Gait trajectory-based interactive controller for lower limb exoskeletons for construction workers

Lower limb exoskeletons (LLEs) are sets of mechanical devices used to support the action of human lower limbs. This recently developed technology has unprecedented potential in the construction industry by increasing the strength, endurance, and other physical capabilities of construction workers. For safety considerations, LLEs need reliable and responsive controllers to closely match their mechanical operation with human gait in a synchronous manner. This research proposes the use of physical human-robot interactive (pHRI) controllers that are suitable for construction tasks. The proposed pHRI integrates a gait trajectory-based musculoskeletal model with iterative control algorithms. To minimize the trajectory tracking error between LLEs and human lower limbs, the gait dynamic was modeled as a spring damping and impedance model for supporting and swing phases. An iterative adaptive controller was developed for trajectory tracking and predication. To validate the proposed model, an in-lab experiment to simulate typical construction activities was conducted, allowing us to assess tracking error. The experiment results suggest that the proposed model can minimize the trajectory tracking error to a level acceptable for safe operation. The iterative controllers allow fast error convergence for different construction scenarios with proper calibration. Therefore, the proposed pHRI iterative controllers are reliable and suitable for complicated activities within the dynamic working conditions intrinsic to construction sites.

Automated summary

Lower limb exoskeletons (LLEs) have unprecedented potential in the construction industry to enhance the strength and endurance of workers. The proposed physical human-robot interactive (pHRI) controllers, integrating gait models and control algorithms, effectively minimize tracking errors, as validated in experiments ensuring safe operation levels.