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I had a few problems that I was stuck on:

1. Suppose a cell is suspended in a solution containing a solute of constant concentration Template:Math. Suppose further that the cell has constant volume Template:Math and that the area of its permeable membrane is the constant Template:Math. By Fick's law the rate of change of its mass Template:Math is directly proportional to the area Template:Math and the difference Template:Math, where Template:Math is the concentration of the solute inside the cell at time Template:Math. Find Template:Math if Template:Math and Template:Math. Use Template:Math as the proportionality constant.

Template:Math

2a. According to Stefan's law of radiation the absolute temperature T of a body cooling in a medium at constant absolute temperature Template:Math is given by Template:Math, where Template:Math is a constant. Stefan's law can be used over a greater temperature range than Newton's law of cooling. Solve the differential equation.

Template:Math

2b. Using the binomial series, expand the right side of the following equation. (Only write the first three terms of the expansion.)

Template:Math

Template:Math

Template:Math

Template:Math

3. A classical problem in the calculus of variations is to find the shape of a curve Template:Math such that a bead, under the influence of gravity, will slide from point Template:Math to point Template:Math in the least time. It can be shown that a nonlinear differential equation for the shape Template:Math of the path is Template:Math, where Template:Math is a constant. First solve for Template:Math in terms of Template:Math and Template:Math. Then use the substitution Template:Math to obtain a parametric form of the solution. The curve Template:Math turns out to be a cycloid.

Template:Math

For 1, I wrote Template:Math, but didn't know how to proceed from there.

For 2a, I tried separation of variables then factoring then partial fractions: Template:Hidden however, this answer was verified to be incorrect. I think I might have the wrong values for Template:Math, Template:Math, and Template:Math.

For 2b, I tried Template:Math and Template:Math, both of which were verified to be incorrect.

Any help would be appreciated. 147.126.10.148 (talk) 10:23, 13 October 2017 (UTC)

${\displaystyle -\frac{dT}{dt}=k(T^4-T_m^4)}$

Note the minus sign. The body is cooling when it is warmer than the surroundings. Choose your units of time and temperature such that the equation takes the form

${\displaystyle -\frac{dT}{dt}=T^4-1}$.

Use perturbation.

${\displaystyle -\frac{dT}{dt}=T^4-ϵ}$

${\displaystyle T(t,ϵ)\approx {\displaystyle \sum _{n=0}^{\mathrm{\infty }}}{T}_n(t){ϵ}^n}$ (as ${\displaystyle ϵ\to 0}$)

The first term in the perturbation series

${\displaystyle T_0(t)=\underset{ϵ\to 0}{\lim }T(t,ϵ)}$

satisfies the differential equation

${\displaystyle -\frac{d{T}_0}{dt}=T_0^4}$

${\displaystyle dt=-T_0^{-4}d{T}_0}$

Integrate

${\displaystyle t=3^{-1}{T}_0^{-3}+t_0}$

Let the beginning of time be ${\displaystyle t_0=0}$.

${\displaystyle t=3^{-1}{T}_0^{-3}}$

${\displaystyle T_0=(3t{)}^{-3^{-1}}}$

This is the cooling formula when the surrounding is at absolute zero.

Differentiate

${\displaystyle d{T}_0=d((3t{)}^{-3^{-1}})=3^{-3^{-1}}(-3^{-1})t^{-3^{-1}-1}dt=-3^{-3^{-1}4}{t}^{-3^{-1}4}dt}$

${\displaystyle =-(3^{-3^{-1}}{t}^{-3^{-1}}{)}^{4}dt=-T_0^{4}dt}$

checking that the differential equation ${\displaystyle d{T}_0=-T_0^{4}dt}$ is satisfied.

Insert the next term in the perturbation series

${\displaystyle T\approx T_0+T_1ϵ}$ (as ${\displaystyle ϵ\to 0}$)

into the differential equation

${\displaystyle -\frac{d(T_0+T_1ϵ)}{dt}=(T_0+T_1ϵ{)}^4-ϵ}$

and expand to the first power in ${\displaystyle ϵ}$

${\displaystyle -\frac{d{T}_0}{dt}-ϵ\frac{d{T}_1}{dt}=T_0^4+4T_0^3{T}_1ϵ-ϵ}$

The constant terms vanish and the rest is divided by ${\displaystyle ϵ}$

${\displaystyle -\frac{d{T}_1}{dt}=4T_0^3{T}_1-1}$

Inserting ${\displaystyle T_0^3=((3t{)}^{-3^{-1}}{)}^3=(3t{)}^{-1}=3^{-1}{t}^{-1}}$

${\displaystyle -\frac{d{T}_1}{dt}=\frac{4T_1}{3t}-1}$

or

${\displaystyle (\frac{d}{dt}+\frac{4}{3t})T_1=1}$

This is an inhomogenous Linear differential equation#First-order equation with variable coefficients.

The integrating factor is

${\displaystyle e^{\int \frac{4dt}{3t}}=e^{\frac{4}{3}\ln t}=t^{\frac{4}{3}}}$

and the differential equation becomes

${\displaystyle d(T_1{t}^{\frac{4}{3}})=t^{\frac{4}{3}}dt}$

integrate

${\displaystyle T_1{t}^{\frac{4}{3}}=\frac{3}{7}{t}^{\frac{7}{3}}+C}$

and divide

${\displaystyle T_1=\frac{3}{7}t+C{t}^{-\frac{4}{3}}}$

Bo Jacoby (talk) 12:24, 13 October 2017 (UTC).

(Bo, I don't know what you're doing here, but it's probably well beyond the scope of what's expected.) The original poster's attempt at separating variables, and then integrating via partial fraction decomposition is most likely what's intended. I'll point out that in general, when you have a term like ${\displaystyle \frac{1}{T^2+T_m^2},}$ the numerator needs to be ${\displaystyle AT+B,}$ not just ${\displaystyle B.}$ In this case, it happens to work out because ${\displaystyle A=0,}$ but it won't always be like that. Otherwise, it's just a matter of being more careful with your algebra, because I think you've got the basic idea right (and I'm not going to try to wade through all your work, sorry Template:Smiley). --Deacon Vorbis (talk) 15:35, 14 October 2017 (UTC)

Thank you! I expect that the differential equation is not solvable in terms of elementary functions. Most differential equations are not. So I tried to find an asymptotic expression. I think I failed. As ${\displaystyle t\to \mathrm{\infty }}$ you should get ${\displaystyle T\to 1}$ , and that is not what I got. I must have made mistakes. Bo Jacoby (talk) 18:51, 14 October 2017 (UTC).

The equation is ${\displaystyle -\frac{dT}{dt}=k(T^4-T_m^4)}$. Substituting ${\displaystyle T=T_{m}y}$ gives ${\displaystyle 3dy=-3k{T}_m^3(y^4-1)dt}$. (The factor 3 is for future convenience). Substituting ${\displaystyle x=3k{T}_m^{3}t}$ gives the dimensionless differential equation ${\displaystyle 3dy+y^{4}dx=dx}$. This is attacked by perturbation theory

${\displaystyle y\approx y_0+y_1ϵ+y_2{ϵ}^2+\cdots }$

satisfies

${\displaystyle 3dy+y^{4}dx=ϵdx}$

for ${\displaystyle ϵ\to 0}$. Equating coefficients:

${\displaystyle 3d{y}_0+y_0^{4}dx=0}$

${\displaystyle 3d{y}_1+4y_0^3{y}_{1}dx=dx}$

${\displaystyle 3d{y}_2+4y_0^3{y}_{2}dx+6y_0^2{y}_1^{2}dx=0}$

The solutions are

${\displaystyle y_0=x^{-3^{-1}}}$

${\displaystyle y_1=7^{-1}x+C_1{x}^{-3^{-1}4}}$

where ${\displaystyle C_1}$ is a constant of integration.

The next equation is

${\displaystyle 3d{y}_2+(4x^{-1}{y}_2+7^{-2}6x^{3^{-1}4}+6C^2{x}^{-3^{-1}10}+7^{-1}12C{x}^{-1})dx=0}$

Bo Jacoby (talk) 06:42, 15 October 2017 (UTC).

Forget all that nonsense. The integral is elementary: [1] Bo Jacoby (talk) 18:26, 19 October 2017 (UTC).