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Successive dynamic programming and subsequent spline optimization for smooth time optimal robot path tracking (2015)

Oberherber, M. ; Gattringer, H. ; Müller, A.

Copernicus

In: Mechanical Sciences. 2015; 6(2): 245-254. Published 2015 Oct 26. doi: 10.5194/ms-6-245-2015.

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Publication Date: 2015-10-26

Description: The time optimal path tracking for industrial robots regards the problem of generating trajectories that follow predefined end-effector (EE) paths in shortest time possible taking into account kinematic and dynamic constraints. The complicated tasks used in industrial applications lead to very long EE paths. At the same time smooth trajectories are mandatory in order to increase the service life. The consideration of jerk and torque rate restrictions, necessary to achieve smooth trajectories, causes enormous numerical effort, and increases computation times. This is in particular due to the high number of optimization variables required for long geometric paths. In this paper we propose an approach where the path is split into segments. For each individual segment a smooth time optimal trajectory is determined and represented by a spline. The overall trajectory is then found by assembling these splines to the solution for the whole path. Further we will show that by using splines, the jerks are automatically bounded so that the jerk constraints do not have to be imposed in the optimization, which reduces the computational complexity. We present experimental results for a six-axis industrial robot. The proposed approach provides smooth time optimal trajectories for arbitrary long geometric paths in an efficient way.

Print ISSN: 2191-9151

Electronic ISSN: 2191-916X

Topics: Physics

Published by Copernicus on behalf of Delft University of Technology.

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A two-stage calibration method for industrial robots with joint and drive flexibilities (2015)

Neubauer, M. ; Gattringer, H. ; Müller, A. ; [et al.]

Copernicus

In: Mechanical Sciences. 2015; 6(2): 191-201. Published 2015 Sep 11. doi: 10.5194/ms-6-191-2015.

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Publication Date: 2015-09-11

Description: Dealing with robot calibration the neglection of joint and drive flexibilities limit the achievable positioning accuracy significantly. This problem is addressed in this paper. A two stage procedure is presented where elastic deflections are considered for the calculation of the geometric parameters. In the first stage, the unknown stiffness and damping parameters are identified. To this end the model based transfer functions of the linearized system are fitted to captured frequency responses of the real robot. The real frequency responses are determined by exciting the system with periodic multisine signals in the motor torques. In the second stage, the identified elasticity parameters in combination with the measurements of the motor positions are used to compute the real robot pose. On the basis of the estimated pose the geometric calibration is performed and the error between the estimated end-effector position and the real position measured with an external sensor (laser-tracker) is minimized. In the geometric model, joint offsets, axes misalignment, length errors and gear backlash are considered and identified. Experimental results are presented, where a maximum end-effector error (accuracy) of 0.32 mm and for 90 % of the poses a maximum error of 0.23 mm was determined (Stäubli TX90L).

Print ISSN: 2191-9151

Electronic ISSN: 2191-916X

Topics: Physics

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Representation of the kinematic topology of mechanisms for kinematic analysis (2015)

Müller, A.

Copernicus

In: Mechanical Sciences. 2015; 6(2): 137-146. Published 2015 Aug 12. doi: 10.5194/ms-6-137-2015.

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Publication Date: 2015-08-12

Description: The kinematic modeling of multi-loop mechanisms requires a systematic representation of the kinematic topology, i.e. the arrangement of links and joints. A linear graph, called the topological graph, is used to this end. Various forms of this graph have been introduced for application in mechanism kinematics and multibody dynamics aiming at matrix formulations of the governing equations. For the (higher-order) kinematic analysis of mechanisms a simple yet stringent representation of the topological information is often sufficient. This paper proposes a simple concept and notation for use in kinematic analysis. Upon a topological graph, an order relation of links and joints is introduced allowing for recursive computation of the mechanism configuration. An ordering is also introduced on the topologically independent fundamental cycles. The latter is indispensable for formulating generically independent loop closure constraints. These are presented for linkages with only lower pairs, as well as for mechanisms with one higher kinematic pair per fundamental cycle. The corresponding formulation is known as cut-body and cut-joint approach, respectively.

Print ISSN: 2191-9151

Electronic ISSN: 2191-916X

Topics: Physics

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