Oceans 2009-Europe 2009
DOI: 10.1109/oceanse.2009.5278231
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Visual mapping of internal pipe walls using sparse features for application on board Autonomous Underwater Vehicles

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Cited by 5 publications
(6 citation statements)
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“…Piciarelli et al [5] directly obtained undistorted flattened images of a pipeline internal surface using the mapping relationship between the right angle and cylindrical and spherical coordinate systems after a pipeline robot captured panoramic images of the pipeline internal surface. Bodenmann et al [6] first mapped the captured panoramic images of the pipeline internal surface to a pipeline 3D model and thereafter drew flattened images of the pipeline based on this 3D model. But, these methods are not suitable for flattening the external surfaces of pipelines captured by an inspection UAV.…”
Section: Geometric Distortion Correction Techniquementioning
confidence: 99%
See 1 more Smart Citation
“…Piciarelli et al [5] directly obtained undistorted flattened images of a pipeline internal surface using the mapping relationship between the right angle and cylindrical and spherical coordinate systems after a pipeline robot captured panoramic images of the pipeline internal surface. Bodenmann et al [6] first mapped the captured panoramic images of the pipeline internal surface to a pipeline 3D model and thereafter drew flattened images of the pipeline based on this 3D model. But, these methods are not suitable for flattening the external surfaces of pipelines captured by an inspection UAV.…”
Section: Geometric Distortion Correction Techniquementioning
confidence: 99%
“…However, the method relies on parallelism and equal line spacing information of printed text on the page and is therefore not suitable for pipeline surface image flattening tasks that lack text information. Currently, there are relatively few studies on geometric distortion correction (GDC) algorithms for pipeline surface images; most studies have focused on GDC tasks for internal pipeline surface images [4][5][6][7]. These methods first require a crawling robot to obtain a panoramic image of the internal pipeline surface; therefore, they are not applicable to GDC tasks for pipeline external surface images.…”
Section: Introductionmentioning
confidence: 99%
“…6) Underwater vehicles: Submersible robots have been developed to inspect underwater structures. Several prototypes have been designed to inspect oil storage tanks (Abdulla, et al 2010) and pipelines (Conte, et al 1996, Bodenmann, et al 2009.…”
Section: Robotic Inspection For Civil Infrastructurementioning
confidence: 99%
“…2. The fish eye lens of the camera has a field of view of 180 degrees, which permits the camera to view the pipe wall interior which can be used for visual mapping and inspection of its interior [10]. This also maximizes the operating range of the sensor as it allows the camera to see the full laser circle without clipping even during displaced, pitched and yawed conditions.…”
Section: Sensor Descriptionmentioning
confidence: 99%