2017
Sarasota, Forida, USA
Conference Sponsors:
- Fluid Power Systems and Technology Division
ISBN:
978-0-7918-5833-2
PROCEEDINGS PAPER
Robust Control Law for Pneumatic Artificial Muscles
Jonathon E. Slightam,
Jonathon E. Slightam
Marquette University, Milwaukee, WI
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Mark L. Nagurka
Mark L. Nagurka
Marquette University, Milwaukee, WI
Search for other works by this author on:
Jonathon E. Slightam
Marquette University, Milwaukee, WI
Mark L. Nagurka
Marquette University, Milwaukee, WI
Paper No:
FPMC2017-4225, V001T01A009; 10 pages
Published Online:
December 4, 2017
Citation
Slightam, JE, & Nagurka, ML. "Robust Control Law for Pneumatic Artificial Muscles." Proceedings of the ASME/BATH 2017 Symposium on Fluid Power and Motion Control. ASME/BATH 2017 Symposium on Fluid Power and Motion Control. Sarasota, Forida, USA. October 16–19, 2017. V001T01A009. ASME. https://doi.org/10.1115/FPMC2017-4225
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