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A round shaped athletic track (centre in a point C) has a radius of $50.0$ $mts$. An athlete runs around the track and a referee is going to time from a starting point A. If the athlete is in a point B, 'how fast does the area of the triangle ABC increases when the central angle is $\pi/4$?

I started by stating that $h=r\sin \alpha$ and $b=r$

Then I said that $A={r^2 \over 2}\sin \alpha$

Implicitly deriving...

${dA \over dt}={r^2 \over 2} \cos \alpha {d\alpha \over dt}$ Replacing:

${dA \over dt}=625 \sqrt2 {d\alpha \over dt}$

But I don't know how to get ${d\alpha \over dt}$? I even tried $l=r*\alpha$

${dl \over dt} = r{d\alpha \over dt}$

And then replacing again:

${dA \over dt}={25 \over 2} \sqrt2 {dl \over dt}$

But then again I have no way out of there.

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You can’t really say more than ${dA \over dt}=625 \sqrt2 ~\frac{d\alpha}{dt}\tag{1}$ unless you have some information on the runner’s speed. The most you can do is rewrite $(1)$ directly in terms of his speed. If he’s running at a speed of $v$ metres per second, then $v=r\frac{d\alpha}{dt}=50\frac{d\alpha}{dt}\;,$ and $\frac{dA}{dt}=\frac{625\sqrt2}{50}v=\frac{25\sqrt2 v}2\;.\tag{2}$ Although they say essentially the same thing, I slightly prefer $(2)$ to $(1)$, since linear units are a little more familiar in this context than angular units.

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    @ChairOTP: Because it’s true. The arc of the circle that subtends an angle $\alpha$ has length $r\alpha$, and $v$ is the rate of change of that length.2012-11-13