Performance Evaluation of a Sensor Concept for Solving the Direct Kinematics Problem of General Planar 3-RPR Parallel Mechanisms by Using Solely the Linear Actuators’ Orientations

Schulz, Stefan

doi:10.3390/robotics8030072

Cited by 3 publications

(3 citation statements)

References 71 publications

(124 reference statements)

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“…However, this will easily get quite complex, and still, the angle γ will always be more noisy and less accurate than the other angles. (4) As discovered in [66,80], the IMU's variances depend on the linear actuator's orientation and therefore, the position and orientation errors variances depend on them too.…”

Section: Discussionmentioning

confidence: 98%

On Using Inertial Measurement Units for Solving the Direct Kinematics Problem of Parallel Mechanisms

Schulz

2019

Robotics

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In this paper, we investigate the accuracy and the computational efficiency of an IMU-based approach for solving the direct kinematics problem of parallel mechanisms with length-variable linear actuators under dynamic conditions. By avoiding to measure the linear actuators’ lengths and by using orientations instead, a comprehensive, low-cost sensor structure can be obtained that provides a unique solution for the direct kinematics problem. As a representative example, we apply our approach to the planar 3-RPR parallel mechanism, where P denotes active prismatic joints and R denotes passive revolute joints, and investigate the achievable accuracy and robustness on a specially designed experimental device. In this context, we also investigate the effect of sensor fusion on the achievable accuracy and compare our results with those obtained from linear actuators’ lengths when the Newton-Raphson algorithm is used to compute the manipulator platform’s pose iteratively. Finally, we discuss the applicability of inertial measurement units (IMUs) for solving the direct kinematics problem of parallel mechanisms.

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Section: Discussionmentioning

confidence: 98%

On Using Inertial Measurement Units for Solving the Direct Kinematics Problem of Parallel Mechanisms

Schulz

2019

Robotics

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“…As mentioned above, the parallel mechanism's pose cannot be calculated unambiguously and is usually computed with the Newton-Raphson algorithm and a pose estimate. The initial pose estimate and the accuracy of the kinematic model itself directly influence the accuracy of the determined pose [5,24]. If, for example, the inverse kinematics equations are not 100% correct, the pose obtained from the active joints' coordinates does not match with the real pose.…”

Section: Introductionmentioning

confidence: 99%

High-Precision Absolute Pose Sensing for Parallel Mechanisms

Schempp

Schulz

2022

Sensors

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A parallel mechanism’s pose is usually obtained indirectly from the active joints’ coordinates by solving the direct kinematics problem. Its accuracy mainly depends on the accuracy of the measured active joints’ coordinates, the tolerances in the active and passive joints, possible backlash, axes misalignment, limb deformations due to stress or temperature, the initial pose estimate that is used for the numerical method, and the accuracy of the kinematic model itself. Backlash and temperature deformations in the active joints especially hinder high-precision applications as they usually cannot be observed. By implementing a camera module on the base platform and an array of fiducial tags on the moveable manipulator platform of a parallel mechanism, a highly accurate, direct, and absolute pose measurement system can be obtained that can overcome those limitations. In this paper, such a measurement system is proposed, designed, and its accuracy is investigated on a state-of-the-art H-811.I2 6-axis miniature hexapod by Physik Instrumente (PI) GmbH & Co. KG.

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“…Recently, there has been a significant increase in construction of parallel robots [ 1 , 2 , 3 , 4 , 5 , 6 , 7 , 8 ]. Manipulators and parallel robots are more widely applied in industry.…”

Section: Introductionmentioning

confidence: 99%

Using a Development Platform with an STM32 Processor to Prototype an Inexpensive 4-DoF Delta Parallel Robot

Łaski¹,

Smykowski²

2021

Sensors

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This article presents a construction prototype of a delta 4-DoF (Degree of Freedom) parallel robot. The structure of kinematic chain was described and the problem of inverse kinematic was formulated and solved. The author also proposed a concept of a control system. The dynamics of the control object were specified, a decision upon the controller and its settings was made, as well as simulation control studies of manipulator drive were conducted. The article contains a description of prepared applications and procedures as well as the research results of the manipulator.

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Performance Evaluation of a Sensor Concept for Solving the Direct Kinematics Problem of General Planar 3-RPR Parallel Mechanisms by Using Solely the Linear Actuators’ Orientations

Cited by 3 publications

References 71 publications

On Using Inertial Measurement Units for Solving the Direct Kinematics Problem of Parallel Mechanisms

On Using Inertial Measurement Units for Solving the Direct Kinematics Problem of Parallel Mechanisms

High-Precision Absolute Pose Sensing for Parallel Mechanisms

Using a Development Platform with an STM32 Processor to Prototype an Inexpensive 4-DoF Delta Parallel Robot

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