Black-box decomposition approach for computational hemodynamics: One-dimensional models

Computer Methods in Applied Mechanics and Engineering

Volumn 200, Issue 13-16, 2011, Pages 1389-1405

  Blanco, P J ^a,d   Leiva, J S ^b   Feijoo R A ^a,d   Buscaglia, G C ^c,d  

^a LABORATÓRIO NACIONAL DE COMPUTAÇÃO CIENTÍFICA   (Brazil)

^b INSTITUTO BALSEIRO   (Argentina)

^c UNIVERSITY OF SÃO PAULO   (Brazil)

^d Instituto Nacional de Ciencia e Tecnologia   (Brazil)

Author keywords

1D models; Domain decomposition; Hemodynamics; Partitioned analysis; Wave propagation

Indexed keywords

1-D MODELS; BLACK BOXES; BROYDEN; CARDIOVASCULAR APPLICATIONS; COMPLETE NETWORKS; COMPUTATIONAL HEMODYNAMICS; CONNECTION POINTS; DECOMPOSITION APPROACH; DECOMPOSITION STRATEGY; DIMENSIONAL NETWORK; DIMENSIONAL REPRESENTATION; DOMAIN DECOMPOSITION; DOMAIN DECOMPOSITIONS; GMRES ALGORITHM; ITERATIVE STRATEGY; LEVELS OF DETAIL; MATRIX; NON-LINEAR; NON-LINEAR SOLVER; NUMERICAL SOLVERS; ONE-DIMENSIONAL MODEL; PARTITIONED ANALYSIS; STABILITY RESTRICTION; STRONG COUPLING; SUB-CRITICAL; SUB-NETWORK; SUBNETWORKS; SYSTEMIC CIRCULATION; TEST CASE; TIME STEP; TIME STEP SIZE; WAVE PROPAGATION PROBLEMS;

ALGORITHMS; CARDIOVASCULAR SYSTEM; DOMAIN DECOMPOSITION METHODS; HEMODYNAMICS; HYDRODYNAMICS; LINEAR SYSTEMS; NONLINEAR SYSTEMS; ONE DIMENSIONAL; TIME VARYING SYSTEMS; WAVE PROPAGATION;

THREE DIMENSIONAL;

EID: 78751646122     PISSN: 00457825     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.cma.2010.12.006     Document Type: Article

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