Title :
Computationally efficient velocity profile solutions for cardiac haemodynamics
Author :
Hann, C.E. ; Chase, J.G. ; Smith, B.W. ; Shaw, G.M.
Author_Institution :
Dept. of Mech. Eng., Canterbury Univ., Christchurch, New Zealand
Abstract :
This work reformulates the nonlinear differential equations associated with time varying resistance in minimal cardio-vascular system models into a system of linear equations with an analytical solution. The importance of including time varying resistance is shown for a single chamber model where there is a 17.5% difference in cardiac output when compared with a constant resistance model. However, the increased complexity has significant extra computational cost. This new formulation provides a significant computational saving of 15x over the previous method. This improvement enables more physiological accuracy with minimal cost in computational time. As a result, the model can be used in clinical situations to aid diagnosis and therapy selection without compromising on physiological accuracy.
Keywords :
cardiovascular system; computational fluid dynamics; haemodynamics; nonlinear differential equations; physiological models; analytical solution; cardiac haemodynamics; computationally efficient velocity profile solution; linear equation; minimal cardiovascular system model; nonlinear differential equation; physiological accuracy; time varying resistance; Acceleration; Blood flow; Cardiovascular system; Computational efficiency; Equations; Finite element methods; Heart valves; Immune system; Medical treatment; Testing; Analytical solution; Computationally efficient; Linear; Non-linear; Time varying resistance;
Conference_Titel :
Engineering in Medicine and Biology Society, 2004. IEMBS '04. 26th Annual International Conference of the IEEE
Conference_Location :
San Francisco, CA
Print_ISBN :
0-7803-8439-3
DOI :
10.1109/IEMBS.2004.1403316
