Respuesta :
Answer:
a) [tex] r = \frac{ln(2)}{210}=0.00330070086[/tex]
b) [tex] r = \frac{ln(2)}{N}[/tex]
Step-by-step explanation:
For this case we assume the followin differential equation:
[tex] \frac{dp}{dt}= rp[/tex]
Where is is the consttant growth/decay rate , p represent the population and the the time.
For this case we can rewrite this expression like this:
[tex] \frac{dp}{p}= rdt[/tex]
And now we can apply integrals on both sides like this:
[tex] \int \frac{dp}{p} r\int dt[/tex]
[tex] ln |p|= rt+C[/tex]
If we apply exponential on both sides we got:
[tex] p(t) = e^{rt} *e^c = p_o e^{rt}[/tex]
And from the previous equation [tex] p_o[/tex] represent the initial population.
Part a
For this case we are assuming that the population doubles in t=210 so then we can set the following equation:
[tex] 2p_o = p_o e^{210r}[/tex]
We can cancel [tex]p_o[/tex] in both sides and we got:
[tex] 2 = e^{210r}[/tex]
We can apply natural log on both sides and we got:
[tex] ln (2) = 210 r[/tex]
[tex] r = \frac{ln(2)}{210}=0.00330070086[/tex]
Part b
For this case we are assuming that the population doubles in t=N so then we can set the following equation:
[tex] 2p_o = p_o e^{Nr}[/tex]
We can cancel [tex]p_o[/tex] in both sides and we got:
[tex] 2 = e^{Nr}[/tex]
We can apply natural log on both sides and we got:
[tex] ln (2) = N r[/tex]
[tex] r = \frac{ln(2)}{N}[/tex]
