Abstract
A significant challenge for the control of a robotic lower extremity rehabilitation exoskeleton is to ensure stability and robustness during programmed tasks or motions, which is crucial for the safety of the mobility-impaired user. Due to various levels of the user’s disability, the human-exoskeleton interaction forces and external perturbations are unpredictable and could vary substantially and cause conventional motion controllers to behave unreliably or the robot to fall down. In this work, we propose a new, reinforcement learning-based, motion controller for a lower extremity rehabilitation exoskeleton, aiming to perform collaborative squatting exercises with efficiency, stability, and strong robustness. Unlike most existing rehabilitation exoskeletons, our exoskeleton has ankle actuation on both sagittal and front planes and is equipped with multiple foot force sensors to estimate center of pressure (CoP), an important indicator of system balance. This proposed motion controller takes advantage of the CoP information by incorporating it in the state input of the control policy network and adding it to the reward during the learning to maintain a well balanced system state during motions. In addition, we use dynamics randomization and adversary force perturbations including large human interaction forces during the training to further improve control robustness. To evaluate the effectiveness of the learning controller, we conduct numerical experiments with different settings to demonstrate its remarkable ability on controlling the exoskeleton to repetitively perform well balanced and robust squatting motions under strong perturbations and realistic human interaction forces.
Highlights
Due to the aging population and other factors, an increasing number of people are suffering from neurological disorders, such as stroke, central nervous system disorder, and spinal cord injury (SCI) that affect the patient’s mobility
Inspired by the center of pressure (CoP)-associated balance and stability (Lee and Goswami, 2012), this paper aims to explore a robust motion controller to encourage the system CoP to stay inside a stable region when subjected to the uncertainty of human interaction and perturbations
We propose a novel robust control framework based on reinforcement learning (RL) to train a robust control policy that operates on the exoskeleton in real-time so as to overcome the external perturbations and unpredictable varying humanexoskeleton force
Summary
Due to the aging population and other factors, an increasing number of people are suffering from neurological disorders, such as stroke, central nervous system disorder, and spinal cord injury (SCI) that affect the patient’s mobility. Squatting exercises are very common for resistance-training programs because their multiple-joint movements are a characteristic of most sports and daily living activities. In rehabilitation, squatting is commonly performed as an important exercise for patients during the recovery of various lower extremity injuries (McGinty et al, 2000; Salem and Powers, 2001; Crossley et al, 2011; Yu et al, 2019). With a reliable lower extremity rehabilitation exoskeleton, performing squatting exercises without external help (e.g., from a clinician) will be a confidence boost for patients to use the exoskeleton independently. In order for the exoskeletons to cooperate with the human without causing risks of harm, advanced balance controllers to robustly perform squatting motion that can deal with a broad range of environment conditions and external perturbations need to be developed
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