• Title of article

    Inverse kinematics of a 6 DoF human upper limb using ANFIS and ANN for anticipatory actuation in ADL-based physical Neurorehabilitation

  • Author/Authors

    Pérez-Rodrيguez، نويسنده , , Rodrigo and Marcano-Cedeٌo، نويسنده , , Alexis and Costa، نويسنده , , عrsula and Solana، نويسنده , , Javier and Cلceres، نويسنده , , César and Opisso، نويسنده , , Eloy and Tormos، نويسنده , , Josep M. and Medina، نويسنده , , Josep and Gَmez، نويسنده , , Enrique J.، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2012
  • Pages
    11
  • From page
    9612
  • To page
    9622
  • Abstract
    Objective esearch is focused in the creation and validation of a solution to the inverse kinematics problem for a 6 degrees of freedom human upper limb. This system is intended to work within a real-time dysfunctional motion prediction system that allows anticipatory actuation in physical Neurorehabilitation under the assisted-as-needed paradigm. For this purpose, a multilayer perceptron-based and an ANFIS-based solution to the inverse kinematics problem are evaluated. als and methods he multilayer perceptron-based and the ANFIS-based inverse kinematics methods have been trained with three-dimensional Cartesian positions corresponding to the end-effector of healthy human upper limbs that execute two different activities of the daily life: ‘serving water from a jar’ and ‘picking up a bottle’. Validation of the proposed methodologies has been performed by a 10 fold cross-validation procedure. s rained, the systems are able to map 3D positions of the end-effector to the corresponding healthy biomechanical configurations. A high mean correlation coefficient and a low root mean squared error have been found for both the multilayer perceptron and ANFIS-based methods. sions tained results indicate that both systems effectively solve the inverse kinematics problem, but, due to its low computational load, crucial in real-time applications, along with its high performance, a multilayer perceptron-based solution, consisting in 3 input neurons, 1 hidden layer with 3 neurons and 6 output neurons has been considered the most appropriated for the target application.
  • Keywords
    Neurorehabilitation , Activities of the daily living , Biomechanical model , Upper Limb , Inverse kinematics , Motion prediction
  • Journal title
    Expert Systems with Applications
  • Serial Year
    2012
  • Journal title
    Expert Systems with Applications
  • Record number

    2352268