Use of physiological connectivity in solving renal concentrating mechanism equations
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Publication:2277175
DOI10.1016/0895-7177(90)90238-IzbMath0724.92005OpenAlexW2007686848MaRDI QIDQ2277175
John L. Stephenson, Reginald P. Tewarson
Publication date: 1990
Published in: Mathematical and Computer Modelling (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/0895-7177(90)90238-i
discretizationnonlinear differential equationsnumerical solutionsnonlinear algebraic equationskidney modelingfluid flow networkshybrid quasi-Newton type method
Related Items (2)
Efficient solution of differential equations for kidney concentrating mechanism analyses ⋮ Models of kidney concentrating mechanism: Relationship between core concentrations and tube permeabilities
Cites Work
- Using quasi-Newton methods for kidney modeling equations
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- Solute concentration in the kidney. II: Input-output studies on a central core model
- Comparison of numerical methods for renal network flows
- A note on solution of large sparse systems of nonlinear equations
- A unified derivation of quasi-Newton methods for solving non-sparse and sparse nonlinear equations
- On computing generalized inverses
- A desirable form for sparse matrices when computing their inverse in factored forms
- An analysis of countercurrent exchange with emphasis on renal function
- Model of solute and water movement in the kidney.
- Quantitative Analysis of Mass and Energy Balance in Non-Ideal Models of the Renal Counterflow System
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