Proposed algorithm.

Proposed algorithm.

<div><p>The kinematic reliability analysis of robotic manipulators is crucial due to uncertainties such as joint variations, manufacturing tolerances, and external disturbances. Traditional methods often rely on analytical techniques that struggle with nonlinear performance functions and...

وصف كامل

محفوظ في:
التفاصيل البيبلوغرافية
المؤلف الرئيسي: Keenjhar Ayoob (22339616) (author)
مؤلفون آخرون: Hassan Elahi (20291140) (author), Tayyab Zafar (22339619) (author), Amir Hamza (12587773) (author), Zhonglai Wang (14047917) (author)
منشور في: 2025
الموضوعات:
Biotechnology
Space Science
Environmental Sciences not elsewhere classified
Biological Sciences not elsewhere classified
Mathematical Sciences not elsewhere classified
Information Systems not elsewhere classified
monte carlo simulation
dof industrial robots
statistical sampling techniques
nonlinear performance functions
greater operational efficiency
kinematic reliability analysis
dependent reliability analysis
robotic manipulator kinematics
maintaining prediction accuracy
based method reduces
novel surrogate model
manipulator performance
based reliability
surrogate modeling
robotic manipulators
proposed method
enhancing efficiency
analytical techniques
analyze reliability
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two 6
specified tolerances
proposed kriging
practical applications
paper proposes
methodology begins
mcs ),
joint variations
function evaluations
external disturbances
efficient evaluation
effector trajectories
effectively capturing
crucial due
considering end
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الوصف
الملخص:<div><p>The kinematic reliability analysis of robotic manipulators is crucial due to uncertainties such as joint variations, manufacturing tolerances, and external disturbances. Traditional methods often rely on analytical techniques that struggle with nonlinear performance functions and fail to account for trajectory-based reliability. To overcome these limitations, this paper proposes a novel surrogate model-based approach using Kriging to estimate the reliability of robotic manipulator kinematics while considering end-effector trajectories. The methodology begins with building an initial Kriging surrogate model to analyze reliability, effectively capturing how input uncertainties influence trajectory accuracy. This model is then refined through statistical sampling techniques, ensuring an efficient evaluation of manipulator performance against specified tolerances. The approach reduces computational complexity while maintaining prediction accuracy. Compared to Monte Carlo Simulation (MCS), the proposed Kriging-based method reduces the number of function evaluations by over 98%, achieving comparable reliability predictions with significantly fewer function calls, and enhancing efficiency in kinematic reliability analysis. The proposed method is validated on two 6-DOF industrial robots, including the UR5, demonstrating improved computational efficiency and accuracy. This work has practical applications in manufacturing and healthcare, where enhanced kinematic reliability leads to greater operational efficiency and safety.</p></div>

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