Having unified representations of human walking gait data is of paramount importance for wearable robot control. In the rehabilitation robotics literature, control approaches that unify the gait cycle of wearable robots are more appealing than the conventional approaches that rely on dividing the gait cycle into several periods, each with their own distinct controllers. In this article we propose employing algebraic curves to represent human walking data for wearable robot controller design. In order to generate algebraic curves from human walking data, we employ the 3L fitting algorithm, a tool developed in the pattern recognition literature for fitting implicit polynomial curves to given datasets. For an impedance model of the knee joint motion driven by the hip angle signal, we provide conditions by which the generated algebraic curves satisfy a robust relative degree condition throughout the entire walking gait cycle. The robust relative degree property makes the algebraic curve representation of walking gaits amenable to various nonlinear output tracking controller design techniques.
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ASME 2018 Dynamic Systems and Control Conference
September 30–October 3, 2018
Atlanta, Georgia, USA
Conference Sponsors:
- Dynamic Systems and Control Division
ISBN:
978-0-7918-5189-0
PROCEEDINGS PAPER
Human-Inspired Algebraic Curves for Wearable Robot Control
Alireza Mohammadi,
Alireza Mohammadi
University of Texas at Dallas, Richardson, TX
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Robert D. Gregg
Robert D. Gregg
University of Texas at Dallas, Richardson, TX
Search for other works by this author on:
Alireza Mohammadi
University of Texas at Dallas, Richardson, TX
Robert D. Gregg
University of Texas at Dallas, Richardson, TX
Paper No:
DSCC2018-9061, V001T11A002; 8 pages
Published Online:
November 12, 2018
Citation
Mohammadi, A, & Gregg, RD. "Human-Inspired Algebraic Curves for Wearable Robot Control." Proceedings of the ASME 2018 Dynamic Systems and Control Conference. Volume 1: Advances in Control Design Methods; Advances in Nonlinear Control; Advances in Robotics; Assistive and Rehabilitation Robotics; Automotive Dynamics and Emerging Powertrain Technologies; Automotive Systems; Bio Engineering Applications; Bio-Mechatronics and Physical Human Robot Interaction; Biomedical and Neural Systems; Biomedical and Neural Systems Modeling, Diagnostics, and Healthcare. Atlanta, Georgia, USA. September 30–October 3, 2018. V001T11A002. ASME. https://doi.org/10.1115/DSCC2018-9061
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