%0 Conference Paper %1 a237832e9589437d888278bbe3f49539 %A Gerritzen, Johannes %A Hornig, Andreas %A Winkler, Peter %A Gude, Maik %B ECCM21 - Proceedings of the 21st European Conference on Composite Materials %D 2024 %I European Society for Composite Materials (ESCM) %K area_architectures topic_engineering Convolutional Direct FIS_scads Fiber Machine Strain dependency, identification, learning, networks, neural parameter plastics rate reinforced %P 1252--1259 %R 10.60691/yj56-np80 %T Direct parameter identification for highly nonlinear strain rate dependent constitutive models using machine learning %U https://eccm21.org/ %V 3 %X Fiber reinforced plastics (FRP) exhibit strongly non-linear deformation behavior. To capture this in simulations, intricate models with a variety of parameters are typically used. The identification of values for such parameters is highly challenging and requires in depth understanding of the model itself. Machine learning (ML) is a promising approach for alleviating this challenge by directly predicting parameters based on experimental results. So far, this works mostly for purely artificial data. In this work, two approaches to generalize to experimental data are investigated: a sequential approach, leveraging understanding of the constitutive model and a direct, purely data driven approach. This is exemplary carried out for a highly non-linear strain rate dependent constitutive model for the shear behavior of FRP.The sequential model is found to work better on both artificial and experimental data. It is capable of extracting well suited parameters from the artificial data under realistic conditions. For the experimental data, the model performance depends on the composition of the experimental curves, varying between excellently suiting and reasonable predictions. Taking the expert knowledge into account for ML-model training led to far better results than the purely data driven approach. Robustifying the model predictions on experimental data promises further improvement. %@ 978-2-912985-01-9

@inproceedings{a237832e9589437d888278bbe3f49539, abstract = {Fiber reinforced plastics (FRP) exhibit strongly non-linear deformation behavior. To capture this in simulations, intricate models with a variety of parameters are typically used. The identification of values for such parameters is highly challenging and requires in depth understanding of the model itself. Machine learning (ML) is a promising approach for alleviating this challenge by directly predicting parameters based on experimental results. So far, this works mostly for purely artificial data. In this work, two approaches to generalize to experimental data are investigated: a sequential approach, leveraging understanding of the constitutive model and a direct, purely data driven approach. This is exemplary carried out for a highly non-linear strain rate dependent constitutive model for the shear behavior of FRP.The sequential model is found to work better on both artificial and experimental data. It is capable of extracting well suited parameters from the artificial data under realistic conditions. For the experimental data, the model performance depends on the composition of the experimental curves, varying between excellently suiting and reasonable predictions. Taking the expert knowledge into account for ML-model training led to far better results than the purely data driven approach. Robustifying the model predictions on experimental data promises further improvement. }, added-at = {2024-11-28T16:27:18.000+0100}, author = {Gerritzen, Johannes and Hornig, Andreas and Winkler, Peter and Gude, Maik}, biburl = {https://puma.scadsai.uni-leipzig.de/bibtex/234f96c0c260c8de96ab81b95ef919042/scadsfct}, booktitle = {ECCM21 - Proceedings of the 21st European Conference on Composite Materials}, day = 2, doi = {10.60691/yj56-np80}, interhash = {47dbfa73e7218fc207b1e7e70df159f0}, intrahash = {34f96c0c260c8de96ab81b95ef919042}, isbn = {978-2-912985-01-9}, keywords = {area_architectures topic_engineering Convolutional Direct FIS_scads Fiber Machine Strain dependency, identification, learning, networks, neural parameter plastics rate reinforced}, language = {English}, month = jul, note = {21st European Conference on Composite Materials, ECCM 21 ; Conference date: 02-07-2024 Through 05-07-2024}, pages = {1252--1259}, publisher = {European Society for Composite Materials (ESCM)}, timestamp = {2024-12-06T14:36:51.000+0100}, title = {Direct parameter identification for highly nonlinear strain rate dependent constitutive models using machine learning}, url = {https://eccm21.org/}, volume = 3, year = 2024 }