Anisotropic adaptive finite element method for modelling blood flow

Anisotropic adaptive finite element method for modelling blood flow

In this study, we present an adaptive anisotropic finite element method (FEM) and demonstrate how computational efficiency can be increased when applying the method to the simulation of blood flow in the cardiovascular system. We use the SUPG formulation for the transient 3D incompressible Navier-St...

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Bibliographic Details
Published in:Computer methods in biomechanics and biomedical engineering Vol. 8; no. 5; pp. 295 - 305
Main Authors: Müller, J., Sahni, O., Li, X., Jansen, K. E., Shephard, M. S., Taylor, C. A.
Format: Journal Article
Language:English
Published: England Taylor & Francis Group 01-10-2005
Subjects:
Adaptation, Physiological - physiology
Animals
anisotropic adaptive techniques
Anisotropy
Arteries - physiology
Blood flow
Blood Flow Velocity - physiology
Blood Pressure - physiology
Computer Simulation
Elasticity
Finite Element Analysis
Finite element method
Hemorheology - methods
Humans
Models, Cardiovascular
Navier-Stokes equations
Pulsatile Flow - physiology
Viscosity
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Summary:In this study, we present an adaptive anisotropic finite element method (FEM) and demonstrate how computational efficiency can be increased when applying the method to the simulation of blood flow in the cardiovascular system. We use the SUPG formulation for the transient 3D incompressible Navier-Stokes equations which are discretised by linear finite elements for both the pressure and the velocity field.  Given the pulsatile nature of the flow in blood vessels we have pursued adaptivity based on the average flow over a cardiac cycle. Error indicators are derived to define an anisotropic mesh metric field. Mesh modification algorithms are used to anisotropically adapt the mesh according to the desired size field. We demonstrate the efficiency of the method by first applying it to pulsatile flow in a straight cylindrical vessel and then to a porcine aorta with a stenosis bypassed by a graft. We demonstrate that the use of an anisotropic adaptive FEM can result in an order of magnitude reduction in computing time with no loss of accuracy compared to analyses obtained with uniform meshes.
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ISSN:1025-5842
1476-8259
DOI:10.1080/10255840500264742