A dynamic numerical method for models of renal tubules
- 1 May 1994
- journal article
- Published by Springer Nature in Bulletin of Mathematical Biology
- Vol. 56 (3) , 547-565
- https://doi.org/10.1007/bf02460470
Abstract
We show that an explicit method for solving hyperbolic partial differential equations can be applied to a model of a renal tubule to obtain both dynamic and steady-state solutions. Appropriate implementation of this method eliminates numerical instability arising from reversal of intratubular flow direction. To obtain second-order convergence in space and time, we employ the recently developed ENO (Essentially Non-Oscillatory) methodology. We present examples of computed flows and concentration profiles in representative model contexts. Finally, we indicate briefly how model tubules may be coupled to construct large-scale simulations of the renal counterflow system.Keywords
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