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Section 15.4 : Double Integrals in Polar Coordinates

2. Evaluate \(\displaystyle \iint\limits_{D}{{\sqrt {1 + 4{x^2} + 4{y^2}} \,dA}}\) where \(D\) is the bottom half of \({x^2} + {y^2} = 16\).

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Below is a quick sketch of the region \(D\).

For double integrals in which polar coordinates are going to be used the sketch of \(D\) is often not as useful as for a general region.

However, if nothing else, it does make it clear that polar coordinates will be needed for this problem. Describing this region in terms of Cartesian coordinates is possible but one of the limits will involve roots which often (not always, but often) leads to messy integral work.

The sketch shows that the region is at least partially circular and that should always indicate that polar coordinates are not a bad thing to at least think about. In this case, because of the Cartesian limits as discussed above polar coordinates are pretty much the only easy way to do this integral. Also note that this integral would be unpleasant in terms of Cartesian coordinates. Hopefully the polar form will be easier to do.

Note as well that once we have the sketch determining the polar limits should be pretty simple.

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Okay, \(D\) is just a portion of a disk and so setting up the limits shouldn’t be too difficult. Here they are,

\[\begin{array}{c}\pi \le \theta \le 2\pi \\ \,0 \le r \le 4\end{array}\] Show Step 3

The integral in terms of polar coordinates is then,

\[\begin{align*}\iint\limits_{D}{{\sqrt {1 + 4{x^2} + 4{y^2}} \,dA}} & = \int_{\pi }^{{2\pi }}{{\int_{0}^{4}{{\left( {\sqrt {1 + 4\left( {{x^2} + {y^2}} \right)} } \right)\,r\,dr}}\,d\theta }}\\ & = \int_{\pi }^{{2\pi }}{{\int_{0}^{4}{{r\sqrt {1 + 4{r^2}} \,dr}}\,d\theta }}\end{align*}\]

When converting the integral don’t forget to convert the \(x\) and \(y\) into polar coordinates. In this case don’t just substitute the polar conversion formulas in for \(x\) and \(y\)! Recall that \({x^2} + {y^2} = {r^2}\) and the integral will be significantly easier to deal with.

Also, don’t forget that \(dA = r\,dr\,d\theta \) and so we’ll pickup an extra \(r\) in the integrand. Forgetting the extra \(r\) is one of the most common mistakes with these kinds of problems and in this case without the extra \(r\) we’d have a much more unpleasant integral to deal with.

Show Step 4

Here is the \(r\) integration.

\[\begin{align*}\iint\limits_{D}{{\sqrt {1 + 4{x^2} + 4{y^2}} \,dA}} & = \int_{\pi }^{{2\pi }}{{\int_{0}^{4}{{r\sqrt {1 + 4{r^2}} \,dr}}\,d\theta }}\\ & = \int_{\pi }^{{2\pi }}{{\left. {\left( {\frac{1}{{12}}{{\left( {1 + 4{r^2}} \right)}^{\frac{3}{2}}}} \right)} \right|_0^4\,d\theta }}\\ & = \int_{\pi }^{{2\pi }}{{\frac{1}{{12}}\left( {{{65}^{\frac{3}{2}}} - 1} \right)\,d\theta }}\end{align*}\] Show Step 5

Finally, here is the \(\theta \) integration.

\[\begin{align*}\iint\limits_{D}{{\sqrt {1 + 4{x^2} + 4{y^2}} \,dA}} & = \int_{\pi }^{{2\pi }}{{\frac{1}{{12}}\left( {{{65}^{\frac{3}{2}}} - 1} \right)\,d\theta }}\\ & = \left. {\left( {\frac{1}{{12}}\left( {{{65}^{\frac{3}{2}}} - 1} \right)\theta } \right)} \right|_\pi ^{2\pi } = \require{bbox} \bbox[2pt,border:1px solid black]{{\frac{1}{{12}}\pi \left( {{{65}^{\frac{3}{2}}} - 1} \right) = 136.9333}}\end{align*}\]

Note that while this was a really simple integral to evaluate you’ll be seeing a fair amount of \({\cos ^2}\theta \), \({\sin ^2}\theta \) and \(\sin \theta \cos \theta \) terms in polar integrals so make sure that you know how to integrate these terms!