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
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