Vibration Measurement of Robot End-Effector Based on Improved Optical Flow in Stereo Vision

In the high-precision operation of industrial robotic arms, vibrations can reduce the accuracy of the end-effector trajectory. To achieve vibration suppression, it is essential to accurately measure the vibration characteristics, which makes high-precision vibration measurement particularly importan...

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Bibliographic Details
Published inInternational Conference on Automation, Control and Robotics Engineering (Online) pp. 23 - 28
Main Authors Wang, Chao, Fang, Lijin, Zhao, Qiankun, Qian, Yian
Format Conference Proceeding
LanguageEnglish
Published IEEE 16.07.2025
Subjects
Accuracy
End effectors
Frequency measurement
high-precision measurements
industrial robotic arms
Kalman filtering
Kalman filters
Optical flow
Robot sensing systems
Service robots
sub-pixel corner detection
three-dimensional vibration measurement
Trajectory
Vibration measurement
Vibrations
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Summary:In the high-precision operation of industrial robotic arms, vibrations can reduce the accuracy of the end-effector trajectory. To achieve vibration suppression, it is essential to accurately measure the vibration characteristics, which makes high-precision vibration measurement particularly important. Traditional contact sensors suffer from mass loading effects and complex installation, whereas computer vision-based approaches have gained significant attention in research due to their non-contact nature. We present a binocular vision-based approach for measuring the three-dimensional vibration of the robotic arm's end effector. The technique utilizes sub-pixel corner detection technology, a video motion magnification algorithm, and an improved optical flow tracking algorithm that integrates Kalman filtering and the Hungarian algorithm. Through experimental analysis of robotic arm end-effector vibrations, the visual algorithm's output was validated against contact sensor data, confirming its efficacy in detecting microvibrations. The experimental results demonstrate that this method can achieve a high-precision measurement of minute vibrations, with a measurement accuracy of 0.01 mm. Additionally, experimental results under different load conditions indicate that the vibration frequencies of the three axes of the robot arm's end effector are concentrated around a specific frequency, further demonstrating that the end vibration frequency of the robot arm is not directly related to the magnitude of the applied load.
ISSN:2997-6278
DOI:10.1109/CACRE66141.2025.11119600