Reconstruction of flow domain boundaries from velocity data via multi-step optimization of distributed resistance
Abstract
We reconstruct the unknown shape of a flow domain using partially available internal velocity measurements. This inverse problem is motivated by applications in cardiovascular imaging where motion-sensitive protocols, such as phase-contrast MRI, can be used to recover three-dimensional velocity fields inside blood vessels. In this context, the information about the domain shape serves to quantify the severity of pathological conditions, such as vessel obstructions. We consider a flow modeled by a linear Brinkman problem with a fictitious resistance accounting for the presence of additional boundaries. To reconstruct these boundaries, we employ a multi-step gradient-based variational method to compute a resistance that minimizes the difference between the computed flow velocity and the available data. Afterward, we apply different post-processing steps to reconstruct the shape of the internal boundaries. To limit the overall computational cost, we use a stabilized equal-order finite element method. We prove the stability and the well-posedness of the considered optimization problem. We validate our method on three-dimensional examples based on synthetic velocity data and using realistic geometries obtained from cardiovascular imaging.
Más información
Título según WOS: | Reconstruction of flow domain boundaries from velocity data via multi-step optimization of distributed resistance |
Título de la Revista: | COMPUTERS & MATHEMATICS WITH APPLICATIONS |
Volumen: | 129 |
Editorial: | PERGAMON-ELSEVIER SCIENCE LTD |
Fecha de publicación: | 2023 |
Página de inicio: | 11 |
Página final: | 33 |
DOI: |
10.1016/j.camwa.2022.11.006 |
Notas: | ISI |