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Hi! I'm almost finished with a homework problem, but I cannot quite finish it. The problem is as follows:

Given the Gompertz growth equation $\frac{dN}{dt}=K(t)N(t),\ N(0)=N_0 \\ \frac{dK}{dt}=-\alpha K(t),\ K(0)=\beta,$ I shall first determined a closed-form expression, which will be $K(t)=\beta e^{-\alpha t}$ and $\frac{dN}{dt}=\beta e^{-\alpha t} N(t) \Leftrightarrow \\ \int\frac{1}{N(t)}dN=\int \beta e^{-\alpha t}dt \Leftrightarrow \\ \log[N(t)]=\frac{-\beta}{\alpha} e^{-\alpha t} + C \Leftrightarrow \\ N(t)=\exp\left( \frac{-\beta}{\alpha}e^{-\alpha t}\right) \frac{N_0}{\exp\left(\frac{-\beta}{\alpha}\right)};$ the last factor is due to the initial condition.

Then: Determine the limit $B:=\lim_{t\rightarrow \infty}N(t), $ it will be $B=\frac{N_0}{\exp\left(\frac{-\alpha}{\beta}\right)}$ (right?)

Then: Show that this is equivalent to $\frac{dN}{dt}=\alpha N \log\frac{B}{N},$ I also managed that (the LHS is $KN$, then solve the logarithm), but THEN:

For the cases $N_0>B, N_0 , determine $\lim_{t\rightarrow -\infty }N(t)$. If I plug in $t=-\infty$ into $N(t)$, then I get just $0$. Or not? And with my solution for $B$, I get $\exp\left( \frac{-\beta}{\alpha}\right)<> 1$, but since $\alpha, \beta >0$, the exp cannot be smaller than one?

I either have a blonde moment, or my solutions are wrong, but magically the equivalence in the $\log$-equation works! Can someone defuse my brain? :)

-marie

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    So... does that mean that the question is wrong? :/2012-05-08

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