Scaling the Heat Equation to Standard Form

Somefantastik · May 29, 2008

I don't understand where to even start with this problem. This book has ZERO examples. I would appreciate some help.

Show that by a suitable scaling of the space coordinates, the heat equation

[tex]u_{t}=\kappa\left(u_{xx}+u_{yy}+u_{zz}\right)[/tex]

can be reduced to the standard form

[tex]v_{t} = \Delta v [/tex] where u becomes v after scaling. [tex]\Delta [/tex] is the Laplacian operator

Mute · May 29, 2008

What you want to do is scale the spatial variables such that (using vector notation) [itex]\mathbf{r} \rightarrow \alpha \mathbf{r}[/itex]. Basically, using the problem's notation, you define the function v such that

[tex]u(x,y,z,t) = v(\alpha x, \alpha y, \alpha z,t)[/tex]

To proceed from there, plug that into your equation for u and use the chain rule to figure out what [itex]\alpha[/itex] should be in terms of [itex]\kappa[/itex] to get the pure laplacian.

Scaling the Heat Equation to Standard Form

1. What is the heat equation and why is it important in science?

2. What does it mean to scale the heat equation to standard form?

3. How is the heat equation scaled to standard form?

4. What are the benefits of scaling the heat equation to standard form?

5. Are there any limitations to scaling the heat equation to standard form?

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