5.5 Triple integrals in cylindrical and spherical coordinates (Page 3/12)

Calculus volume 3 Page 3 / 12

Evaluate the triple integral $\int_{θ = 0}^{θ = π} \int_{r = 0}^{r = 1} \int_{z = 0}^{z = 4} r z sin θ r d z d r d θ .$

$8$

If the cylindrical region over which we have to integrate is a general solid, we look at the projections onto the coordinate planes. Hence the triple integral of a continuous function $f (r, θ, z)$ over a general solid region $E = {(r, θ, z) | (r, θ) \in D, u_{1} (r, θ) \leq z \leq u_{2} (r, θ)}$ in $ℝ^{3},$ where $D$ is the projection of $E$ onto the $r θ$ -plane, is

\underset{E}{∭} f (r, θ, z) r d r d θ d z = \iint_{D} [\int_{u_{1} (r, θ)}^{u_{2} (r, θ)} f (r, θ, z) d z] r d r d θ .

In particular, if $D = {(r, θ) | g_{1} (θ) \leq r \leq g_{2} (θ), α \leq θ \leq β},$ then we have

\underset{E}{∭} f (r, θ, z) r d r d θ = \int_{θ = α}^{θ = β} \int_{r = g_{1} (θ)}^{r = g_{2} (θ)} \int_{z = u_{1} (r, θ)}^{z = u_{2} (r, θ)} f (r, θ, z) r d z d r d θ .

Similar formulas exist for projections onto the other coordinate planes. We can use polar coordinates in those planes if necessary.

Setting up a triple integral in cylindrical coordinates over a general region

Consider the region $E$ inside the right circular cylinder with equation $r = 2 sin θ,$ bounded below by the $r θ$ -plane and bounded above by the sphere with radius $4$ centered at the origin ( [link] ). Set up a triple integral over this region with a function $f (r, θ, z)$ in cylindrical coordinates.

In polar coordinate space, a sphere of radius 4 is shown with equation r squared + z squared = 16 and center being the origin. There is also a cylinder described by r = 2 sin theta inside the sphere. — Setting up a triple integral in cylindrical coordinates over a cylindrical region.

First, identify that the equation for the sphere is $r^{2} + z^{2} = 16 .$ We can see that the limits for $z$ are from $0$ to $z = \sqrt{16 - r^{2}} .$ Then the limits for $r$ are from $0$ to $r = 2 sin θ .$ Finally, the limits for $θ$ are from $0$ to $π .$ Hence the region is

E = {(r, θ, z) | 0 \leq θ \leq π, 0 \leq r \leq 2 sin θ, 0 \leq z \leq \sqrt{16 - r^{2}}} .

Therefore, the triple integral is

\underset{E}{∭} f (r, θ, z) r d z d r d θ = \int_{θ = 0}^{θ = π} \int_{r = 0}^{r = 2 sin θ} \int_{z = 0}^{z = \sqrt{16 - r^{2}}} f (r, θ, z) r d z d r d θ .

Got questions? Get instant answers now!

Consider the region $E$ inside the right circular cylinder with equation $r = 2 sin θ,$ bounded below by the $r θ$ -plane and bounded above by $z = 4 - y .$ Set up a triple integral with a function $f (r, θ, z)$ in cylindrical coordinates.

$\underset{E}{∭} f (r, θ, z) r d z d r d θ = \int_{θ = 0}^{θ = π} \int_{r = 0}^{r = 2 sin θ} \int_{z = 0}^{z = 4 - r sin θ} f (r, θ, z) r d z d r d θ .$

Got questions? Get instant answers now!

Setting up a triple integral in two ways

Let $E$ be the region bounded below by the cone $z = \sqrt{x^{2} + y^{2}}$ and above by the paraboloid $z = 2 - x^{2} - y^{2} .$ ( [link] ). Set up a triple integral in cylindrical coordinates to find the volume of the region, using the following orders of integration:

$d z d r d θ$
$d r d z d θ .$

Setting up a triple integral in cylindrical coordinates over a conical region.

The cone is of radius 1 where it meets the paraboloid. Since $z = 2 - x^{2} - y^{2} = 2 - r^{2}$ and $z = \sqrt{x^{2} + y^{2}} = r$ (assuming $r$ is nonnegative), we have $2 - r^{2} = r .$ Solving, we have $r^{2} + r - 2 = (r + 2) (r - 1) = 0 .$ Since $r \geq 0,$ we have $r = 1 .$ Therefore $z = 1 .$ So the intersection of these two surfaces is a circle of radius $1$ in the plane $z = 1 .$ The cone is the lower bound for $z$ and the paraboloid is the upper bound. The projection of the region onto the $x y$ -plane is the circle of radius $1$ centered at the origin.
Thus, we can describe the region as

$E = {(r, θ, z) | 0 \leq θ \leq 2 π, 0 \leq r \leq 1, r \leq z \leq 2 - r^{2}} .$

Hence the integral for the volume is

$V = \int_{θ = 0}^{θ = 2 π} \int_{r = 0}^{r = 1} \int_{z = r}^{z = 2 - r^{2}} r d z d r d θ .$
We can also write the cone surface as $r = z$ and the paraboloid as $r^{2} = 2 - z .$ The lower bound for $r$ is zero, but the upper bound is sometimes the cone and the other times it is the paraboloid. The plane $z = 1$ divides the region into two regions. Then the region can be described as

$\begin{matrix} E & = {(r, θ, z) | 0 \leq θ \leq 2 π, 0 \leq z \leq 1, 0 \leq r \leq z} \\ \cup {(r, θ, z) | 0 \leq θ \leq 2 π, 1 \leq z \leq 2, 0 \leq r \leq \sqrt{2 - z}} . \end{matrix}$

Now the integral for the volume becomes

$V = \int_{θ = 0}^{θ = 2 π} \int_{z = 0}^{z = 1} \int_{r = 0}^{r = z} r d r d z d θ + \int_{θ = 0}^{θ = 2 π} \int_{z = 1}^{z = 2} \int_{r = 0}^{r = \sqrt{2 - z}} r d r d z d θ .$

Got questions? Get instant answers now!

<< Chapter < Page Page > Chapter >>

Practice Key Terms 2

Read also:

Get Jobilize Job Search Mobile App in your pocket Now!

100% Free Mobile Applications
Receive real-time job alerts and never miss the right job again

Source: OpenStax, Calculus volume 3. OpenStax CNX. Feb 05, 2016 Download for free at http://legacy.cnx.org/content/col11966/1.2

Google Play and the Google Play logo are trademarks of Google Inc.

Notification Switch

Would you like to follow the 'Calculus volume 3' conversation and receive update notifications?

Ask

	14 AP Key Terms 14 Brain Cranial Nerves By OpenStax Start Key Terms
©flickr:	Core Java Unit Test-1(CAJ003) By Abishek Devaraj Start Quiz
	Fundamentals of electrical engineering i By OpenStax Read Online Course
	3 CDL Quiz - General Knowledge Part 1 By Jazzycazz Jackson Start Quiz
	Business Statistics By David Bourgeois Start Quiz
	16 AP 16 Neurological MCQ Exam By OpenStax Start Quiz
	Principles of economics By OpenStax Read Online Course
	5 BOD Reproductive System quiz By Brooke Delaney Start Quiz
	Vocabulary Week 1-3 By Rachel Woolard Start Quiz
	Evolutionary Biology Ecology By Olivia D'Ambrogio Start Quiz