Article: Adaptive fuzzy logic control for a robotic gait training orthosis Journal: International Journal of Intelligent Systems Technologies and Applications (IJISTA) 2021 Vol.20 No.3 pp.199 - 214 Abstract: This paper aims to develop an adaptive control strategy for a fuzzy logic system for a robotic gait training orthosis whose design is bio-inspired from biomechanics of the human gait. Powerful yet light weight pneumatic muscle actuators (PMAs) fulfilled the ambulatory requirements of the robot while also providing the actuation required to create the sagittal plane rotations at the hip and knee. The PMA is controlled by a fuzzy logic controller based on Mamdani inference for obtaining the rotational degrees of freedom. To cope with the nonlinear behaviour of the PMA towards external disturbances, a second fuzzy-based controller was also developed. In order to compensate for time dependent characteristics of the PMA, an adaptive control mechanism was introduced. Experiments were conducted on healthy subjects for understanding and estimating the performance of the adaptive fuzzy logic controller and robotic design. The human-robot interaction was mainly passive-active, while the paths were predefined. Inderscience Publishers - linking academia, business and industry through research

Title: Adaptive fuzzy logic control for a robotic gait training orthosis

Authors: Deepa Mathur; Deepak Bhatia; Prashant K. Jamwal; Shahid Hussain; Mergen H. Ghayesh

Addresses: Instrumentation Department, Government Polytechnic College, Kota, Rajasthan, India ' Electronics Department, Rajasthan Technical University, Kota, Rajasthan, India ' Department of Electrical and Electronics Engineering, Nazarbayev University, Astana, Kazakhstan ' Department of Information Technology (IT) and Systems, University of Canberra, Australia ' School of Mechanical Engineering, University of Adelaide, SA, Australia

Abstract: This paper aims to develop an adaptive control strategy for a fuzzy logic system for a robotic gait training orthosis whose design is bio-inspired from biomechanics of the human gait. Powerful yet light weight pneumatic muscle actuators (PMAs) fulfilled the ambulatory requirements of the robot while also providing the actuation required to create the sagittal plane rotations at the hip and knee. The PMA is controlled by a fuzzy logic controller based on Mamdani inference for obtaining the rotational degrees of freedom. To cope with the nonlinear behaviour of the PMA towards external disturbances, a second fuzzy-based controller was also developed. In order to compensate for time dependent characteristics of the PMA, an adaptive control mechanism was introduced. Experiments were conducted on healthy subjects for understanding and estimating the performance of the adaptive fuzzy logic controller and robotic design. The human-robot interaction was mainly passive-active, while the paths were predefined.

Keywords: adaptive fuzzy logic control; robotic orthosis; gait training; pneumatic muscle actuator; PMA; neurological impairments.

DOI: 10.1504/IJISTA.2021.120497

International Journal of Intelligent Systems Technologies and Applications, 2021 Vol.20 No.3, pp.199 - 214

Received: 04 Jun 2020
Accepted: 04 Sep 2020
Published online: 24 Jan 2022 *

Full-text access for editors Full-text access for subscribers Purchase this article Comment on this article

Title: Adaptive fuzzy logic control for a robotic gait training orthosis

Keep up-to-date