Terrestrial laser scanner self-calibration: Correlation sources and their mitigation |
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| Authors: | Derek D Lichti |
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| Institution: | 1. Department of Architecture, Selçuk University, Faculty of Architecture, 421030 Campus, Konya, Turkey;2. Department of Civil and Environmental Engineering, University of Florence, via di S. Marta 3, I-50139 Florence, Italy;3. GeCo, Geomatics for Conservation & Communication of Cultural Heritage Laboratory, Italy;1. Department of Surveying Sciences and Geomatics, Universiti Teknologi MARA, Malaysia;2. Department of Geomatic Engineering, University of Calgary, Canada;3. Department of Geomatic Engineering, University of Southern Queensland, Australia;4. Department of Geomatic Engineering, Universiti Teknologi Malaysia, Malaysia;1. Technische Universität Berlin, 10623 Berlin, Germany;2. Zoller + Fröhlich GmbH, 88239 Wangen im Allgäu, Germany |
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| Abstract: | Instrument calibration is recognised as an important process to assure the quality of data captured with a terrestrial laser scanner. While the self-calibration approach can provide optimal estimates of systematic error parameters without the need for specialised equipment or facilities, its success is somewhat hindered by high correlations between model variables. This paper presents the findings of a detailed study into the sources of correlation in terrestrial laser scanner self-calibration for a basic additional parameter set. Several pertinent outcomes, resulting from experiments conducted with simulated data, and 12 real calibration datasets captured with a Faro 880 terrestrial laser scanner, are presented. First, it is demonstrated that panoramic-type scanner self-calibration from only two instrument locations is possible so long as the scans have orthogonal orientation in the horizontal plane. Second, the importance of including scanner tilt angle observations in the adjustment for parameter de-correlation is demonstrated. Third, a new network measure featuring an asymmetric distribution of object points that does not rely upon a priori observation of the instrument position is proposed. It is shown to be an effective means to reduce the correlation between the rangefinder offset and the scanner position parameters. Fourth, the roles of several other influencing variables on parameter correlation are revealed. The paper concludes with a set of recommended design measures to reduce parameter correlation in terrestrial laser scanner self-calibration. |
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