Semi-computational simulation of magneto-hemodynamic flow in a semi-porous channel using optimal homotopy and differential transform methods

Computers in Biology and Medicine

Volumn 43, Issue 9, 2013, Pages 1142-1153

  Basiri Parsa, A ^a   Rashidi, M M ^b   Anwar Beg O ^c   Sadri, S M ^b  

^a ISLAMIC AZAD UNIVERSITY   (Iran)

^b BU ALI SINA UNIVERSITY   (Iran)

^c Gort Engovation Research (Propulsion and Biomechanics)   (United Kingdom)

Author keywords

Blood flow control; Differential transform method (DTM); Hartmann number; Homotopy analysis method (HAM); Laminar viscous flow; Magneto hemodynamics; Nonlinear differential equations; Semi porous channel; Wall transpiration

Indexed keywords

BLOOD FLOW; DIFFERENTIAL TRANSFORM METHOD; HARTMANN NUMBERS; HOMOTOPY ANALYSIS METHODS; LAMINAR VISCOUS FLOW; MAGNETO-HEMODYNAMICS; NONLINEAR DIFFERENTIAL EQUATION; SEMI-POROUS CHANNEL; WALL TRANSPIRATION;

BIOLOGICAL SYSTEMS; BOUNDARY CONDITIONS; FLOW MEASUREMENT; HEMODYNAMICS; MAGNETIC FIELDS; MAGNETOHYDRODYNAMICS; MAGNETOS; NONLINEAR ANALYSIS; OPTIMIZATION; ORDINARY DIFFERENTIAL EQUATIONS; PARTIAL DIFFERENTIAL EQUATIONS; REYNOLDS NUMBER; RUNGE KUTTA METHODS; TRANSPIRATION; VISCOUS FLOW;

NUMERICAL METHODS;

ACCURACY; ANALYTIC METHOD; ARTICLE; BLOOD FLOW; COMPUTATIONAL FLUID DYNAMICS; HEART HEMODYNAMICS; HOMOTOPY ANALYSIS METHOD; MAGNETIC FIELD; MAGNETOHYDRODYNAMICS; MATHEMATICAL MODEL; NONLINEAR SYSTEM; PRIORITY JOURNAL; REYNOLDS RISK SCORE; VELOCITY;

BLOOD FLOW CONTROL; DIFFERENTIAL TRANSFORM METHOD (DTM); HARTMANN NUMBER; HOMOTOPY ANALYSIS METHOD (HAM); LAMINAR VISCOUS FLOW; MAGNETO-HEMODYNAMICS; NONLINEAR DIFFERENTIAL EQUATIONS; SEMI-POROUS CHANNEL; WALL TRANSPIRATION;

BLOOD FLOW VELOCITY; BLOOD VISCOSITY; COMPUTER SIMULATION; HUMANS; MAGNETIC FIELDS; MODELS, CARDIOVASCULAR; POROSITY;

EID: 84880019537     PISSN: 00104825     EISSN: 18790534     Source Type: Journal    
DOI: 10.1016/j.compbiomed.2013.05.019     Document Type: Article

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