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Double Integrals In Polar Coordinates | Calculus - Mathematics PDF Download

To this point we’ve seen quite a few double integrals. However, in every case we’ve seen to this point the region D could be easily described in terms of simple functions in Cartesian coordinates. In this section we want to look at some regions that are much easier to describe in terms of polar coordinates. For instance, we might have a region that is a disk, ring, or a portion of a disk or ring. In these cases, using Cartesian coordinates could be somewhat cumbersome. For instance, let’s suppose we wanted to do the following integral,
Double Integrals In Polar Coordinates | Calculus - Mathematics
To this we would have to determine a set of inequalities for x and y that describe this region. These would be,
Double Integrals In Polar Coordinates | Calculus - Mathematics
With these limits the integral would become,
Double Integrals In Polar Coordinates | Calculus - Mathematics
Due to the limits on the inner integral this is liable to be an unpleasant integral to compute. However, a disk of radius 2 can be defined in polar coordinates by the following inequalities,
Double Integrals In Polar Coordinates | Calculus - Mathematics
These are very simple limits and, in fact, are constant limits of integration which almost always makes integrals somewhat easier. So, if we could convert our double integral formula into one involving polar coordinates we would be in pretty good shape. The problem is that we can’t just convert the dx and the dy into a dr and a dθ. In computing double integrals to this point we have been using the fact that dA=dxdy and this really does require Cartesian coordinates to use. Once we’ve moved into polar coordinates dA≠drdθ and so we’re going to need to determine just what dA is under polar coordinates. So, let’s step back a little bit and start off with a general region in terms of polar coordinates and see what we can do with that. Here is a sketch of some region using polar coordinates.
Double Integrals In Polar Coordinates | Calculus - Mathematics
So, our general region will be defined by inequalities,
Double Integrals In Polar Coordinates | Calculus - Mathematics
Now, to find dA let’s redo the figure above as follows,
Double Integrals In Polar Coordinates | Calculus - Mathematics
As shown, we’ll break up the region into a mesh of radial lines and arcs. Now, if we pull one of the pieces of the mesh out as shown we have something that is almost, but not quite a rectangle. The area of this piece is Δ A . The two sides of this piece both have length Δ r = r− ri where r o is the radius of the outer arc and ri is the radius of the inner arc. Basic geometry then tells us that the length of the inner edge is ri Δθ while the length of the out edge is ro Δθ where Δ θ is the angle between the two radial lines that form the sides of this piece.
Now, let’s assume that we’ve taken the mesh so small that we can assume that ri ≈ ro = r and with this assumption we can also assume that our piece is close enough to a rectangle that we can also then assume that,
ΔA ≈ r Δθ Δr
Also, if we assume that the mesh is small enough then we can also assume that,
dAΔAdθΔθdrΔr 
With these assumptions we then get dA≈rdrdθ.
In order to arrive at this we had to make the assumption that the mesh was very small. This is not an unreasonable assumption. Recall that the definition of a double integral is in terms of two limits and as limits go to infinity the mesh size of the region will get smaller and smaller. In fact, as the mesh size gets smaller and smaller the formula above becomes more and more accurate and so we can say that,
dA=rdrdθ
We’ll see another way of deriving this once we reach the Change of Variables section later in this chapter. This second way will not involve any assumptions either and so it maybe a little better way of deriving this. Before moving on it is again important to note that d A ≠ d r d θ . The actual formula for dA has an r in it. It will be easy to forget this r on occasion, but as you’ll see without it some integrals will not be possible to do. Now, if we’re going to be converting an integral in Cartesian coordinates into an integral in polar coordinates we are going to have to make sure that we’ve also converted all the x ’s and y ’s into polar coordinates as well. To do this we’ll need to remember the following conversion formulas,
x = rcos θ, y = r sin θ, r2 = x2 + y2 
We are now ready to write down a formula for the double integral in terms of polar coordinates.
Double Integrals In Polar Coordinates | Calculus - Mathematics
It is important to not forget the added r and don’t forget to convert the Cartesian coordinates in the function over to polar coordinates.
Let’s look at a couple of examples of these kinds of integrals.
Example 1 Evaluate the following integrals by converting them into polar coordinates.
(a) Double Integrals In Polar Coordinates | Calculus - MathematicsD  is the portion of the region between the circles of radius 2 and radius 5 centered at the origin that lies in the first quadrant.
(b)Double Integrals In Polar Coordinates | Calculus - Mathematics
D is the unit disk centered at the origin. 
(a) Double Integrals In Polar Coordinates | Calculus - Mathematicsis the portion of the region between the circles of radius 2 and radius 5 centered at the origin that lies in the first quadrant. 
Solution: First let’s get D in terms of polar coordinates. The circle of radius 2 is given by r = 2 and the circle of radius 5 is given by r = 5 . We want the region between the two circles, so we will have the following inequality for r. Double Integrals In Polar Coordinates | Calculus - Mathematics.
Also, since we only want the portion that is in the first quadrant we get the following range of θ’s.
Double Integrals In Polar Coordinates | Calculus - Mathematics
Now that we’ve got these we can do the integral.
Double Integrals In Polar Coordinates | Calculus - Mathematics
Don’t forget to do the conversions and to add in the extra r. Now, let’s simplify and make use of the double angle formula for sine to make the integral a little easier.
Double Integrals In Polar Coordinates | Calculus - Mathematics

(b) Double Integrals In Polar Coordinates | Calculus - Mathematicsis the unit disk centered at the origin.
Solution: In this case we can’t do this integral in terms of Cartesian coordinates. We will however be able to do it in polar coordinates. First, the region D is defined by, Double Integrals In Polar Coordinates | Calculus - Mathematics 
In terms of polar coordinates the integral is then, Double Integrals In Polar Coordinates | Calculus - Mathematics
Notice that the addition of the r gives us an integral that we can now do. Here is the work for this integral. 
Double Integrals In Polar Coordinates | Calculus - Mathematics
Let’s not forget that we still have the two geometric interpretations for these integrals as well.
Example 2 Determine the area of the region that lies inside r=3+2sinθr=3+2sin⁡θ and outside r=2r=2.
Solution: Here is a sketch of the region, D, that we want to determine the area of.
Double Integrals In Polar Coordinates | Calculus - Mathematics
To determine this area we’ll need to know that value of θ for which the two curves intersect. We can determine these points by setting the two equations equal and solving.Double Integrals In Polar Coordinates | Calculus - Mathematics
Here is a sketch of the figure with these angles added.
Double Integrals In Polar Coordinates | Calculus - Mathematics
Note as well that we’ve acknowledged that − π/6 is another representation for the angle 11 π/6 . This is important since we need the range of θ to actually enclose the regions as we increase from the lower limit to the upper limit. If we’d chosen to use 11 π 6 then as we increase from 7 π/6 to 11 π/6 we would be tracing out the lower portion of the circle and that is not the region that we are after. So, here are the ranges that will define the region.
Double Integrals In Polar Coordinates | Calculus - Mathematics
To get the ranges for r  the function that is closest to the origin is the lower bound and the function that is farthest from the origin is the upper bound. The area of the region D is then,
Double Integrals In Polar Coordinates | Calculus - Mathematics
Example 3 Determine the volume of the region that lies under the sphere x2+y2+z2=9x2+y2+z2=9, above the plane z=0 and inside the cylinder x2+y2=5x2+y2=5.
Solution: We know that the formula for finding the volume of a region is,
Double Integrals In Polar Coordinates | Calculus - Mathematics
In order to make use of this formula we’re going to need to determine the function that we should be integrating and the region D that we’re going to be integrating over. The function isn’t too bad. It’s just the sphere, however, we do need it to be in the form z = f ( x , y ) . We are looking at the region that lies under the sphere and above the plane z = 0 (just the x y -plane right?) and so all we need to do is solve the equation for z and when taking the square root we’ll take the positive one since we are wanting the region above the x y -plane. Here is the function.
Double Integrals In Polar Coordinates | Calculus - Mathematics
The region D isn’t too bad in this case either. As we take points, ( x , y ) , from the region we need to completely graph the portion of the sphere that we are working with. Since we only want the portion of the sphere that actually lies inside the cylinder given by x2 + y2 = 5 this is also the region D . The region D is the disk x2 + y2 ≤ 5 in the x y -plane.
For reference purposes here is a sketch of the region that we are trying to find the volume of.

Double Integrals In Polar Coordinates | Calculus - Mathematics   Double Integrals In Polar Coordinates | Calculus - Mathematics
So, the region that we want the volume for is really a cylinder with a cap that comes from the sphere.
We are definitely going to want to do this integral in terms of polar coordinates so here are the limits (in polar coordinates) for the region,
Double Integrals In Polar Coordinates | Calculus - Mathematics
and we’ll need to convert the function to polar coordinates as well.
Double Integrals In Polar Coordinates | Calculus - Mathematics
The volume is then, 
Double Integrals In Polar Coordinates | Calculus - Mathematics
Example 4 Find the volume of the region that lies inside z=x2+y2z=x2+y2 and below the plane z=16z=16.
Solution: Let’s start this example off with a quick sketch of the region. 
Double Integrals In Polar Coordinates | Calculus - Mathematics Double Integrals In Polar Coordinates | Calculus - Mathematics
Now, in this case the standard formula is not going to work. The formula
Double Integrals In Polar Coordinates | Calculus - Mathematics
finds the volume under the function f(x,y) and we’re actually after the area that is above a function. This isn’t the problem that it might appear to be however. First, notice that
Double Integrals In Polar Coordinates | Calculus - Mathematics
will be the volume under z=16 (of course we’ll need to determine D eventually) whileDouble Integrals In Polar Coordinates | Calculus - Mathematics
is the volume under z = x 2 + y 2 , using the same D . The volume that we’re after is really the difference between these two or,
Double Integrals In Polar Coordinates | Calculus - Mathematics
Now all that we need to do is to determine the region D and then convert everything over to polar coordinates. Determining the region D in this case is not too bad. If we were to look straight down the z -axis onto the region we would see a circle of radius 4 centered at the origin. This is because the top of the region, where the elliptic paraboloid intersects the plane, is the widest part of the region. We know the z coordinate at the intersection so, setting z = 16 in the equation of the paraboloid gives,
16 = x2 + y2
which is the equation of a circle of radius 4 centered at the origin.
Here are the inequalities for the region and the function we’ll be integrating in terms of polar coordinates. Double Integrals In Polar Coordinates | Calculus - Mathematics
The volume is then,
 Double Integrals In Polar Coordinates | Calculus - Mathematics
In both of the previous volume problems we would have not been able to easily compute the volume without first converting to polar coordinates so, as these examples show, it is a good idea to always remember polar coordinates. There is one more type of example that we need to look at before moving on to the next section. Sometimes we are given an iterated integral that is already in terms of x and y and we need to convert this over to polar so that we can actually do the integral. We need to see an example of how to do this kind of conversion.
Example 5 Evaluate the following integral by first converting to polar coordinates.
Double Integrals In Polar Coordinates | Calculus - Mathematics
Solution: First, notice that we cannot do this integral in Cartesian coordinates and so converting to polar coordinates may be the only option we have for actually doing the integral. Notice that the function will convert to polar coordinates nicely and so shouldn’t be a problem.
Let’s first determine the region that we’re integrating over and see if it’s a region that can be easily converted into polar coordinates. Here are the inequalities that define the region in terms of Cartesian coordinates.
Double Integrals In Polar Coordinates | Calculus - Mathematics
Now, the lower limit for the y’s is, 
Double Integrals In Polar Coordinates | Calculus - Mathematics
and this looks like the bottom of the circle of radius 1 centered at the origin. Since the upper limit for the y ’s is y = 0 we won’t have any portion of the top half of the disk and so it looks like we are going to have a portion (or all) of the bottom of the disk of radius 1 centered at the origin.
The range for the x ’s in turn, tells us that we are will in fact have the complete bottom part of the disk. So, we know that the inequalities that will define this region in terms of polar coordinates are then, Double Integrals In Polar Coordinates | Calculus - Mathematics
Finally, we just need to remember that, dxdy=dA=rdrdθ
and so the integral becomes, Double Integrals In Polar Coordinates | Calculus - Mathematics
Note that this is an integral that we can do. So, here is the rest of the work for this integral.
Double Integrals In Polar Coordinates | Calculus - Mathematics

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FAQs on Double Integrals In Polar Coordinates - Calculus - Mathematics

1. What is the concept of double integrals in polar coordinates?
Ans. Double integrals in polar coordinates are a mathematical tool used to calculate the area of regions in the plane that cannot be easily expressed in Cartesian coordinates. It involves integrating a function over a two-dimensional region defined in terms of polar coordinates, which consists of a radius and an angle.
2. How do you convert a double integral from Cartesian to polar coordinates?
Ans. To convert a double integral from Cartesian to polar coordinates, we use the following steps: 1. Express the limits of integration in terms of polar coordinates. The inner integral limits will be in terms of the radius, and the outer integral limits will be in terms of the angle. 2. Replace the differential area element dA in the integral with the corresponding area element in polar coordinates, which is r dr dθ. 3. Substitute the Cartesian variables x and y with their corresponding polar forms, x = r cosθ and y = r sinθ. 4. Simplify the integrand and perform the integration using the polar limits of integration.
3. What are the advantages of using polar coordinates in double integrals?
Ans. Using polar coordinates in double integrals offers several advantages: 1. Simplified region description: Many regions have simpler descriptions in polar coordinates compared to Cartesian coordinates. For example, circles become simple equations like r = a, where 'a' represents the radius. This simplification makes it easier to set up the limits of integration. 2. Symmetry exploitation: Polar coordinates are particularly useful when the region being integrated over has a high degree of symmetry, such as circular or annular regions. The symmetry can be effectively exploited to simplify the integrals and reduce computation. 3. Application to physical problems: Many physical problems, such as those involving circular objects or radial symmetry, naturally lend themselves to polar coordinates. Using polar coordinates allows for a more intuitive and physical interpretation of the integrals.
4. Can any double integral be expressed in polar coordinates?
Ans. Not all double integrals can be easily expressed in polar coordinates. The suitability of polar coordinates depends on the region of integration and the nature of the integrand. Certain regions, such as those with irregular shapes or non-circular boundaries, may require more complex transformations or a combination of coordinate systems to express the integral in polar coordinates. Additionally, some integrands may not have a simple representation in terms of polar coordinates, making it necessary to stick with Cartesian coordinates for evaluation.
5. How do you determine the limits of integration in polar coordinates for a given region?
Ans. Determining the limits of integration in polar coordinates for a given region typically involves analyzing the boundaries of the region. Here are some common approaches: 1. Identify polar curves: Determine the equations of the curves that define the boundaries of the region. These curves may be simple polar curves or combinations of multiple curves. 2. Find the angles: Determine the angle values (θ) at which the curves intersect or change. These angles will help define the limits of integration for the outer integral. 3. Determine the radii: For each angle, find the corresponding radius values (r) at which the curves intersect or change. These radii will help define the limits of integration for the inner integral. 4. Set up the limits: Use the determined angles and radii to set up the limits of integration for the double integral in polar coordinates, ensuring that the angles and radii cover the entire region of interest.
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