Article: Nonlinear optimal stabilising control of a two-wheel robot Journal: International Journal of Modelling, Identification and Control (IJMIC) 2021 Vol.38 No.2 pp.175 - 189 Abstract: The stabilisation of a two-wheel robot is a classical benchmarking problem for determining the effectiveness of a control technique. In this paper, a nonlinear optimal control technique is applied to a two-wheel robot which demonstrates excellent control performance comparing against the LQR technique. Simulation results demonstrated that this nonlinear optimal controller can achieve accurate tracking of wheel angular displacement and effective stabilisation of the robot from a very large range of initial pitch angles. Practical factors such as maximum motor voltages are considered and analysed using an extended state-space model to embed such control saturations. Significantly, the two-wheel robot can be balanced from a body pitch angle of up to 88.0° with a maximum motor voltage of 48 V using the proposed nonlinear optimal control technique, larger than any other methods achieved in the literature. Controllability studies are also performed throughout this research to facilitate understanding and visualisation of the substantial stabilisation ranges with and without control saturations. Inderscience Publishers - linking academia, business and industry through research

Title: Nonlinear optimal stabilising control of a two-wheel robot

Authors: Surapong Kokkrathoke; Andy Rawsthorne; Hongwei Zhang; Xu Xu

Addresses: Materials and Engineering Research Institute and Department of Engineering and Mathematics, College of Business, Technology and Engineering, Sheffield Hallam University, Sheffield, S1 1WB, UK ' Materials and Engineering Research Institute and Department of Engineering and Mathematics, College of Business, Technology and Engineering, Sheffield Hallam University, Sheffield, S1 1WB, UK ' Materials and Engineering Research Institute and Department of Engineering and Mathematics, College of Business, Technology and Engineering, Sheffield Hallam University, Sheffield, S1 1WB, UK ' Materials and Engineering Research Institute and Department of Engineering and Mathematics, College of Business, Technology and Engineering, Sheffield Hallam University, Sheffield, S1 1WB, UK

Abstract: The stabilisation of a two-wheel robot is a classical benchmarking problem for determining the effectiveness of a control technique. In this paper, a nonlinear optimal control technique is applied to a two-wheel robot which demonstrates excellent control performance comparing against the LQR technique. Simulation results demonstrated that this nonlinear optimal controller can achieve accurate tracking of wheel angular displacement and effective stabilisation of the robot from a very large range of initial pitch angles. Practical factors such as maximum motor voltages are considered and analysed using an extended state-space model to embed such control saturations. Significantly, the two-wheel robot can be balanced from a body pitch angle of up to 88.0° with a maximum motor voltage of 48 V using the proposed nonlinear optimal control technique, larger than any other methods achieved in the literature. Controllability studies are also performed throughout this research to facilitate understanding and visualisation of the substantial stabilisation ranges with and without control saturations.

Keywords: nonlinear system; optimal stabilising control; controllability; two-wheel robot.

DOI: 10.1504/IJMIC.2021.122501

International Journal of Modelling, Identification and Control, 2021 Vol.38 No.2, pp.175 - 189

Received: 12 Jan 2021
Accepted: 11 May 2021
Published online: 28 Apr 2022 *

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Title: Nonlinear optimal stabilising control of a two-wheel robot

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