Mancisidor, AitziberZubizarreta, AsierCabanes, ItziarBengoa, PabloJung, Je Hyung2018-02Mancisidor , A , Zubizarreta , A , Cabanes , I , Bengoa , P & Jung , J H 2018 , ' Kinematical and dynamical modeling of a multipurpose upper limbs rehabilitation robot ' , Robotics and Computer-Integrated Manufacturing , vol. 49 , pp. 374-387 . https://doi.org/10.1016/j.rcim.2017.08.0131879-2537researchoutputwizard: 11556/423Publisher Copyright: © 2017 Elsevier LtdKnowing accurate model of a system is always beneficial to design a robust and safe control while allowing reduction of sensors-related cost as the system outputs are predictable using the model. In this context, this paper addresses the kinematical and dynamical model identification of the multipurpose rehabilitation robot, Universal Haptic Pantograph (UHP), and present experimental validations of the identified models. The UHP is a Pantograph based innovative robot actuated by two SEAs (Series Elastic Actuator), aiming at training impaired upper limbs after a stroke. This novel robot, thanks to its lockable/unlockable joints, can change its mechanical structure so that it enables stroke patient to perform different training exercises of the shoulder, elbow and wrist. This work focuses on the ARM mode, which is a training mode used to rehabilitate elbow and shoulder. The kinematical model of UHP is identified based on the loop vector equations, while the dynamical model is derived based on the Lagrangian formulation. To demonstrate the accuracy of the models, several experimental tests were performed. The results reveal that the mean position error between estimated values with the model and actual measured values stays in 3 mm (less than 2% of the maximum motion range). Moreover, the error between estimated and measured interaction force is smaller than 10% of maximum force range. So, the developed models can be adopted to estimate motion and force of UHP as well as control it without the need of additional sensors such as a force sensor, resulting in the reduction of total robot cost.143960957enginfo:eu-repo/semantics/openAccessjournal article10.1016/j.rcim.2017.08.013Upper limb rehabilitationRehabilitation robotsKinematical modelingDynamical modelingForce estimationExperimental validationUpper limb rehabilitationRehabilitation robotsKinematical modelingDynamical modelingForce estimationExperimental validationControl and Systems EngineeringSoftwareGeneral MathematicsComputer Science ApplicationsIndustrial and Manufacturing EngineeringSDG 3 - Good Health and Well-beingFunding InfoThis work was supported in part by the Basque Country Governments_x000D_ (GV/EJ) under grant PRE-2014-1-152, UPV/EHU’s PPG17/56_x000D_ project, Basque Country Governments IT914-16 project, Spanish Ministry_x000D_ of Economy and Competitiveness’ MINECO & FEDER inside DPI-_x000D_ 2012-32882 projects, Spanish Ministry of Economy and Competitiveness_x000D_ BES-2013-066142 grant, Euskampus, FIK.This work was supported in part by the Basque Country Governments_x000D_ (GV/EJ) under grant PRE-2014-1-152, UPV/EHU’s PPG17/56_x000D_ project, Basque Country Governments IT914-16 project, Spanish Ministry_x000D_ of Economy and Competitiveness’ MINECO & FEDER inside DPI-_x000D_ 2012-32882 projects, Spanish Ministry of Economy and Competitiveness_x000D_ BES-2013-066142 grant, Euskampus, FIK.http://www.scopus.com/inward/record.url?scp=85027835209&partnerID=8YFLogxK