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Physics-Informed Neural Networks Enhanced Particle Tracking Velocimetry: An Example for Turbulent Jet Flow

Shengze Cai, Callum Gray, George Em Karniadakis

2024IEEE Transactions on Instrumentation and Measurement37 citationsDOI

Abstract

Particle image velocimetry (PIV) and particle tracking velocimetry (PTV) are important flow visualization technologies for measuring global velocity fields in a non-intrusive manner. However, they are limited by the spatial resolution of the measurement, and they require further post-processing steps to refine the flow fields. To this end, we employ a deep learning method, physics-informed neural networks (PINNs), which can integrate the sparse velocity measurements from PIV or PTV with the governing equations of the fluid flow by a neural network. A real experiment, where the tomographic PTV setup is applied to measure the three-dimensional turbulent jet flow, is considered to evaluate the proposed method. We perform a systematic study based on the experimental data, demonstrating that the PINN-enhanced velocimetry approach can yield super-resolution for the velocity vectors, hence demanding only of the order of 100 vectors per snapshot compared to 16,500 vectors at full resolution. In addition, PINNs infer the pressure field without providing any pressure information. The proposed algorithm can be readily implemented with the existing PIV/PTV software, providing a standard method for greatly enhancing experimental data in fluid dynamics.

Topics & Concepts

Particle tracking velocimetryParticle image velocimetryTurbulenceFlow visualizationPhysicsVelocimetryVector fieldTracking (education)Flow measurementVisualizationFlow (mathematics)Computer scienceOpticsArtificial intelligenceMechanicsPsychologyPedagogyFluid Dynamics and Turbulent FlowsModel Reduction and Neural NetworksFluid Dynamics and Vibration Analysis
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