A Computer-Aided Design Technique for Semi-Automated Infinite Point Coupler Curve Synthesis of Four-Bar Linkages

Unruh, Vicky; Krishnaswami, Prakash

doi:10.1115/1.2826099

Cited by 35 publications

(6 citation statements)

References 1 publication

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The solver requires the use of precision points approximating the desired curve, while a cost function minimizes the error between the actual and desired coupler curves. Other techniques such as machine learning and neural network approaches [8,9] rely on a database of linkage solutions. Such techniques may suffer from the coverage of mechanisms in the database and sampling techniques.…”

Section: Introduction To Linkage Synthesismentioning

confidence: 99%

Appropriate synthesis of the four-bar linkage

Pickard

Carretero

Merlet

2020

Mechanism and Machine Theory

View full text Add to dashboard Cite

The uncertainties arising from the fabrication and operation of mechanisms, specifically the four-bar linkage, significantly affect the expected performance of the mechanism. To accommodate uncertainties during the dimensional synthesis of the four-bar linkage, the desired coupler curve response is described by any number of precision point elements and trajectory elements, where each element is specified with an allowable error. A design description which accounts for bounded uncertainties is termed an appropriate design. An appropriate synthesis method is developed to synthesize the entire set of appropriate design solutions corresponding to the desired response. This method is able to completely explore the continuous design space and each synthesized appropriate design guarantees that the resulting four-bar linkage has a corresponding coupler point which lies inside each precision point response element, and a corresponding set of continuous coupler points which remain inside the trajectory response elements from start to finish.

show abstract

Section: Introduction To Linkage Synthesismentioning

confidence: 99%

Appropriate synthesis of the four-bar linkage

Pickard

Carretero

Merlet

2020

Mechanism and Machine Theory

View full text Add to dashboard Cite

show abstract

“…A machine is a combination of rigid bodies, with various components connected moving with definite relative motion, applying force from the source of power in order to overcome higher resistance relatively to the applied force. A mechanism, according to [1][2][3][4] can be defined as a combination structural body, interconnected moving with definite relative motions in conjunction with one another [5,6].…”

Section: Introductionmentioning

confidence: 99%

Development and Application of a Computer Program for Four-Bar Linkage and Slider-Crank Mechanisms

Adesola¹,

Olatunde²,

Dare³

et al. 2020

JESR

View full text Add to dashboard Cite

Complex mathematical problems have been solved with the aid of software application to obtain reliable results. The positional kinematic analysis of a slider crank mechanism involves computation of the motion parameters: linear displacement, velocity and acceleration of the slider; and angular velocity and angular acceleration of the connecting rod for every 300 variation of the crank angle. This study aimed to develop a customized software which can be used to efficiently analyse a given design of a four-bar and a slider-crank mechanisms. A program was written using VB (Visual Basic) programming language for the equations of angular velocities and angular acceleration of the coupler and follower for the four-bar linkage and the linear velocity and acceleration of the piston for the slider crank mechanism. The program was tested with different parameters for the mechanisms and the solutions compared with the results from manual calculations. The findings revealed that there were no differences (p ≤ 0.05) between the results using the program and manual calculations, which imply the accuracy of the program. It can be concluded that the program could be used to solve problems of four- bar linkage and slider-crank mechanisms.

show abstract

“…These are data points are relative to the hip joint. A B-spline [26] was used to repre- Figure 6 shows a plot of these 60 data points and Figure 7 plots the 7 points required for the homotopy solution.…”

Section: Six-bar Linkage Mechanism For the Ankle Trajectorymentioning

confidence: 99%

An Adjustable Single Degree-of-Freedom System to Guide Natural Walking Movement for Rehabilitation

Tsuge

McCarthy

2016

Journal of Medical Devices

View full text Add to dashboard Cite

This paper presents a linkage system designed to guide a natural ankle trajectory with the corresponding foot orientation. A six-bar linkage was designed to coordinate the joint angles of an RR chain (R denotes a revolute or hinged joint) that models the leg to achieve the desired ankle trajectory. The design is shown to be adjustable to meet a range of trajectories obtained in an individual's normal gait. Control of the foot position is obtained using a cam-driven parallel chain that has the same input as the six-bar linkage. The result is a one degree of freedom system that guides a natural walking movement of the leg and foot. A solid model of the complete device is presented.

show abstract

A Computer-Aided Design Technique for Semi-Automated Infinite Point Coupler Curve Synthesis of Four-Bar Linkages

Cited by 35 publications

References 1 publication

Appropriate synthesis of the four-bar linkage

Appropriate synthesis of the four-bar linkage

Development and Application of a Computer Program for Four-Bar Linkage and Slider-Crank Mechanisms

An Adjustable Single Degree-of-Freedom System to Guide Natural Walking Movement for Rehabilitation

Contact Info

Product

Resources

About