High-Precision Surface Inspection: Uncertainty Evaluation within an Accuracy Range of 15μm with Triangulation-based Laser Line Scanners
High-Precision Surface Inspection: Uncertainty Evaluation within an Accuracy Range of 15μm with Triangulation-based Laser Line Scanners
Dokument öffnen (2.8MB)Datum der Veröffentlichung
02.01.2014Verlag / herausgebende Einrichtung
de GruyterVerlagsort
BerlinMetadaten
Zur Langanzeige
Zitierbarer Link (Handle URI) 
https://hdl.handle.net/20.500.11811/8359
Inhalt
Triangulation-based range sensors, e.g. laser line scanners, are used for high-precision geometrical acquisition of free-form surfaces, for reverse engineering tasks or quality management. In contrast to classical tactile measuring devices, these scanners generate a great amount of 3D-points in a short period of time and enable the inspection of soft materials. However, for accurate measurements, a number of aspects have to be considered to minimize measurement uncertainties. This study outlines possible sources of uncertainties during the measurement process regarding the scanner warm-up, the impact of laser power and exposure time as well as scanner’s reaction to areas of discontinuity, e.g. edges. All experiments were performed using a fixed scanner position to avoid effects resulting from imaging geometry. The results show a significant dependence of measurement accuracy on the correct adaption of exposure time as a function of surface reflectivity and laser power. Additionally, it is illustrated that surface structure as well as edges can cause significant systematic uncertainties.
Schlagwörter
high precision laser scanning, laser line scanner, laser triangulation, measurement uncertainties
Klassifikation (DDC)
526.1 GeodäsieErschienen in
Journal of Applied Geodesy, 8, 2, S. 109-118Erstpublikation
https://doi.org/10.1515/jag-2014-0001Dupuis, Jan; Kuhlmann, Heiner: High-Precision Surface Inspection: Uncertainty Evaluation within an Accuracy Range of 15μm with Triangulation-based Laser Line Scanners. In: Journal of Applied Geodesy. 8, 2, 109-118.
Online-Ausgabe in bonndoc: https://hdl.handle.net/20.500.11811/8359
Online-Ausgabe in bonndoc: https://hdl.handle.net/20.500.11811/8359
@article{handle:20.500.11811/8359,
author = {{Jan Dupuis} and {Heiner Kuhlmann}},
title = {High-Precision Surface Inspection: Uncertainty Evaluation within an Accuracy Range of 15μm with Triangulation-based Laser Line Scanners},
publisher = {de Gruyter},
year = 2014,
month = jan,
journal = {Journal of Applied Geodesy},
volume = 8,
number = 2,
pages = 109--118,
note = {Triangulation-based range sensors, e.g. laser line scanners, are used for high-precision geometrical acquisition of free-form surfaces, for reverse engineering tasks or quality management. In contrast to classical tactile measuring devices, these scanners generate a great amount of 3D-points in a short period of time and enable the inspection of soft materials. However, for accurate measurements, a number of aspects have to be considered to minimize measurement uncertainties. This study outlines possible sources of uncertainties during the measurement process regarding the scanner warm-up, the impact of laser power and exposure time as well as scanner’s reaction to areas of discontinuity, e.g. edges. All experiments were performed using a fixed scanner position to avoid effects resulting from imaging geometry. The results show a significant dependence of measurement accuracy on the correct adaption of exposure time as a function of surface reflectivity and laser power. Additionally, it is illustrated that surface structure as well as edges can cause significant systematic uncertainties.},
url = {https://hdl.handle.net/20.500.11811/8359}
}
author = {{Jan Dupuis} and {Heiner Kuhlmann}},
title = {High-Precision Surface Inspection: Uncertainty Evaluation within an Accuracy Range of 15μm with Triangulation-based Laser Line Scanners},
publisher = {de Gruyter},
year = 2014,
month = jan,
journal = {Journal of Applied Geodesy},
volume = 8,
number = 2,
pages = 109--118,
note = {Triangulation-based range sensors, e.g. laser line scanners, are used for high-precision geometrical acquisition of free-form surfaces, for reverse engineering tasks or quality management. In contrast to classical tactile measuring devices, these scanners generate a great amount of 3D-points in a short period of time and enable the inspection of soft materials. However, for accurate measurements, a number of aspects have to be considered to minimize measurement uncertainties. This study outlines possible sources of uncertainties during the measurement process regarding the scanner warm-up, the impact of laser power and exposure time as well as scanner’s reaction to areas of discontinuity, e.g. edges. All experiments were performed using a fixed scanner position to avoid effects resulting from imaging geometry. The results show a significant dependence of measurement accuracy on the correct adaption of exposure time as a function of surface reflectivity and laser power. Additionally, it is illustrated that surface structure as well as edges can cause significant systematic uncertainties.},
url = {https://hdl.handle.net/20.500.11811/8359}
}
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