Density theorems for the constraint equations

In this paper, the kinematic calibration of a planar two-degree-of-freedom redundantly actuated parallel manipulator is studied without any assumption on parameters. A cost function based on closed-loop constraint equations is first formulated. Using plane geometry theory, we analyze the pose transformations that bring infinite solutions and present a kinematic calibration integrated of closed-loop and open-loop methods. In the integrated method, the closed-loop calibration solves all the solutions that fit the constraint equations, and the open-loop calibration guarantees the uniqueness of the solution. In the experiments, differential evolution is applied to compute the solution set, for its advantages in computing multi-optima. Experimental results show that all the parameters involved are calibrated with high accuracy.

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Density theorems and extremal hypergraph problems

Israel Journal of Mathematics ◽

10.1007/bf02771992 ◽

2006 ◽

Vol 152 (1) ◽

pp. 371-380 ◽

Cited By ~ 9

Author(s):

V. Rödl ◽

E. Tengan ◽

M. Schacht ◽

N. Tokushige

Keyword(s):

Density Theorems ◽

Extremal Hypergraph

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Systematic Construction of the Equations of Motion for Multibody Systems Containing Closed Kinematic Loops

15th Design Automation Conference: Volume 3 — Mechanical Systems Analysis, Design and Simulation ◽

10.1115/detc1989-0102 ◽

1989 ◽

Author(s):

P. E. Nikravesh ◽

G. Gim

Keyword(s):

Equations Of Motion ◽

Transformation Matrix ◽

Velocity Transformation ◽

Constraint Equations ◽

Advantages And Disadvantages ◽

Lagrange Multiplier Technique ◽

Joint Coordinates ◽

Minimum Number ◽

Kinematic Loops ◽

Equations Of Motions

Abstract This paper presents a systematic method for deriving the minimum number of equations of motion for multibody system containing closed kinematic loops. A set of joint or natural coordinates is used to describe the configuration of the system. The constraint equations associated with the closed kinematic loops are found systematically in terms of the joint coordinates. These constraints and their corresponding elements are constructed from known block matrices representing different kinematic joints. The Jacobian matrix associated with these constraints is further used to find a velocity transformation matrix. The equations of motions are initially written in terms of the dependent joint coordinates using the Lagrange multiplier technique. Then the velocity transformation matrix is used to derive a minimum number of equations of motion in terms of a set of independent joint coordinates. An illustrative example and numerical results are presented, and the advantages and disadvantages of the method are discussed.

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Efficient Dynamic Analysis Method for Multibody Systems With Constraint Violation Stabilization Method

Volume 7A: 17th Biennial Conference on Mechanical Vibration and Noise ◽

10.1115/detc99/vib-8255 ◽

1999 ◽

Author(s):

Apiwat Reungwetwattana ◽

Shigeki Toyama

Keyword(s):

Dynamic Analysis ◽

Multibody Systems ◽

Analysis Method ◽

Stabilization Method ◽

Kinematic Constraint ◽

Constraint Violation ◽

Closed Loops ◽

Constraint Stabilization ◽

Constraint Equations ◽

Crank Mechanism

Abstract This paper presents an efficient extension of Rosenthal’s order-n algorithm for multibody systems containing closed loops. Closed topological loops are handled by cut joint technique. Violation of the kinematic constraint equations of cut joints is corrected by Baumgarte’s constraint violation stabilization method. A reliable approach for selecting the parameters used in the constraint stabilization method is proposed. Dynamic analysis of a slider crank mechanism is carried out to demonstrate efficiency of the proposed method.

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Kinematic Fixturing With Respect to a Plane Using Contact Sensing

Volume 1B: 25th Biennial Mechanisms Conference ◽

10.1115/detc98/mech-5907 ◽

1998 ◽

Author(s):

Walter W. Nederbragt ◽

Bahram Ravani

Keyword(s):

Spatial Constraint ◽

Spatial Constraints ◽

Constraint Equations ◽

Contact Sensing ◽

Geometric Elements ◽

Work Cells

Abstract This paper presents a method for determining the location of geometric elements that compose the external features of referencing fixtures. Since in most applications parts that are handled in robotic work-cells are on a worktable or a floor, this paper focuses on fixture geometries that reside on a plane of known location. The location of the unknown geometric elements are found using contacts to the geometric elements and spatial constraints between the geometric elements. Geometric equations for contacts between lines, planes, points, spheres, and cylinders are derived. Spatial constraint equations are also derived. An algorithm is given for locating the geometric elements that form the fixture. The algorithm uses the contact equations and spatial constraint equations to locate the geometric elements. To illustrate the use of this algorithm, two examples are described in detail.

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