Alignment of Highly Resolved Time-Dependent Experimental and Simulated Crash Test Data
Alignment of Highly Resolved Time-Dependent Experimental and Simulated Crash Test Data
View/Date of Publication
05.2022Publisher
Institut für Numerische SimulationPublisher Location
BonnMetadata
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Citable Link (Handle URI) 
https://hdl.handle.net/20.500.11811/11598
Abstract
We investigate for car and component crash tests the comparison of highly resolved experimental data with corresponding simulation data. Due to re- cent advances for optical measurement systems, one can nowadays obtain surface measurement data from a real crash experiment with high resolution in space and time. These advances call for new data processing methods that allow an alignment of this experimental data with numerical simulation results. We propose an approach based on a data representation stemming from a discrete Laplace–Beltrami operator, which allows such an alignment as well as a joint visual comparative analysis of both data sources. The method enables the identification of the best corresponding simulation among several numerical results, which allows inferring physical quantities that cannot be measured in experiments. We evaluate the procedure on synthetic and real experimental data from two different setups.
Subjects
CAE Analysis, Alignment of Experiment and Simulation, Temporal Coherence, Embedded Deformation
Classification (DDC)
510 Mathematik 518 Numerische AnalysisRelated Publications
https://ins.uni-bonn.de/publication/preprintshttps://doi.org/10.1080/13588265.2022.2131078
Part of Series
INS Preprints ; 2208Garcke, Jochen; Hahner, Sara; Iza-Teran, Rodrigo: Alignment of Highly Resolved Time-Dependent Experimental and Simulated Crash Test Data. In: INS Preprints, 2208.
Online-Ausgabe in bonndoc: https://hdl.handle.net/20.500.11811/11598
Online-Ausgabe in bonndoc: https://hdl.handle.net/20.500.11811/11598
@unpublished{handle:20.500.11811/11598,
author = {{Jochen Garcke} and {Sara Hahner} and {Rodrigo Iza-Teran}},
title = {Alignment of Highly Resolved Time-Dependent Experimental and Simulated Crash Test Data},
publisher = {Institut für Numerische Simulation},
year = 2022,
month = may,
INS Preprints},
volume = 2208,
note = {We investigate for car and component crash tests the comparison of highly resolved experimental data with corresponding simulation data. Due to re- cent advances for optical measurement systems, one can nowadays obtain surface measurement data from a real crash experiment with high resolution in space and time. These advances call for new data processing methods that allow an alignment of this experimental data with numerical simulation results. We propose an approach based on a data representation stemming from a discrete Laplace–Beltrami operator, which allows such an alignment as well as a joint visual comparative analysis of both data sources. The method enables the identification of the best corresponding simulation among several numerical results, which allows inferring physical quantities that cannot be measured in experiments. We evaluate the procedure on synthetic and real experimental data from two different setups.},
url = {https://hdl.handle.net/20.500.11811/11598}
}
author = {{Jochen Garcke} and {Sara Hahner} and {Rodrigo Iza-Teran}},
title = {Alignment of Highly Resolved Time-Dependent Experimental and Simulated Crash Test Data},
publisher = {Institut für Numerische Simulation},
year = 2022,
month = may,
INS Preprints},
volume = 2208,
note = {We investigate for car and component crash tests the comparison of highly resolved experimental data with corresponding simulation data. Due to re- cent advances for optical measurement systems, one can nowadays obtain surface measurement data from a real crash experiment with high resolution in space and time. These advances call for new data processing methods that allow an alignment of this experimental data with numerical simulation results. We propose an approach based on a data representation stemming from a discrete Laplace–Beltrami operator, which allows such an alignment as well as a joint visual comparative analysis of both data sources. The method enables the identification of the best corresponding simulation among several numerical results, which allows inferring physical quantities that cannot be measured in experiments. We evaluate the procedure on synthetic and real experimental data from two different setups.},
url = {https://hdl.handle.net/20.500.11811/11598}
}
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