Energies of Accelerations in Advanced Robotics Dynamics

Iuliu Negrean; Kalman Kacso; Claudiu Schonstein

doi:10.4028/www.scientific.net/AMM.762.67

Paper Titles

Hydraulic and Termographical Test Rig for Automatic Gearboxes
p.41

Bending Vibrations of a Viscoelastic Euler-Bernoulli Beam – Two Methods and Comparison
p.47

Experimental Research to Evaluate Thermal Behavior of a Brushless Driving Servomotor for Linear Motion NC Axis Experimental Stand
p.55

Computer Assisted Selection of Servomotor Driving System for Linear Motion NC Axis Experimental Stand
p.61

Energies of Accelerations in Advanced Robotics Dynamics
p.67

Reconfigurable Anthropomorphic Gripper with Three Fingers: Synthesis, Analysis, and Simulation
p.75

Structure and Control Method for a Pneumatic Muscle Actuated Seat Used in a Motion Simulator
p.83

Hybrid Force-Position Humanoid Hand Control in 3D Virtual Environment
p.91

Rigid versus Flexible Link Dynamic Analysis of a 3DOF Delta Type Parallel Manipulator
p.101

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 762Energies of Accelerations in Advanced Robotics...

Energies of Accelerations in Advanced Robotics Dynamics

Abstract:

This paper is devoted to the presentation of new formulations on the higher order motion energies that are used in the advanced dynamic study of robots. Integral part of these mechanical systems are the mechanical robot structures, on which an application will be presented in order to highlight the importance of the higher order motion energies regarding the dynamic behavior. In current dynamic studies, the kinetic energy is used as a central function in Lagrange - Euler equations. This paper extends the study by developing the acceleration energies of first, second and third order and their implementation in differential equations of motion of third and fourth order, which gives the possibility of applying the initial motion conditions in positions, velocities and accelerations of first and second order. This leads to a more precise control on the transitory motion phases of the multibody systems, in which the robot structures are included.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volume 762)

Pages:

67-73

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.762.67

Citation:

Cite this paper

Online since:

May 2015

Authors:

Iuliu Negrean*, Kalman Kacso, Claudiu Schonstein

Keywords:

Dynamic, Energies of Higher Order, Modeling, Multibody Systems, Robotics

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] M. D. Ardema, Analytical Dynamics Theory and Applications, Springer US, ISBN 978-0-306-48681-4, pp.225-243, 245-259, (2006).

Google Scholar

[2] B. N. Frandlin, L. D. Roshchupkin, On the Dolapchiev – Manzheron – Tsenov equations in the Case of Natural Systems, Soviet Applied Mechanics, Vol. 9, Issue 3, pp.251-254, (1973).

DOI: 10.1007/bf00885328

Google Scholar

[3] I. Negrean, D. C. Negrean, Matrix exponentials to robot kinematics, 17th International Conference on Robotics and Factories of the Future, Vol. 2, pp.1250-1257, Durban, (2001).

Google Scholar

[4] I. Negrean, A. Duca, D. C. Negrean, K. Kacso, Mecanică avansată în robotică, ISBN 978-973-662-420-9, UT Press, Cluj-Napoca, (2008), http: /users. utcluj. ro/~inegrean.

Google Scholar

[5] I. Negrean, C. Schonstein, K. Kacso, A. Duca, Mecanică. Teorie şi aplicaţii, Editura UT PRESS, ISBN 978-973-662-523-7, Cluj – Napoca, (2012).

Google Scholar

[6] F. C. Park, Computational Aspects of the Product-of-Exponentials Formula for Robot Kinematics, IEEE Transaction on Automatic Control, (1994).

DOI: 10.1109/9.280779

Google Scholar

[7] F. P. J. Rimrott, B. Tabarrok, Complementary Formulation of the Appell Equation, Technische Mechanik, Band 16, Heft 2 pp.187-196, (1996).

Google Scholar

[8] P. P. Teodorescu, Sisteme mecanice. Modele clasice, Vol. IV, ISBN 973-31-1082-5, Ed. Tehnică, Bucureşti, (2002).

Google Scholar