Stereo Vision Combined With Laser Profiling for Mapping of Pipeline Internal Defects

Underground potable water pipes are essential infrastructure assets for any country. A significant proportion of those assets are deteriorating due to pipe corrosion which results in premature failure of pipes causing enormous disruptions to the public and loss to the economy. To address such advers...

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Veröffentlicht in:	IEEE sensors journal 2021-05, Vol.21 (10), p.11926-11934
Hauptverfasser:	Gunatilake, Amal, Piyathilaka, Lasitha, Tran, Antony, Vishwanathan, Vinoth Kumar, Thiyagarajan, Karthick, Kodagoda, Sarath
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Sprache:	eng
Schlagworte:	3D laser profiling Buried pipes Calibration Cameras Defects defects detection Drinking water Image color analysis Infrared lasers Linings mobile robot pipeline inspection RGB depth mapping Robot sensors Robot vision systems robotic sensing robotic vision Robots Sensors Service life stereo camera vision Three-dimensional displays Water pipelines Water pipes Water utilities
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creator	Gunatilake, Amal Piyathilaka, Lasitha Tran, Antony Vishwanathan, Vinoth Kumar Thiyagarajan, Karthick Kodagoda, Sarath
description	Underground potable water pipes are essential infrastructure assets for any country. A significant proportion of those assets are deteriorating due to pipe corrosion which results in premature failure of pipes causing enormous disruptions to the public and loss to the economy. To address such adverse effects, the water utilities in Australia exploit advanced pipelining technologies with a motive of extending the service life of their pipe assets. However, the linings are prone to defects due to improper liner application and unfavorable environmental conditions during the liner curing phase. To monitor the imperfections of the pipe linings, in this article, we propose a mobile robotic sensing system that can scan, detect, locate and measure pipeline internal defects by generating three-dimensional RGB-Depth maps using stereo camera vision combined with infrared laser profiling unit. The system does not require complex calibration procedures and it utilizes orientation correction to provide accurate real-time RGB-D maps. The defects are identified and color mapped for easier visualization. The robotic sensing system was extensively tested in laboratory conditions followed by field deployments in buried water pipes in Sydney, Australia. The experimental results show that the RGB-D maps were generated with millimeter (mm) level accuracy with demonstrated liner defect quantification.
doi_str_mv	10.1109/JSEN.2020.3040396
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A significant proportion of those assets are deteriorating due to pipe corrosion which results in premature failure of pipes causing enormous disruptions to the public and loss to the economy. To address such adverse effects, the water utilities in Australia exploit advanced pipelining technologies with a motive of extending the service life of their pipe assets. However, the linings are prone to defects due to improper liner application and unfavorable environmental conditions during the liner curing phase. To monitor the imperfections of the pipe linings, in this article, we propose a mobile robotic sensing system that can scan, detect, locate and measure pipeline internal defects by generating three-dimensional RGB-Depth maps using stereo camera vision combined with infrared laser profiling unit. The system does not require complex calibration procedures and it utilizes orientation correction to provide accurate real-time RGB-D maps. The defects are identified and color mapped for easier visualization. The robotic sensing system was extensively tested in laboratory conditions followed by field deployments in buried water pipes in Sydney, Australia. 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subjects	3D laser profiling Buried pipes Calibration Cameras Defects defects detection Drinking water Image color analysis Infrared lasers Linings mobile robot pipeline inspection RGB depth mapping Robot sensors Robot vision systems robotic sensing robotic vision Robots Sensors Service life stereo camera vision Three-dimensional displays Water pipelines Water pipes Water utilities
title	Stereo Vision Combined With Laser Profiling for Mapping of Pipeline Internal Defects
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