A Passivity-based Concurrent Whole-Body Control (cWBC) of Persistently Interacting Human-Exoskeleton Systems
This work addresses power augmentation for healthy operators in manufacturing to reduce injury risks, representing an incremental improvement in exoskeleton control.
The paper tackles the problem of controlling human-exoskeleton systems for power augmentation by proposing a concurrent whole-body control method that cancels gravity, maintains balance, and amplifies human forces, resulting in a passive dynamic system with dissipated energy until a minimum is reached.
This paper presents a concurrent whole-body control (cWBC) for human-exoskeleton systems that are tightly coupled at a Cartesian level (e.g., feet, hands, torso). The exoskeleton generates joint torques that i) cancel the effects of gravity on the coupled system, ii) perform a primary task (e.g., maintaining the balance of the system), and iii) exploit the kinematic redundancy of the system to amplify the forces exerted by the human operator. The coupled dynamic system is demonstrated to be passive, as its overall energy always goes dissipated until a minimum is reached. The proposed method is designed specifically to control exoskeletons for power augmentation worn by healthy operators in applications such as manufacturing, as it allows to increase the worker's capabilities, therefore reducing the risk of injuries.