scholarly journals Discussion: “Complete Solution of the Nine-Point Path Synthesis Problem for Four-Bar Linkages” (Wampler, C.W., Morgan, A. P., and Sommese, A. J., 1992, ASME J. Mech. Des., 114, pp. 153–159)

1997 ◽  
Vol 119 (1) ◽  
pp. 149-150
Author(s):  
Preben W. Jensen
Keyword(s):  
Complete Solution ◽  
Synthesis Problem ◽  
Path Synthesis

Complete Solution of the Nine-Point Path Synthesis Problem for Four-Bar Linkages

1992 ◽  
Vol 114 (1) ◽  
pp. 153-159 ◽  
Author(s):  
C. W. Wampler ◽  
A. P. Morgan ◽  
A. J. Sommese
Keyword(s):  
Unsolved Problem ◽  
Complete Solution ◽  
Synthesis Problem ◽  
Computer Algorithm ◽  
All Solutions ◽  
Path Synthesis

The problem of finding all four-bar linkages whose coupler curve passes through nine prescribed points has been a longstanding unsolved problem in kinematics. Using a combination of classical elimination, multihomogeneous variables, and numerical polynomial continuation, we show that there are generically 1442 nondegenerate solution along with their Roberts cognates, for a total of 4326 distinct solutions. Moreover, a computer algorithm that computes all solutions for any given nine points has been developed.

scholarly journals Comparison of some evolutionary algorithms for optimization of the path synthesis problem

2018 ◽  
Author(s):  
Jakub Krzysztof Grabski ◽  
Tomasz Walczak ◽  
Jacek Buśkiewicz ◽  
Martyna Michałowska
Keyword(s):  
Evolutionary Algorithms ◽  
Synthesis Problem ◽  
Path Synthesis

Synthesis of Defect Free Six Bar Linkages for Body Guidance Through up to Six Finitely Separated Positions

1994 ◽  
Author(s):  
Timothy Tylaska ◽  
Kazem Kazerounian
Keyword(s):  
Design Problem ◽  
Design Methodology ◽  
Complete Solution ◽  
Higher Order ◽  
Synthesis Problem ◽  
Design Constraint ◽  
Solution Sets ◽  
Constraint Equations ◽  
Design Considerations ◽  
Highly Nonlinear

Abstract In the synthesis of watt I six bar linkage, for finitely separated design positions, or in higher order design, constraint equations become highly nonlinear and transcendental. This paper presents a method to decouple the synthesis problem to the synthesis of two path generator 4-bar linkages. Based on this decoupled system, an explicit design methodology is developed, enabling a three, four, five or six body guidance position Watt I linkage to be designed while the designer has choice of some body pivots and ground pivots. Numerical procedures for higher number of positions are also discussed. The methodology allows the designer to obtain an entire set of solutions to a particular design problem. As a spin off from this work, a methodology is also presented to obtain complete solution sets of four bar path generators capable of passing through up to seven precision points, with a procedure that can be eventually extended to eight and nine path points. Design considerations such as branching and transmission angles are also considered.

scholarly journals Finding Only Finite Roots to Large Kinematic Synthesis Systems

2017 ◽  
Vol 9 (2) ◽  
Author(s):  
Mark M. Plecnik ◽  
Ronald S. Fearing
Keyword(s):  
Polynomial Systems ◽  
Synthesis Problem ◽  
New Method ◽  
Homotopy Continuation ◽  
Kinematic Synthesis ◽  
Root Finding ◽  
Large Polynomial Systems ◽  
Path Synthesis

In this work, a new method is introduced for solving large polynomial systems for the kinematic synthesis of linkages. The method is designed for solving systems with degrees beyond 100,000, which often are found to possess quantities of finite roots that are orders of magnitude smaller. Current root-finding methods for large polynomial systems discover both finite and infinite roots, although only finite roots have meaning for engineering purposes. Our method demonstrates how all infinite roots can be precluded in order to obtain substantial computational savings. Infinite roots are avoided by generating random linkage dimensions to construct startpoints and start systems for homotopy continuation paths. The method is benchmarked with a four-bar path synthesis problem.

Fourier series method for path generation of RCCC mechanism

2011 ◽  
Vol 226 (3) ◽  
pp. 816-827 ◽  
Author(s):  
J W Sun ◽  
D Q Mu ◽  
J K Chu
Keyword(s):  
Fourier Series ◽  
Frequency Domain ◽  
Synthesis Problem ◽  
Mathematical Representation ◽  
Path Generation ◽  
Series Method ◽  
Internal Relation ◽  
Fourier Series Method ◽  
Mathematical Equations ◽  
Path Synthesis

The mathematical representation of the coupler curves of RCCC mechanism is established. The coupler curve of RCCC mechanism is analysed using the Fourier series theory. The internal relation between the coupler curve and the dimensional type of the RCCC mechanism in the frequency domain is discovered. Subsequently, a database comprising millions of basic dimensional types, taking the crank–rocker linkages as an example, is established. Based on the information of prescribed coupler and the database, the best suitable basic dimensional type can be determined by identification. The mathematical equations for calculating actual dimensions of mechanism and positional dimensions of installation are deduced. Thus, the path synthesis problem of RCCC mechanism can be solved by the mathematic equations and the basic dimensional type. The calculation illustration is given later in this article.

A Study on Finding Finite Roots for Kinematic Synthesis

2017 ◽  
Author(s):  
Mark M. Plecnik ◽  
Ronald S. Fearing
Keyword(s):  
Random Process ◽  
Synthesis Problem ◽  
Homotopy Continuation ◽  
Synthesis System ◽  
Expected Number ◽  
Kinematic Synthesis ◽  
Scaling Down ◽  
Path Synthesis ◽  
Number Of Iterations

This study presents new results on a method to solve large kinematic synthesis systems termed Finite Root Generation. The method reduces the number of startpoints used in homotopy continuation to find all the roots of a kinematic synthesis system. For a single execution, many start systems are generated with corresponding startpoints using a random process such that start-points only track to finite roots. Current methods are burdened by computations of roots to infinity. New results include a characterization of scaling for different problem sizes, a technique for scaling down problems using cognate symmetries, and an application for the design of a spined pinch gripper mechanism. We show that the expected number of iterations to perform increases approximately linearly with the quantity of finite roots for a given synthesis problem. An implementation that effectively scales the four-bar path synthesis problem by six using its cognate structure found 100% of roots in an average of 16,546 iterations over ten executions. This marks a roughly six-fold improvement over the basic implementation of the algorithm.

Finding Only Finite Roots to Large Kinematic Synthesis Systems

2016 ◽  
Author(s):  
Mark M. Plecnik ◽  
Ronald S. Fearing
Keyword(s):  
Polynomial Systems ◽  
Synthesis Problem ◽  
New Method ◽  
Homotopy Continuation ◽  
Kinematic Synthesis ◽  
Root Finding ◽  
Large Polynomial Systems ◽  
Path Synthesis

In this work, a new method is introduced for solving large polynomial systems for the kinematic synthesis of linkages. The method is designed for solving systems with degrees beyond 100,000, which often are found to possess a number of finite roots that is orders of magnitude smaller. Current root-finding methods for large polynomial systems discover both finite and infinite roots, although only finite roots have meaning for engineering purposes. Our method demonstrates how all infinite roots can be avoided in order to obtain substantial computational savings. Infinite roots are avoided by generating random linkage dimensions to construct start-points and start-systems for homotopy continuation paths. The method is benchmarked with a four-bar path synthesis problem.

The Complete Solution of Alt–Burmester Synthesis Problems for Four-Bar Linkages

2016 ◽  
Vol 8 (4) ◽  
Author(s):  
Daniel A. Brake ◽  
Jonathan D. Hauenstein ◽  
Andrew P. Murray ◽  
David H. Myszka ◽  
Charles W. Wampler
Keyword(s):  
Algebraic Geometry ◽  
Rigid Body ◽  
Finite Number ◽  
Complete Solution ◽  
Numerical Algebraic Geometry ◽  
Number Of Solutions ◽  
One Dimensional ◽  
The Family ◽  
Path Synthesis ◽  
Path Point

Precision-point synthesis problems for design of four-bar linkages have typically been formulated using two approaches. The exclusive use of path-points is known as “path synthesis,” whereas the use of poses, i.e., path-points with orientation, is called “rigid-body guidance” or the “Burmester problem.” We consider the family of “Alt–Burmester” synthesis problems, in which some combination of path-points and poses is specified, with the extreme cases corresponding to the classical problems. The Alt–Burmester problems that have, in general, a finite number of solutions include Burmester's original five-pose problem and also Alt's problem for nine path-points. The elimination of one path-point increases the dimension of the solution set by one, while the elimination of a pose increases it by two. Using techniques from numerical algebraic geometry, we tabulate the dimension and degree of all problems in this Alt–Burmester family, and provide more details concerning all the zero- and one-dimensional cases.

Sign in / Sign up

Export Citation Format

Share Document