Metrological Characterization of a Vision-Based System for Relative Pose Measurements with Fiducial Marker Mapping for Spacecrafts
An improved approach for the measurement of the relative pose between a target and a chaser spacecraft is presented. The selected method is based on a single camera, which can be mounted on the chaser, and a plurality of fiducial markers, which can be mounted on the external surface of the target. T...
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MDPI AG
2018-08-01
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| Series: | Robotics |
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| Online Access: | http://www.mdpi.com/2218-6581/7/3/43 |
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doaj-3795d608bc5346078c66dea40a8ce6042020-11-25T02:26:32ZengMDPI AGRobotics2218-65812018-08-01734310.3390/robotics7030043robotics7030043Metrological Characterization of a Vision-Based System for Relative Pose Measurements with Fiducial Marker Mapping for SpacecraftsMarco Pertile0Sebastiano Chiodini1Riccardo Giubilato2Mattia Mazzucato3Andrea Valmorbida4Alberto Fornaser5Stefano Debei6Enrico C. Lorenzini7CISAS “G. Colombo”, University of Padova, 35131 Padova, ItalyCISAS “G. Colombo”, University of Padova, 35131 Padova, ItalyCISAS “G. Colombo”, University of Padova, 35131 Padova, ItalyCISAS “G. Colombo”, University of Padova, 35131 Padova, ItalyIndustrial Engineering Department, University of Padova, 35131 Padova, ItalyIndustrial Engineering Department, University of Trento, 38123 Povo (TN), ItalyCISAS “G. Colombo”, University of Padova, 35131 Padova, ItalyCISAS “G. Colombo”, University of Padova, 35131 Padova, ItalyAn improved approach for the measurement of the relative pose between a target and a chaser spacecraft is presented. The selected method is based on a single camera, which can be mounted on the chaser, and a plurality of fiducial markers, which can be mounted on the external surface of the target. The measurement procedure comprises of a closed-form solution of the Perspective from n Points (PnP) problem, a RANdom SAmple Consensus (RANSAC) procedure, a non-linear local optimization and a global Bundle Adjustment refinement of the marker map and relative poses. A metrological characterization of the measurement system is performed using an experimental set-up that can impose rotations combined with a linear translation and can measure them. The rotation and position measurement errors are calculated with reference instrumentations and their uncertainties are evaluated by the Monte Carlo method. The experimental laboratory tests highlight the significant improvements provided by the Bundle Adjustment refinement. Moreover, a set of possible influencing physical parameters are defined and their correlations with the rotation and position errors and uncertainties are analyzed. Using both numerical quantitative correlation coefficients and qualitative graphical representations, the most significant parameters for the final measurement errors and uncertainties are determined. The obtained results give clear indications and advice for the design of future measurement systems and for the selection of the marker positioning on a satellite surface.http://www.mdpi.com/2218-6581/7/3/43vision systempose measurementuncertainty evaluationmetrological calibration |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Marco Pertile Sebastiano Chiodini Riccardo Giubilato Mattia Mazzucato Andrea Valmorbida Alberto Fornaser Stefano Debei Enrico C. Lorenzini |
| spellingShingle |
Marco Pertile Sebastiano Chiodini Riccardo Giubilato Mattia Mazzucato Andrea Valmorbida Alberto Fornaser Stefano Debei Enrico C. Lorenzini Metrological Characterization of a Vision-Based System for Relative Pose Measurements with Fiducial Marker Mapping for Spacecrafts Robotics vision system pose measurement uncertainty evaluation metrological calibration |
| author_facet |
Marco Pertile Sebastiano Chiodini Riccardo Giubilato Mattia Mazzucato Andrea Valmorbida Alberto Fornaser Stefano Debei Enrico C. Lorenzini |
| author_sort |
Marco Pertile |
| title |
Metrological Characterization of a Vision-Based System for Relative Pose Measurements with Fiducial Marker Mapping for Spacecrafts |
| title_short |
Metrological Characterization of a Vision-Based System for Relative Pose Measurements with Fiducial Marker Mapping for Spacecrafts |
| title_full |
Metrological Characterization of a Vision-Based System for Relative Pose Measurements with Fiducial Marker Mapping for Spacecrafts |
| title_fullStr |
Metrological Characterization of a Vision-Based System for Relative Pose Measurements with Fiducial Marker Mapping for Spacecrafts |
| title_full_unstemmed |
Metrological Characterization of a Vision-Based System for Relative Pose Measurements with Fiducial Marker Mapping for Spacecrafts |
| title_sort |
metrological characterization of a vision-based system for relative pose measurements with fiducial marker mapping for spacecrafts |
| publisher |
MDPI AG |
| series |
Robotics |
| issn |
2218-6581 |
| publishDate |
2018-08-01 |
| description |
An improved approach for the measurement of the relative pose between a target and a chaser spacecraft is presented. The selected method is based on a single camera, which can be mounted on the chaser, and a plurality of fiducial markers, which can be mounted on the external surface of the target. The measurement procedure comprises of a closed-form solution of the Perspective from n Points (PnP) problem, a RANdom SAmple Consensus (RANSAC) procedure, a non-linear local optimization and a global Bundle Adjustment refinement of the marker map and relative poses. A metrological characterization of the measurement system is performed using an experimental set-up that can impose rotations combined with a linear translation and can measure them. The rotation and position measurement errors are calculated with reference instrumentations and their uncertainties are evaluated by the Monte Carlo method. The experimental laboratory tests highlight the significant improvements provided by the Bundle Adjustment refinement. Moreover, a set of possible influencing physical parameters are defined and their correlations with the rotation and position errors and uncertainties are analyzed. Using both numerical quantitative correlation coefficients and qualitative graphical representations, the most significant parameters for the final measurement errors and uncertainties are determined. The obtained results give clear indications and advice for the design of future measurement systems and for the selection of the marker positioning on a satellite surface. |
| topic |
vision system pose measurement uncertainty evaluation metrological calibration |
| url |
http://www.mdpi.com/2218-6581/7/3/43 |
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