Abstract
The study of human balance recovery strategies is important for human balance rehabilitation and humanoid robot balance control. To date, many efforts have been made to improve balance during quiet standing and walking motions. Arm usage (arm strategy) has been proposed to control the balance during walking motion in the literature. However, limited research exists on the contributions of the arm strategy for balance recovery during quiet standing along with ankle and hip strategy. Therefore, in this study, we built a simplified model with arms and proposed a controller based on nonlinear model predictive control to achieve human-like balance control. Three arm states of the model, namely, active arms, passive arms, and fixed arms, were considered to discuss the contributions of arm usage to human balance recovery during quiet standing. Furthermore, various indexes such as root mean square deviation of joint angles and recovery energy consumption were verified to reveal the mechanism behind arm strategy employment. In this study, we demonstrate to computationally reproduce human-like balance recovery with and without arm rotation during quiet standing while applying different magnitudes of perturbing forces on the upper body. In addition, the conducted human balance experiments are presented as supplementary information in this paper to demonstrate the concept on a typical example of arm strategy.
Highlights
Balance control mechanism of human has been researched to enhance balance ability of human and humanoid robots (Winter, 1995)
We pushed the position of the center of mass of the upper body with different disturbing forces backward and forward for 1 [s], which could be different with the previous study on perturbation setting with a balance board (Chumacero and Yang, 2019, 2020)
This indicates that the active arm rotation strategy widens the range of the disturbing forces; this result is similar to the conclusions derived in Nakada et al (2010) and Kuindersma et al (2011)
Summary
Balance control mechanism of human has been researched to enhance balance ability of human and humanoid robots (Winter, 1995). Principal balance recovery strategies, namely, ankle, hip, and stepping strategies have been studied based on human experiments (Nashner, 1985; Horak and Nashner, 1986; Horak et al, 1990) and artificial systems (Kuo and Zajac, 1993; Kuo, 1995; Shen et al, 2020b) These strategies have been considered as efficient means to help preventing falls and analyze the mechanism of balance control during standing and walking motions in human rehabilitation and humanoid robot control. These arm strategies are relevant for stability improvement and energy efficiency in human and humanoid/bipedal walking and standing They did not leverage nonlinear model predictive control (NMPC) for addressing multiple constraints of the ankle, hip, arm joint angles, and torques and reproducing human-like balance recovery controller in their artificial systems.
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