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Measuring unit for synchronously collecting air dose rate and measurement position
This paper describes a measuring unit for synchronously collecting the air dose rate and measurement position for efficient dosimetry surveying and data logging. The developed prototype comprises a three-dimensional light detection and ranging-based mapping part and dosimetry part, which are integra...
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Published in: | ROBOMECH journal 2024-12, Vol.11 (1), p.11-11, Article 11 |
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creator | Kawabata, Kuniaki Imabuchi, Takashi Shirasaki, Norihito Suzuki, Soichiro Ito, Rintaro Aoki, Yuto Omori, Takazumi |
description | This paper describes a measuring unit for synchronously collecting the air dose rate and measurement position for efficient dosimetry surveying and data logging. The developed prototype comprises a three-dimensional light detection and ranging-based mapping part and dosimetry part, which are integrated into a single measuring unit through an embedded computer that installs a ROS (robot operating system) framework. The unit can function as a standalone system with embedded batteries. Since it is portable, on-line data gathering in the workspace can be realized, thereby maintaining consistency between the air dose rate and measurement position. In this paper, we describe the functional requirements for the measuring unit, the prototype system configuration, and the experimental results obtained in the mockup environment and nuclear facility to discuss its performance. |
doi_str_mv | 10.1186/s40648-024-00279-x |
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subjects | Accuracy Air dose rate data Artificial Intelligence Computational Intelligence Configuration management Control and Systems Theory Data collection Data logging Dosimeters Dosimetry Engineering Gamma rays Lidar Measurement position data Measuring unit Mechatronics Methods Nuclear reactors On-line data monitoring and recording Position measurement Prototypes R&D Radiation Remote control Research & development Robotics and Automation Sensors Synchronous data collection |
title | Measuring unit for synchronously collecting air dose rate and measurement position |
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