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I am currently working on understanding this problem and am in need of some assistance. I'll let you know what I've done so far, and then hopefully someone will be able to help me.

So the problem is as follows:

Give a parametrization to the ellipse $\frac{x^2}{a^2} + \frac{y^2}{b^2}$ = 1, a,b > 0 and write down the range of your parameter. Then use this parametrization to find the area this ellipse encloses.

Alright so I believe I've gotten the correct parametrization with the following

x = a cos t

y = b sin t

And the formula for the area is: $\int y dx$

The only thing I'm stuck on is how to find the correct range of parameters and how to evaluate the integral. I believe there is some sort of trick to figuring out the integral because if you try to evaluate it normally the top will cancel the bottom and you'll end up with zero.

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    @user28694 The integral doesn't cancel out. See my answer. Can you show us the integral you attempted? Perhaps you made a mistake.2012-04-29

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One way to calculate the area is to use the integral $\int y \,dx$ when $x$ changes from $-a$ to $a$. This corresponds to $t$ changing from $\pi$ to $0$ and results in the area of the upper half. For both halves, multiply by $2$:

\begin{align*} \mathcal{A} &= 2 \int_{\pi}^{0} (b\sin{t}) (-a\sin{t}) \,dt \\ &= 2ab \int_{\pi}^{0} -\sin^2{t} \,dt \\ &= 2ab \int_{\pi}^{0} \left(-\frac{1}{2} + \frac{1}{2}\cos(2t)\right) \,dt \\ &= 2ab \left[-\frac{t}{2} + \frac{1}{4}\sin(2t) \right]_{\pi}^{0} \\ &= \pi ab \end{align*}

You'll get the same result if you integrate $-\int y \,dx$ for $t \in [0, 2\pi]$. See Green's Theorem for justification.