Machine-Learning-Accelerated Simulations for the Design of Airbag
Constrained by Obstacles at Rest 2023-22-0001
Predicting airbag deployment geometries is an important task for airbag and
vehicle designers to meet safety standards based on biomechanical injury risk
functions. This prediction is also an extraordinarily complex problem given the
number of disciplines and their interactions. State-of-the-art airbag deployment
geometry simulations (including time history) entail large, computationally
expensive numerical methods such as finite element analysis (FEA) and
computational fluid dynamics (CFD), among others. This complexity results in
exceptionally large simulation times, making thorough exploration of the design
space prohibitive. This paper proposes new parametric simulation models which
drastically accelerate airbag deployment geometry predictions while maintaining
the accuracy of the airbag deployment geometry at reasonable levels; these
models, called herein machine learning (ML)-accelerated models, blend physical
system modes with data-driven techniques to accomplish fast predictions within a
design space defined by airbag and impactor parameters. These ML-accelerated
models are evaluated with virtual test cases of increasing complexity: from
airbag deployments against a locked deformable obstacle to airbag deployments
against free rigid obstacles; the dimension of the tested design spaces is up to
six variables. ML training times are documented for completeness; thus, airbag
design explorers or optimization engineers can assess the full budget for
ML-accelerated approaches including training. In these test cases, the
ML-accelerated simulation models run three orders of magnitude faster than the
high-fidelity multi-physics methods, while accuracies are kept within reasonable
levels within the design space.
Citation: Valenzuela del Rio, J., Lancashire, R., Chatrath, K., Ritmeijer, P. et al., "Machine-Learning-Accelerated Simulations for the Design of Airbag Constrained by Obstacles at Rest," Stapp Car Crash Journal 67(1):1-13, 2023, https://doi.org/10.4271/2023-22-0001. Download Citation
Author(s):
Jose E. Valenzuela del Rio, Richard Lancashire, Karan Chatrath, Peter Ritmeijer, Elena Arvanitis, Lucia Mirabella
Affiliated:
Siemens Technology (United States), Siemens Industry Software (Netherlands)
Pages: 13
Event:
67th Stapp Car Crash Conference
ISSN:
1532-8546
e-ISSN:
2993-1940
Also in:
Stapp Car Crash Journal-STAPP2023-EJ
Related Topics:
Computational fluid dynamics (CFD)
Finite element analysis
Airbag systems
Machine learning
SAE MOBILUS
Subscribers can view annotate, and download all of SAE's content.
Learn More »