Answer:
The quantity of P(t) in the lake is [tex]Vr+(P-Vr)e^{-Ft/V}[/tex] litres where V is the amount of water in litres, r is the concentration of the flow in, P is the initial amount , F is the rate of flow in/out and t is time.
Step-by-step explanation:
The equation is given
Rate of Change of Amount=Flow Rate(in)*(Conc. of flow in)-Flow Rate(out)*(Conc. at any given time)
Here
Change of Amount is given P'(t)
Flow Rate(in) and Flow Rate(out) are given F
The conc. at any time is given P(t)/V
The conc. of the Flow in is given r
The initial concentration is given P
so the equation becomes
[tex]P'(t)=rF-\frac{P(t)}{V}F[/tex]
Now this equation in the standard form of the linear differential equation is as below and the integrating factor is
[tex]x'(t)=b+a(x)x(t)\\[/tex]
Here
[tex]a(x)=-\frac{F}{V}[/tex]
So integrating factor is
[tex]e^{Ft/V}[/tex]
Now the equation is
[tex]P(t)=e^{-Ft/V} \times \int{e^{F/V}Frdt} \\P(t)=e^{-Ft/V} \times[Fr\frac{V}{F}e^{Ft/V}+C]\\P(t)=Vr+Ce^{-Ft/V}[/tex]
As the initial condition is
As P(0)=P so by substituting this in the equation gives
[tex]P(t)=Vr+Ce^{-Ft/V}\\P(0)=Vr+Ce^{-F(0)/V}\\P=Vr+C\\C=P-Vr[/tex]
Putting this in the above differential equation
[tex]P(t)=Vr+Ce^{-Ft/V}\\P(t)=Vr+(P-Vr)e^{-Ft/V}[/tex]
So the amount P(t) in the lake is [tex]Vr+(P-Vr)e^{-Ft/V}[/tex] litres where V is the amount of water in litres, r is the concentration of the flow in, P is the initial amount, F is the rate of flow in/ out and t is time.
