Download e - Klaus Schittkowski

Transcript
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name
HYPERBO5
IN LAYER
INTEG
INTERF1
INTERF2
INV PROB
IONTRAN1
IONTRAN3
ISOTHRM1
ISOTHRM2
JONTO
KILN
KIN SORP
LAM FLOW
LAPLACE
LDCP
LIN ADV
LIN HC
LIN HYP1
LIN HYP2
LIN HYP3
LNCHROM1
LNCHROM2
LOSSLESS
LUNG
MALTDX10
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90
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25
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1
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l̃
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nc
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mr
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background
Hyperbolic test system
Catalyst with inert layers (diffusion, absorption, desorption)
Population dynamics with integro-differential equation
System with interface (not modeled)
System with interface
Inverse problem in heat conduction
Ion transport through membrane by diffusion
Ion transport through membrane with Langmuir isotherm for
sorption
Reactive solute transport, advective-dispersive transport
Reactive solute transport, advective-dispersive transport (Freundlich version)
Optimal control of iontophoresis with three membranes
Heating a probe in a kiln
Kinetic sorption by advection-dispersion
Unsteady laminar flow in a circular tube
Laplace equation (elliptic)
Linear diffusion-convection equation
Linear advection problem, highly nonlinear initial condition
Linear heat conduction
First-order linear hyperbolic equation
First-order linear hyperbolic equation with interface
First-order linear hyperbolic equation with variable velocity field
Nonlinear chromatographic system
Nonlinear chromatographic system
Lossless electric transmission line
Protein application in lung with decomposition
Drying of maltodextrin in a convection oven, simultaneous fitting
of 10 data sets
(continued)
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ref
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