Team:ULB-Brussels/Modelling/Population-Dynamics
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<h3>$1.1)$ $By$ $Probabilities$</h3> | <h3>$1.1)$ $By$ $Probabilities$</h3> | ||
- | When some new plasmids are genetically introduced into the cytoplasm of | + | When some new plasmids are genetically introduced into the cytoplasm of $\EColi$ bacteria, this doesn't garantee that the future copies will contain it. Indeed, these plasmids can be lost after cell division or replication, so it's interesting to study a model based on the different possibilities of plasmid combinations in bacteria, like in the studies of mutations in animals. A typical example of a similar way is found if we study the mutations of the eyes or hair color in a family, by vertical genes transfer. In this case, there's a horizontal genes transfer too, originated by the plasmids. </p> |
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<h3>$1.2)$ $By$ $Logistic$ $\small\&\normalsize$ $Lotka$ $Equations$</h3> | <h3>$1.2)$ $By$ $Logistic$ $\small\&\normalsize$ $Lotka$ $Equations$</h3> | ||
- | The Logistic Equation was initially introduced during the beginning of the XIXth Century, by the belgian mathematician P.F. Verhulst. Now, this equation is mainly used in Population Dynamics Models, especially in Biological Sciences. Mathematicians currently finish Ph.D thesis using this, and the analytical Lotka-Volterra model is directly associated with the Verhulst theory.</p> | + | The Logistic Equation was initially introduced during the beginning of the XIXth Century, by the belgian mathematician P.F. Verhulst. Now, this equation is mainly used in Population Dynamics Models, especially in Biological Sciences. Mathematicians currently finish Ph.D thesis using this, and the analytical $Lotka-Volterra$ $model$ is directly associated with the $Verhulst$ $theory$.</p> |
- | Another interesting model is obtained from Euler-Lotka equation to the Leslie matrix coefficients. By identifying the caracteristic eigenvalues and eigenvectors analyse, we estimate the asymptotic stability (stable steady state) and the profile of the growth rate, as in [Fig.m3]. An advantage is that this model is yet discrete, so by computing it, we don't loose info of the background theory. | + | Another interesting model is obtained from Euler-Lotka equation to the $Leslie$ $matrix$ $coefficients$. By identifying the caracteristic eigenvalues and eigenvectors analyse, we estimate the asymptotic stability (stable steady state) and the profile of the growth rate, as in [Fig.m3]. An advantage is that this model is yet discrete, so by computing it, we don't loose info of the background theory. |
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Revision as of 15:21, 20 September 2014
$~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ \newcommand{\MyColi}{{\small Mighty\hspace{0.12cm}Coli}} \newcommand{\Stabi}{\small Stabi}$ $\newcommand{\EColi}{\small E.coli} \newcommand{\SCere}{\small S.cerevisae}\\[0cm] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ \newcommand{\PI}{\small PI}$ $\newcommand{\Igo}{\Large\mathcal{I}} \newcommand{\Tgo}{\Large\mathcal{T}} \newcommand{\Ogo}{\Large\mathcal{O}} ~$
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