Flow in an elastic tube subject to prescribed forcing: A model of umbilical venous flow.
Waters, S.L., Guiot, C. (2001)
Journal of Theoretical Medicine
Similarity:
Displaying similar documents to “Deterministic multivariate model for simulation of downstream BIVAL automatic controller in irrigation systems.”
Flow in an elastic tube subject to prescribed forcing: A model of umbilical venous flow.
Nonlinear peristaltic transport of MHD flow through a porous medium.
Mekheimer, Kh. S., Al-Arabi, T. H. (2003)
International Journal of Mathematics and Mathematical Sciences
Similarity:
A numerical study of effects of the axial stress on unsteady liquid pipeline flows.
Watanabe, Masaji, Kono, Yukio, Suito, Hiroshi (2004)
International Journal of Mathematics and Mathematical Sciences
Similarity:
A numerical investigation of heat transfer cardiac output measurements.
Fotheringham, P., Gourlay, A.R., Mckee, S., Andrews, S. (2005)
Journal of Theoretical Medicine
Similarity:
Influence of wall waviness on friction and pressure drop in channels.
Vajravelu, K., Nayfeh, Ali H. (1981)
International Journal of Mathematics and Mathematical Sciences
Similarity:
Pulsatile flow of a two-fluid model for blood flow through arterial stenosis.
Sankar, D.S. (2010)
Mathematical Problems in Engineering
Similarity:
Investigations on actuator dynamics through theoretical and finite element approach.
Hiremath, Somashekhar S., Singaperumal, M. (2010)
Mathematical Problems in Engineering
Similarity:
Hydrodynamic flow between rotating eccentric cylinders with suction at the porous walls.
Meena, S., Kandaswamy, P., Debnath, Lokenath (2001)
International Journal of Mathematics and Mathematical Sciences
Similarity:
Effects of Poiseuille flow on peristaltic transport.
El Shehawey, El Sayed F., El Sebaei, Wahed A. F. (2001)
International Journal of Mathematics and Mathematical Sciences
Similarity:
Two-Layer Flow with One Viscous Layer in Inclined Channels
O. K. Matar, G. M. Sisoev, C. J. Lawrence (2008)
Mathematical Modelling of Natural Phenomena
Similarity:
We study pressure-driven, two-layer flow in inclined channels with high density and viscosity contrasts. We use a combination of asymptotic reduction, boundary-layer theory and the Karman-Polhausen approximation to derive evolution equations that describe the interfacial dynamics. Two distinguished limits are considered: where the viscosity ratio is small with density ratios of order unity, and where both density and viscosity ratios are small. The evolution equations account for the...
Mathematical foundation of flow of glaciers and large ice masses
Kolumban Hutter (1985)
Banach Center Publications
Similarity: