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Flow-field reconstruction in rotating detonation combustor based on physics-informed neural network

Xutun Wang, Haocheng Wen, Tong Hu, Bing Wang

2023Physics of Fluids19 citationsDOI

Abstract

The flow-field reconstruction of a rotating detonation combustor (RDC) is essential to understand the stability mechanism and performance of rotating detonation engines. This study embeds a reduced-order model of an RDC into a neural network (NN) to construct a physics-informed neural network (PINN) to achieve the full-dimensional high-resolution reconstruction of the combustor flow field based on partially observed data. Additionally, the unobserved physical fields are extrapolated through the NN-embedded physical model. The influence of the residual point sampling strategy and observation point spatial-temporal sampling resolution on the reconstruction results are studied. As a surrogate model of the RDC, the PINN fills the gap that traditional computational fluid dynamics methods have difficulty solving, such as inverse problems, and has engineering value for the flow-field reconstruction of RDCs.

Topics & Concepts

CombustorPhysicsDetonationArtificial neural networkFlow (mathematics)Field (mathematics)Sampling (signal processing)Inverse problemResidualStatistical physicsMechanicsApplied mathematicsAlgorithmArtificial intelligenceComputer scienceMathematical analysisCombustionOpticsMathematicsChemistryOrganic chemistryDetectorExplosive materialPure mathematicsCombustion and Detonation ProcessesNuclear Engineering Thermal-HydraulicsWind and Air Flow Studies