Qualitative Models of Neural Activity and the Carleman Embedding Technique.

Gezahagne, Azamed Yehuala

19 August 2009

The two variable Fitzhugh Nagumo model behaves qualitatively like the four variable Hodgkin-Huxley space clamped system and is more mathematically tractable than the Hodgkin Huxley model, thus allowing the action potential and other properties of the Hodgkin Huxley system to be more readily be visualized. In this thesis, it is shown that the Carleman Embedding Technique can be applied to both the Fitzhugh Nagumo model and to Van der Pol's model of nonlinear oscillation, which are both finite nonlinear systems of differential equations. The Carleman technique can thus be used to obtain approximate solutions of the Fitzhugh Nagumo model and to study neural activity such as excitability.

Excitability

Green's function

Carleman embedding

Fitzhugh Nagumo

Applied Mathematics

Non-linear Dynamics

Physical Sciences and Mathematics

Solving the Differential Equation for the Probit Function Using a Variant of the Carleman Embedding Technique.

Alu, Kelechukwu Iroajanma

07 May 2011

The probit function is the inverse of the cumulative distribution function associated with the standard normal distribution. It is of great utility in statistical modelling. The Carleman embedding technique has been shown to be effective in solving first order and, less efficiently, second order nonlinear differential equations. In this thesis, we show that solutions to the second order nonlinear differential equation for the probit function can be approximated efficiently using a variant of the Carleman embedding technique.

Carleman embedding

linearization

quantile function

probit function

differential equation

Applied Statistics

Physical Sciences and Mathematics

Statistics and Probability

A Variation of the Carleman Embedding Method for Second Order Systems.

Dzacka, Charles Nunya

19 December 2009

The Carleman Embedding is a method that allows us to embed a finite dimensional system of nonlinear differential equations into a system of infinite dimensional linear differential equations. This technique works well when dealing with first-order nonlinear differential equations. However, for higher order nonlinear ordinary differential equations, it is difficult to use the Carleman Embedding method. This project will examine the Carleman Embedding and a variation of the method which is very convenient in applying to second order systems of nonlinear equations.

Applied Mathematics

Carleman embedding

perturbation technique

Applied Mathematics

Non-linear Dynamics

Physical Sciences and Mathematics