Team:Grenoble/Modeling/Amplification/Quorum

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Revision as of 15:48, 21 September 2012

iGEM Grenoble 2012

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The goal of this part was only to check the speed of the diffusion. We use the same model as the 2011 IGEM team of Grenoble, which is based on the Bangalore 2007 IGEM team model. We first have to add the diffusion terms in the equations thus we get:

Because of the temporal and special derivatives, we couldn’t use a classic matlab solver to solve this set of equations. The approximation we used consisted in dividing the space into a grid:

It is the finite difference method. We thus get:

with h=l_x/N, where l_x is the length of the grid and N is the number of points of discretization along x. By using the same approximation on y_i, and assuming that l_y=l_x, and that we have the same number of points of discretization, we get:

In addition, we also use the finite difference method on the time scale. Thus, we get:

where p=∆t/Nt where ∆t is the interval of time we work in and N_t the number of points of our time discretization.

With these approximations, we could solve the equations.

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 <center><img src="https://static.igem.org/mediawiki/2012/4/48/Eq36_grenoble.png" alt="" /></center>
 </br>
+</br>
+In addition, we also use the finite difference method on the time scale. Thus, we get:
+</br>
+</br>
+<center><img src="https://static.igem.org/mediawiki/2012/8/84/Eq37_grenoble.png" alt="" /></center>
+</br>
+</br>
+where p=∆t/Nt where ∆t is the interval of time we work in and N<SUB>t</SUB> the number of points of our time discretization.
+</br>
+</br>
+With these approximations, we could solve the equations.
 </br>
 </section>