A two-level time step technique for the partitioned solution of one-dimensional arterial networks

Malossi, A. Cristiano I.; Blanco, Pablo; Deparis, Simone

doi:10.1016/j.cma.2012.05.017

Cited by 31 publications

(73 citation statements)

References 25 publications

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“…This method may be used in association with an operator splitting technique [60,116], where the flow rate is split into two components, one satisfying the pure elastic problem and the second one the visco-elastic correction.…”

Section: Numerical Discretizationmentioning

confidence: 99%

“…General statements on the most restrictive conditions are difficult to draw, as they depend on the specific problem (the vascular district for the 3D model as well as the portion of the network for the 1D one). For this reason, in partitioned schemes where the different solvers are called in an either sequential or parallel fashion, it is worth resorting to multi-level time stepping techniques, where the different geometric components are solved with individual convenient time steps and matching interface conditions are fulfilled thanks to suitable synchronization procedures [28,116] -see also Sect. 6.4.2 In the remainder of this Section we keep considering the time discretization of the coupled problems already introduced in Sect.…”

Section: Numerical Strategiesmentioning

confidence: 99%

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Geometric multiscale modeling of the cardiovascular system, between theory and practice

Quarteroni

Veneziani

Vergara

2016

Computer Methods in Applied Mechanics and Engineering

159

153

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This review paper addresses the so called geometric multiscale approach for the numerical simulation of blood flow problems, from its origin (that we can collocate in the second half of '90s) to our days. By this approach the blood fluid-dynamics in the whole circulatory system is described mathematically by means of heterogeneous featuring different degree of detail and different geometric dimension that interact together through appropriate interface coupling conditions.Our review starts with the introduction of the stand-alone problems, namely the 3D fluidstructure interaction problem, its reduced representation by means of 1D models, and the so-called lumped parameters (aka 0D) models, where only the dependence on time survives. We then address specific methods for stand-alone 3D models when the available boundary data are not enough to ensure the mathematical well posedness. These so-called "defective problems" naturally arise in practical applications of clinical relevance but also because of the interface coupling of heterogeneous problems that are generated by the geometric multiscale process. We also describe specific issues related to the boundary treatment of reduced models, particularly relevant to the geometric multiscale coupling. Next, we detail the most popular numerical algorithms for the solution of the coupled problems. Finally, we review some of the most representative works -from different research groups -which addressed the geometric multiscale approach in the past years.A proper treatment of the different scales relevant to the hemodynamics and their interplay is essential for the accuracy of numerical simulations and eventually for their clinical impact. This paper aims at providing a state-of-the-art picture of these topics, where the gap between theory and practice demands rigorous mathematical models to be reliably filled.

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Section: Numerical Discretizationmentioning

confidence: 99%

Section: Numerical Strategiesmentioning

confidence: 99%

Geometric multiscale modeling of the cardiovascular system, between theory and practice

Quarteroni

Veneziani

Vergara

2016

Computer Methods in Applied Mechanics and Engineering

159

153

View full text Add to dashboard Cite

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“…The spatial discretization is accomplished using P1 finite elements. For more details see Malossi et al 29 and references therein.…”

Section: Numerical Approximationmentioning

confidence: 99%

Numerical simulation of left ventricular assist device implantations: Comparing the ascending and the descending aorta cannulations

Bonnemain

Malossi

Lesinigo

et al. 2013

Medical Engineering & Physics

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“…The fluid problem (3) is coupled with the 1-D structural model through the pressure-area constitutive relation. As in [17,18] we take into account the elastic and viscoelastic responses of the vessel wall, such that…”

Section: -D Fsi Modelmentioning

confidence: 99%

“…In addition, a F and j F are the Coriolis and friction coefficients, respectively, whose definitions are given, e.g., in [17]. The fluid problem (3) is coupled with the 1-D structural model through the pressure-area constitutive relation.…”

Section: -D Fsi Modelmentioning

confidence: 99%

On the continuity of mean total normal stress in geometrical multiscale cardiovascular problems

Blanco

Deparis

Malossi

2013

Journal of Computational Physics

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a b s t r a c tIn this work an iterative strategy to implicitly couple dimensionally-heterogeneous blood flow models accounting for the continuity of mean total normal stress at interface boundaries is developed. Conservation of mean total normal stress in the coupling of heterogeneous models is mandatory to satisfy energetic consistency between them. Nevertheless, existing methodologies are based on modifications of the Navier-Stokes variational formulation, which are undesired when dealing with fluid-structure interaction or black box codes. The proposed methodology makes possible to couple one-dimensional and threedimensional fluid-structure interaction models, enforcing the continuity of mean total normal stress while just imposing flow rate data or even the classical Neumann boundary data to the models. This is accomplished by modifying an existing iterative algorithm, which is also able to account for the continuity of the vessel area, when required. Comparisons are performed to assess differences in the convergence properties of the algorithms when considering the continuity of mean normal stress and the continuity of mean total normal stress for a wide range of flow regimes. Finally, examples in the physiological regime are shown to evaluate the importance, or not, of considering the continuity of mean total normal stress in hemodynamics simulations.

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A two-level time step technique for the partitioned solution of one-dimensional arterial networks

Cited by 31 publications

References 25 publications

Geometric multiscale modeling of the cardiovascular system, between theory and practice

Geometric multiscale modeling of the cardiovascular system, between theory and practice

Numerical simulation of left ventricular assist device implantations: Comparing the ascending and the descending aorta cannulations

On the continuity of mean total normal stress in geometrical multiscale cardiovascular problems

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