We consider an optimal flow control problem in a patient-specific coronary artery bypass graft with the aim of matching the blood flow velocity with given measurements as the Reynolds number varies in a physiological range. Blood flow is modelled with the steady incompressible Navier-Stokes equations. The geometry consists in a stenosed left anterior descending artery where a single bypass is performed with the right internal thoracic artery. The control variable is the unknown value of the normal stress at the outlet boundary, which is need for a correct set-up of the outlet boundary condition. For the numerical solution of the parametric optimal flow control problem, we develop a data-driven reduced order method that combines proper orthogonal decomposition (POD) with neural networks. We present numerical results showing that our data-driven approach leads to a substantial speed-up with respect to a more classical POD-Galerkin strategy proposed in [62], while having comparable accuracy.
A data-driven reduced order method for parametric optimal blood flow control: Application to coronary bypass graft / Balzotti, Caterina; Siena, Pierfrancesco; Girfoglio, Michele; Quaini, Annalisa; Rozza, Gianluigi. - In: COMMUNICATIONS IN OPTIMIZATION THEORY. - ISSN 2051-2953. - 2022:(2022). [10.23952/cot.2022.26]
A data-driven reduced order method for parametric optimal blood flow control: Application to coronary bypass graft
Caterina Balzotti;Pierfrancesco Siena;Michele Girfoglio;Annalisa Quaini;Gianluigi Rozza
2022-01-01
Abstract
We consider an optimal flow control problem in a patient-specific coronary artery bypass graft with the aim of matching the blood flow velocity with given measurements as the Reynolds number varies in a physiological range. Blood flow is modelled with the steady incompressible Navier-Stokes equations. The geometry consists in a stenosed left anterior descending artery where a single bypass is performed with the right internal thoracic artery. The control variable is the unknown value of the normal stress at the outlet boundary, which is need for a correct set-up of the outlet boundary condition. For the numerical solution of the parametric optimal flow control problem, we develop a data-driven reduced order method that combines proper orthogonal decomposition (POD) with neural networks. We present numerical results showing that our data-driven approach leads to a substantial speed-up with respect to a more classical POD-Galerkin strategy proposed in [62], while having comparable accuracy.| File | Dimensione | Formato | |
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