We are given that a cylindrical tank with volume 300L is leaking from a hole in the bottom at a rate that is proportional to the remaining volume. We are given that after one day, 19L has leaked out.
Let t be the time in days, let V(t) be the volume in liters at time t. Then V(0)=300 and V(1)=281. The rate of change of the volume, (dV)/(dt) , is proportional to the remaining volume so (dV)/(dt)=ksqrt(V) where k is the constant of proportionality. This differential equation is separable so we rewrite as: (dV)/sqrt(V)=kdt . Integrating both sides we get:
2V^(1/2)=kt+C_1 " or " V^(1/2)=k/2 t + C where C is the constant of integration.
V(0)=300 so C=sqrt(300)=10sqrt(3)
V(1)=281 so sqrt(281)=k/2(1)+10sqrt(3) ==> k~~-1.115
Thus V^(1/2) =-.557t+10sqrt(3)
(a) The time when the volume will be 1/2 the original volume:
sqrt(150)=-.557t+10sqrt(3) ==> t~~9.1
(b) How much remains after three days? t=3 so
sqrt(V)=-.557(3)+10sqrt(3) ==> V~~244.91"L"
A graph of the model with time as the independent variable and volume the dependent variable.
http://mathworld.wolfram.com/DifferentialEquation.html
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