• Title of article

    Automatic formulation of falling multiple flexible-link robotic manipulators using 3×3 rotational matrices

  • Author/Authors

    Shafei ، Ali Mohammad - Shahid Bahonar University of Kerman

  • Pages
    26
  • From page
    15
  • To page
    40
  • Abstract
    In this paper, the effect of normal impact on the mathematical modeling of flexible multiple links is investigated. The response of such a system can be fully determined by two distinct solution procedures. Highly nonlinear differential equations are exploited to model the falling phase of the system prior to normal impact; and algebraic equations are used to model the normal collision of this open-chain robotic system. To avoid employing the Lagrangian method which suffers from too many differentiations, the governing equations of such complicated system are acquired via the Gibbs- Appell (G-A) methodology. The main contribution of the present work is the use of an automatic algorithm according to 3×3 rotational matrices to obtain the system’s motion equations more efficiently. Accordingly, all mathematical formulations are completed by the use of 3×3 matrices and 3×1 vectors only. The dynamic responses of this system are greatly reliant on the step sizes. Therefore, as well as solving the obtained differential equations by using several ODE solvers, a computer program according to the Runge-Kutta method was also developed. Finally, the computational counts of both algorithms i.e., 3×3 rotational matrices and 4×4 transformation matrices are compared to prove the efficiency of the former in deriving the motion equations.
  • Keywords
    Recursive formulation , Gibbs , Appell , Flying phase , Impact phase , 3×3 rotational matrices
  • Journal title
    Journal of Theoretical and Applied Vibration and Acoustics (TAVA)
  • Serial Year
    2017
  • Journal title
    Journal of Theoretical and Applied Vibration and Acoustics (TAVA)
  • Record number

    2452139