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Paper detail

An integrated heterogeneous computing framework for ensemble simulations of laser-induced ignition

An integrated computational framework is introduced to study complex engineering systems through physics-based ensemble simulations on heterogeneous supercomputers. The framework is primarily designed for the quantitative assessment of laser-induced ignition in rocket engines. We develop and combine an implicit programming system, a compressible reacting flow solver, and a data generation/management strategy on a robust and portable platform. We systematically present this framework using test problems on a hybrid CPU/GPU machine. Efficiency, scalability, and accuracy of the solver are comprehensively assessed with canonical unit problems. Ensemble data management and autoencoding are demonstrated using a canonical diffusion flame case. Sensitivity analysis of the ignition of a turbulent, gaseous fuel jet is performed using a simplified, three-dimensional model combustor. Our approach unifies computer science, physics and engineering, and data science to realize a cross-disciplinary workflow. The framework is exascale-oriented and can be considered a benchmark for future computational science studies of real-world systems.

preprint2022arXivOpen access
Kazuki MaedaThiago TeixeiraJonathan M. WangJeffrey M. HokansonCaetano MeloneMario Di RenzoSteve JonesJavier UrzayGianluca Iaccarino
Computational Engineering, Finance, and Sciencephysics.flu-dynphysics.data-anDistributed, Parallel, and Cluster Computing
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Kazuki MaedaThiago TeixeiraJonathan M. WangJeffrey M. HokansonCaetano MeloneMario Di RenzoSteve JonesJavier UrzayGianluca Iaccarino

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