Is the Gradient of a Composite Function Always Zero?

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t_n_p
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Homework Statement



http://img21.imageshack.us/img21/8175/46521897.jpg

The Attempt at a Solution



I think I have a starting point, but I'm not 100% sure
Basically I thought of just computing grad(f(α(t)) · dα/dt and showing its equal to zero.

Am I on the right track, or shall I try another approach?
 
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hey tnp, i think you might want to start by taking the gradient of both sides of the original equation: grad(f(α(t)) = grad(c)

as the prove is an "if & only if", you might have to think about whether this proves both directions of the theorem, ie. "if" and "only if"
 
\cdotok, say I were to take grad of lhs, I need to apply chain rule since f(α(t))

so..

df/dt = (df/dα)(dα/dt)

I recognise (dα/dt) as [tex]\dot{\alpha}[/tex], which leads me to

df/dt = (df/dα)([tex]\dot{\alpha}[/tex])

Also, since [tex]\alpha[/tex] has components [tex]\alpha[/tex]1, [tex]\alpha[/tex]2, [tex]\alpha[/tex]3, ..., [tex]\alpha[/tex]n+1

df/dα = ([tex]\partial[/tex]f/d[tex]\alpha[/tex]1, [tex]\partial[/tex]f/d[tex]\alpha[/tex]2, ...,[tex]\partial[/tex]f/d[tex]\alpha[/tex]n+1) which I recognise is [tex]\nabla[/tex]f(α(t)),

this df/dt = [tex]\nabla[/tex]f(α(t)) [tex]\cdot[/tex] [tex]\dot{\alpha}[/tex] which is what I wanted.

I hope I'm correct up to here and it isn't too messy to show with the latex...o:)

But as you said before, the question states, if and only if, which means I have to show both ways. Puzzled as to how to do the reverse way...
 
can anybody help please? :P
 
Could you possibly provide me the name of the textbook?

Regards.