Abstract
In this article, a novel controller for a nonanthropomorphic exoskeleton robot was designed to reduce joint torque of its operator using the contact force between them. Since the joints of the nonanthropomorphic exoskeletons are not directly connected to those of the operator due to the difference between their kinematic structure, joint assistance is performed by transmitting the contact force on their coupling parts instead of transmitting the joint torque of the nonanthropomorphic exoskeleton directly into the human joint. Most of the previous studies have focused on reducing the measured contact force by moving the coupling parts or commanding the robot joint torque. On the contrary, the proposed method focuses on reducing the human joint torque, which is estimated by formulating inverse dynamics, by obtaining possible contact force solutions. The commanding torque of the nonanthropomorphic exoskeleton was calculated by inverse dynamics based on the model information. To verify the control performance of the proposed method, we have developed a simulation environment for a lower-limb nonanthropomorphic exoskeleton. When the coupling part was implemented to be rigid for an ideal case, the joint torque of the human model to perform the same motion was successfully reduced by the given torque reduction ratio. For a more realistic condition, a nonrigid coupling was also implemented as a virtual spring-damper system, and its effect on the control performance was demonstrated in the simulation.
Highlights
Most exoskeletons have been designed to be anthropomorphic and fit close to their operator’s body.[1,2,3] Their joints are aligned to those of users, and assistive torque produced by actuators is directly transmitted into the corresponding human joints.[4]
We proposed a method for nonanthropomorphic exoskeletons (NAEs) to reduce joint torque of the operator using contact force transmission
The control performance was verified in simulations for a lower-limb NAE, where both rigid and nonrigid coupling were implemented for an ideal case and for a realistic condition, respectively
Summary
Most exoskeletons have been designed to be anthropomorphic and fit close to their operator’s body.[1,2,3] Their joints are aligned to those of users, and assistive torque produced by actuators is directly transmitted into the corresponding human joints.[4]. The assistive torque is determined to satisfy the given torque reduction ratios for each joint and is transmitted into the human body through the contact force on the coupling parts.
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