Improved area-based deformation analysis of a radio telescope’s main reflector based on terrestrial laser scanning
Improved area-based deformation analysis of a radio telescope’s main reflector based on terrestrial laser scanning
Dokument öffnen (3.7MB)Datum der Veröffentlichung
14.03.2015Verlag / herausgebende Einrichtung
de GruyterVerlagsort
BerlinMetadaten
Zur Langanzeige
Zitierbarer Link (Handle URI) 
https://hdl.handle.net/20.500.11811/8490
Inhalt
The main reflectors of radio telescopes deform due to gravitation when changing their elevation angle. This can be analyzed by scanning the paraboloid surface with a terrestrial laser scanner and by determining focal length variations and local deformations from best-fit approximations.
For the Effelsberg radio telescope, both groups of deformations are estimated from seven points clouds measured at different elevation angles of the telescope: the focal length decreases by 22.7 mm when tilting the telescope from 90 deg to 7.5 deg elevation angle. Variable deformations of ± 2 mm are detected as well at certain areas. Furthermore, a few surface panels seem to be misaligned.
Apart from these results, the present study highlights the need for an appropriate measurement concept and for preprocessing stepswhen using laser scanners for area-based deformation analyses. Especially, data reduction, object segmentation and laser scanner calibration are discussed in more detail. An omission of these steps would significantly degrade the deformation analysis and the significance of its results. This holds for all sorts of laser scanner based analyses.
For the Effelsberg radio telescope, both groups of deformations are estimated from seven points clouds measured at different elevation angles of the telescope: the focal length decreases by 22.7 mm when tilting the telescope from 90 deg to 7.5 deg elevation angle. Variable deformations of ± 2 mm are detected as well at certain areas. Furthermore, a few surface panels seem to be misaligned.
Apart from these results, the present study highlights the need for an appropriate measurement concept and for preprocessing stepswhen using laser scanners for area-based deformation analyses. Especially, data reduction, object segmentation and laser scanner calibration are discussed in more detail. An omission of these steps would significantly degrade the deformation analysis and the significance of its results. This holds for all sorts of laser scanner based analyses.
Schlagwörter
terrestrial laser scanner, area-based deformation analysis, object segmentation, data reduction, selfcalibration
Klassifikation (DDC)
526.1 GeodäsieErschienen in
Journal of Applied Geodesy, 9, 1, S. 1-13Erstpublikation
https://doi.org/10.1515/jag-2014-0018Holst, Christoph; Nothnagel, Axel; Blome, Martin; Becker, Philip; Eichborn, Malwin; Kuhlmann, Heiner: Improved area-based deformation analysis of a radio telescope’s main reflector based on terrestrial laser scanning. In: Journal of Applied Geodesy. 9, 1, 1-13.
Online-Ausgabe in bonndoc: https://hdl.handle.net/20.500.11811/8490
Online-Ausgabe in bonndoc: https://hdl.handle.net/20.500.11811/8490
@article{handle:20.500.11811/8490,
author = {{Christoph Holst} and {Axel Nothnagel} and {Martin Blome} and {Philip Becker} and {Malwin Eichborn} and {Heiner Kuhlmann}},
title = {Improved area-based deformation analysis of a radio telescope’s main reflector based on terrestrial laser scanning},
publisher = {de Gruyter},
year = 2015,
month = mar,
journal = {Journal of Applied Geodesy},
volume = 9,
number = 1,
pages = 1--13,
note = {The main reflectors of radio telescopes deform due to gravitation when changing their elevation angle. This can be analyzed by scanning the paraboloid surface with a terrestrial laser scanner and by determining focal length variations and local deformations from best-fit approximations.
For the Effelsberg radio telescope, both groups of deformations are estimated from seven points clouds measured at different elevation angles of the telescope: the focal length decreases by 22.7 mm when tilting the telescope from 90 deg to 7.5 deg elevation angle. Variable deformations of ± 2 mm are detected as well at certain areas. Furthermore, a few surface panels seem to be misaligned.
Apart from these results, the present study highlights the need for an appropriate measurement concept and for preprocessing stepswhen using laser scanners for area-based deformation analyses. Especially, data reduction, object segmentation and laser scanner calibration are discussed in more detail. An omission of these steps would significantly degrade the deformation analysis and the significance of its results. This holds for all sorts of laser scanner based analyses.},
url = {https://hdl.handle.net/20.500.11811/8490}
}
author = {{Christoph Holst} and {Axel Nothnagel} and {Martin Blome} and {Philip Becker} and {Malwin Eichborn} and {Heiner Kuhlmann}},
title = {Improved area-based deformation analysis of a radio telescope’s main reflector based on terrestrial laser scanning},
publisher = {de Gruyter},
year = 2015,
month = mar,
journal = {Journal of Applied Geodesy},
volume = 9,
number = 1,
pages = 1--13,
note = {The main reflectors of radio telescopes deform due to gravitation when changing their elevation angle. This can be analyzed by scanning the paraboloid surface with a terrestrial laser scanner and by determining focal length variations and local deformations from best-fit approximations.
For the Effelsberg radio telescope, both groups of deformations are estimated from seven points clouds measured at different elevation angles of the telescope: the focal length decreases by 22.7 mm when tilting the telescope from 90 deg to 7.5 deg elevation angle. Variable deformations of ± 2 mm are detected as well at certain areas. Furthermore, a few surface panels seem to be misaligned.
Apart from these results, the present study highlights the need for an appropriate measurement concept and for preprocessing stepswhen using laser scanners for area-based deformation analyses. Especially, data reduction, object segmentation and laser scanner calibration are discussed in more detail. An omission of these steps would significantly degrade the deformation analysis and the significance of its results. This holds for all sorts of laser scanner based analyses.},
url = {https://hdl.handle.net/20.500.11811/8490}
}
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