by Julio Molleda, Rubén Usamentiaga, Francisco González Bulnes, Juan Carlos Granda and Laura Ema
Abstract:
Quality evaluation of rolling processes in the metal industry involves an inspection of the shape of the outgoing products in real time during manufacturing. Shape measurement systems are usually based on 3-D reconstructions of the surface of rolled products. As surface properties are crucial, these systems favor contactless techniques. Using 3-D measurements of the surface of rolled products, several geometric properties can be analyzed. In this paper, we analyze how uncertainty is propagated in a contactless shape measurement system designed and developed by the authors and presented in previous published works. This measurement system is based on active triangulation, and it is able to provide inline width and flatness measurements of long, flat-rolled products in harsh industrial environments. The camera model used to calibrate the vision system is described, and it is used to estimate the uncertainty of the reprojected 3-D points on the scene. The system uses the reprojected 3-D points, and the speed of the product movement in the production line to reconstruct its surface. Thus, the uncertainty of the speed is also estimated. Finally, the propagation of both the uncertainty of the 3-D reprojection, and the uncertainty of the speed into the final width and flatness measurements is analyzed. This paper comprises a detailed uncertainty propagation analysis in 3-D shape measurements computed indirectly through functional relationships. 2012 IEEE.
Reference:
Uncertainty propagation analysis in 3-D shape measurement using laser range finding (Julio Molleda, Rubén Usamentiaga, Francisco González Bulnes, Juan Carlos Granda and Laura Ema), In IEEE Transactions on Instrumentation and Measurement, volume 61, 2012.
Bibtex Entry:
@article{molleda2012tim,
author = {Julio Molleda and Rubén Usamentiaga and Francisco González Bulnes and Juan Carlos Granda and Laura Ema},
title = {Uncertainty propagation analysis in 3-D shape measurement using laser range finding},
volume = {61},
number = {5},
pages = {1160--1172},
issn = {0018-9456},
abstract = {Quality evaluation of rolling processes in the metal industry involves an inspection of the shape of the outgoing products in real time during manufacturing. Shape measurement systems are usually based on 3-D reconstructions of the surface of rolled products. As surface properties are crucial, these systems favor contactless techniques. Using 3-D measurements of the surface of rolled products, several geometric properties can be analyzed. In this paper, we analyze how uncertainty is propagated in a contactless shape measurement system designed and developed by the authors and presented in previous published works. This measurement system is based on active triangulation, and it is able to provide inline width and flatness measurements of long, flat-rolled products in harsh industrial environments. The camera model used to calibrate the vision system is described, and it is used to estimate the uncertainty of the reprojected 3-D points on the scene. The system uses the reprojected 3-D points, and the speed of the product movement in the production line to reconstruct its surface. Thus, the uncertainty of the speed is also estimated. Finally, the propagation of both the uncertainty of the 3-D reprojection, and the uncertainty of the speed into the final width and flatness measurements is analyzed. This paper comprises a detailed uncertainty propagation analysis in 3-D shape measurements computed indirectly through functional relationships. 2012 {IEEE}.},
author+an = {4=highlight},
date = {2012},
year = {2012},
doi = {10.1109/TIM.2011.2180964},
journal = {{IEEE} Transactions on Instrumentation and Measurement},
keywords = {3-D measurement, 3D reconstruction, 3-d shape measurement, Active triangulation, Calibration, Camera model, Contact less, Contactless technique, error analysis, flatness measurement, Flat-rolled products, Functional relationship, Geometric properties, Industrial environments, In-line, Laser range-finding, measurement by laser beam, Measurements, Measurement system, measurement uncertainty, Metal industries, Production line, Quality control, Quality evaluation, Real time, Re-projection, Rolled products, Rolling process, shape measurement, Shape measurements, Shape measurement systems, Surface properties, System use, Three dimensional, Uncertainty analysis, Uncertainty propagation, Vision systems, width measurement, Width measurements},
shortjournal = {{IEEE} Trans. Instrum. Meas.},
url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-84859804430&doi=10.1109%2fTIM.2011.2180964&partnerID=40&md5=47d7fd2ab7430bbf825104431d956e26},
jcr = {1.357 -- Q2 [2012]},
}