In this work a numerical strategy to address the solution of the blood flow in one-dimensional arterial networks through a topology-based decomposition is presented. Such decomposition results in the local analysis of the blood flow in simple arterial segments. Hence, iterative methods are used to perform the strong coupling among the segments, which communicate through non-overlapping interfaces. Specifically, two approaches are considered to solve the associated nonlinear interface problem: (i) the Newton method and (ii) the Broyden method. Moreover, since the modeling of blood flow in compliant vessels is tackled using explicit finite element methods, we formulate the coupling problem using a two-level time stepping technique. A local (i...
In the present work, we propose an FFT-based method for solving blood flow equations in an arterial ...
The fluid structure interaction mechanism in vascular dynamics can be described by either 3D or 1D m...
The aim of the present work is to address the closure problem for hemodynamic simulations by develop...
In this study the one dimensional blood flow equations are solved using a newly proposed enhanced tr...
Increasing efforts exist in integrating different levels of detail in models of the cardiovascular s...
AbstractWe consider a one-dimensional blood flow model suitable for larger arteries. It consists of ...
In this study, parallel computation of blood flow in a 1-D model of human arterial network has been ...
When modeling complex systems such as the cardiovascular circulation one often needs to separate the...
When modeling complex systems such as the cardiovascular circulation one often needs to separate the...
The blood flow in arterial trees in the cardiovascular system can be simulated with the help of diff...
The development of mathematical models for studying phenomena observed in vascular networks is very...
The blood flow in arterial trees in the cardiovascular system can be simulated with the help of diff...
The paper describes the numerical coupling challenges in multiphysics problems like the simulation o...
AbstractThe present work deals with the parameter identification problem in outflow models used in o...
In this paper a family of one-dimensional nonlinear systems which model the blood pulse propagation ...
In the present work, we propose an FFT-based method for solving blood flow equations in an arterial ...
The fluid structure interaction mechanism in vascular dynamics can be described by either 3D or 1D m...
The aim of the present work is to address the closure problem for hemodynamic simulations by develop...
In this study the one dimensional blood flow equations are solved using a newly proposed enhanced tr...
Increasing efforts exist in integrating different levels of detail in models of the cardiovascular s...
AbstractWe consider a one-dimensional blood flow model suitable for larger arteries. It consists of ...
In this study, parallel computation of blood flow in a 1-D model of human arterial network has been ...
When modeling complex systems such as the cardiovascular circulation one often needs to separate the...
When modeling complex systems such as the cardiovascular circulation one often needs to separate the...
The blood flow in arterial trees in the cardiovascular system can be simulated with the help of diff...
The development of mathematical models for studying phenomena observed in vascular networks is very...
The blood flow in arterial trees in the cardiovascular system can be simulated with the help of diff...
The paper describes the numerical coupling challenges in multiphysics problems like the simulation o...
AbstractThe present work deals with the parameter identification problem in outflow models used in o...
In this paper a family of one-dimensional nonlinear systems which model the blood pulse propagation ...
In the present work, we propose an FFT-based method for solving blood flow equations in an arterial ...
The fluid structure interaction mechanism in vascular dynamics can be described by either 3D or 1D m...
The aim of the present work is to address the closure problem for hemodynamic simulations by develop...