@Article{cmes.2025.069167,
AUTHOR = {Mohammad Soleimani Amiri, Sahbi Boubaker, Rizauddin Ramli, Souad Kamel},
TITLE = {Radial Basis Function Neural Network Adaptive Controller for Wearable Upper-Limb Exoskeleton with Disturbance Observer},
JOURNAL = {Computer Modeling in Engineering \& Sciences},
VOLUME = {144},
YEAR = {2025},
NUMBER = {3},
PAGES = {3113--3133},
URL = {http://www.techscience.com/CMES/v144n3/63954},
ISSN = {1526-1506},
ABSTRACT = {Disability is defined as a condition that makes it difficult for a person to perform certain vital activities. In recent years, the integration of the concepts of intelligence in solving various problems for disabled persons has become more frequent. However, controlling an exoskeleton for rehabilitation presents challenges due to their non-linear characteristics and external disturbances caused by the structure itself or the patient wearing the exoskeleton. To remedy these problems, this paper presents a novel adaptive control strategy for upper-limb rehabilitation exoskeletons, addressing the challenges of nonlinear dynamics and external disturbances. The proposed controller integrated a Radial Basis Function Neural Network (RBFNN) with a disturbance observer and employed a high-dimensional integral Lyapunov function to guarantee system stability and trajectory tracking performance. In the control system, the role of the RBFNN was to estimate uncertain signals in the dynamic model, while the disturbance observer tackled external disturbances during trajectory tracking. Artificially created scenarios for Human-Robot interactive experiments and periodically repeated reference trajectory experiments validated the controller’s performance, demonstrating efficient tracking. The proposed controller is found to achieve superior tracking accuracy with Root-Mean-Squared (RMS) errors of 0.022–0.026 rad for all joints, outperforming conventional Proportional-Integral-Derivative (PID) by 73% and Neural-Fuzzy Adaptive Control (NFAC) by 389.47% lower error. These results suggested that the RBFNN adaptive controller, coupled with disturbance compensation, could serve as an effective rehabilitation tool for upper-limb exoskeletons. These results demonstrate the superiority of the proposed method in enhancing rehabilitation accuracy and robustness, offering a promising solution for the control of upper-limb assistive devices. Based on the obtained results and due to their high robustness, the proposed control schemes can be extended to other motor disabilities, including lower limb exoskeletons.},
DOI = {10.32604/cmes.2025.069167}
}