Team:Grenoble-EMSE-LSU/Project/Modelling/Parameters

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<p> $R$ is the time of division of bacteria, and so : $r=\frac{\ln(2)}{R}$.</p>
<p> $R$ is the time of division of bacteria, and so : $r=\frac{\ln(2)}{R}$.</p>
<p> $M$ is the time at which half of the KillerRed have matured, and so : $m=\frac{\ln(2)}{M}$ .</p>
<p> $M$ is the time at which half of the KillerRed have matured, and so : $m=\frac{\ln(2)}{M}$ .</p>
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<p> They are both actual times (in $min$) and make the figures easier to understand.</p>
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<p> $M$ and $R$ are both actual times (in $min$) and make the figures easier to understand.</p>
<p> In the table, $1-l$ appears, and not $l$ for $l$ has a huge effect on the previsions when $l\rightarrow1$. Turning it that way permits us to better control its variations, a variation of 1% of $l$ can make it exceed the value $1$, which becomes meaningless, whereas for $1-l$ even a variation of 10% does not make it exceed any limit value. </p>
<p> In the table, $1-l$ appears, and not $l$ for $l$ has a huge effect on the previsions when $l\rightarrow1$. Turning it that way permits us to better control its variations, a variation of 1% of $l$ can make it exceed the value $1$, which becomes meaningless, whereas for $1-l$ even a variation of 10% does not make it exceed any limit value. </p>

Revision as of 02:37, 3 October 2013

Grenoble-EMSE-LSU, iGEM


Grenoble-EMSE-LSU, iGEM

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