Reaction moments matter when designing lower-extremity robots for tripping recovery

Abstract: Balance recovery after tripping often requires an active adaptation of foot placement. Thus far, few attempts have been made to actively assist forward foot placement for balance recovery employing wearable devices. This study aims to explore the possibilities of active forward foot placement through two paradigms of actuation: assistive moments exerted with the reaction moments either internal or external to the human body, namely ‘joint’ moments and ‘free’ moments, respectively. Both paradigms can be applied… Show more

“…The individual gyroscopic actuators (approx. 1.5 kg) can help study populations with altered lower and upper extremity function, for instance by: modifying cueing in people with Parkinson's disease [58], modifying inertial properties of objects for grasping tasks [59], through telerehabilitation [60], or by assisting obstacle avoidance [61]. In the current study, arm swing was restricted to increase task difficulty and reduce its influence on H and trunk angular velocity variability [41].…”

Light-Weight Wearable Gyroscopic Actuators Can Modulate Balance Performance and Gait Characteristics: A Proof-of-Concept Study

“…The individual gyroscopic actuators (approx. 1.5 kg) can help study populations with altered lower and upper extremity function, for instance by: modifying cueing in people with Parkinson's disease [58], modifying inertial properties of objects for grasping tasks [59], through telerehabilitation [60], or by assisting obstacle avoidance [61]. In the current study, arm swing was restricted to increase task difficulty and reduce its influence on H and trunk angular velocity variability [41].…”

Light-Weight Wearable Gyroscopic Actuators Can Modulate Balance Performance and Gait Characteristics: A Proof-of-Concept Study

A Gait Recognition of EMG Signal Method Based on Bat Algorithm Optimized KNN