Synthesis of Stephenson III Timed Curve Generators Using a Probabilistic Continuation Method

Baskar, Aravind; Plecnik, Mark

doi:10.1115/detc2019-98136

Cited by 3 publications

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“…Methods for kinematic synthesis for four-bar linkages were also found, as references [66][67][68] without constraints, and [69] who used constraints on lengths of the type higher than or less than. Another method for kinematic synthesis with path generation for a six-bar linkage Stephenson III was referred to in reference [70] without any type of constraints. Finally, there are general purpose synthesis methods for planar linkages as reference [71] where no constraint applies; or reference [72], due to the authors, which is the only one using geometric constraints of fixed length.…”

Section: Scope and Contribution Of This Studymentioning

confidence: 99%

Optimum dimensional synthesis of planar mechanisms with geometric constraints

et al. 2020

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The deformed energy method has shown to be a good option for dimensional synthesis of mechanisms. In this paper the introduction of some new features to such approach is proposed. First, constraints fixing dimensions of certain links are introduced in the error function of the synthesis problem. Second, requirements on distances between determinate nodes are included in the error function for the analysis of the deformed position problem. Both the overall synthesis error function and the inner analysis error function are optimized using a Sequential Quadratic Problem (SQP) approach. This also reduces the probability of branch or circuit defects. In the case of the inner function analytical derivatives are used, while in the synthesis optimization approximate derivatives have been introduced. Furthermore, constraints are analyzed under two formulations, the Euclidean distance and an alternative approach that uses the previous raised to the power of two. The latter approach is often used in kinematics, and simplifies the computation of derivatives. Some examples are provided to show the convergence order of the error function and the fulfilment of the constraints in both formulations studied under different topological situations or achieved energy levels.

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Section: Scope and Contribution Of This Studymentioning

confidence: 99%

Optimum dimensional synthesis of planar mechanisms with geometric constraints

et al. 2020

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Higher Order Path Synthesis of Four-Bar Mechanisms Using Polynomial Continuation

Baskar

Plecnik

2020

Advances in Robot Kinematics 2020

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Synthesis of Six-Bar Timed Curve Generators of Stephenson-Type Using Random Monodromy Loops

Baskar

Plecnik

2020

Journal of Mechanisms and Robotics

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Synthesis of rigid-body mechanisms has traditionally been motivated by the design for kinematic requirements such as rigid-body motions, paths or functions. A blend of the latter two leads to timed curve synthesis, the goal of which is to produce a path coordinated to the input of a joint variable. This approach has utility for altering the transmission of forces and velocities from an input joint onto an output point path. The design of timed curve generators can be accomplished by setting up a square system of algebraic equations and obtaining all isolated solutions. For a four-bar linkage, obtaining these solutions is routine. The situation becomes much more complicated for the six-bar linkages, but the range of possible output motions is more diverse. The computation of nearly complete solution sets for these six-bar design equations has been facilitated by recent root finding techniques belonging to the field of numerical algebraic geometry. In particular, we implement a method that uses random monodromy loops. In this work, we report these solution sets to all relevant six-bars of the Stephenson topology. The computed solution sets to these generic problems represent a design library which can be used in a parameter continuation step to design linkages for different subsequent requirements.

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Synthesis of Stephenson III Timed Curve Generators Using a Probabilistic Continuation Method

Cited by 3 publications

References 0 publications

Optimum dimensional synthesis of planar mechanisms with geometric constraints

Optimum dimensional synthesis of planar mechanisms with geometric constraints

Higher Order Path Synthesis of Four-Bar Mechanisms Using Polynomial Continuation

Synthesis of Six-Bar Timed Curve Generators of Stephenson-Type Using Random Monodromy Loops

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