In this problem we are being asked to integrate the function.

In order to do this we need to remember,

.

Since 

then the integral,

.

This problem is asking us to integrate the function.

In order to do this we need to remember,

.

Therefore,

We are asked to set up an integral without solving it. We want to evaluate the function from 3 to 13, so 3 goes at the bottom of the integral and 13 goes at the top. No other options have this correct.

Recall that area under the curve requires integration from either top minus bottom curve, or right minus left curve.

The top curve is: 

The bottom curve is: 

The  interval indicates that the lower bound is 2 and the upper bound is 5.

Write the integral.

This is a tricky question.   

If we chose , the region in the third quadrant of  is negative area, since  is no longer the top curve.  Evaluating this integral will cancel out the negative area in the third quadrant with the positive area on the first quadrant.  This integral will give zero area, which is incorrect.

The correct method is to split this interval into 2 separate integrations:  One from  and the other from .

From interval , the top curve is  minus the bottom curve, ,  is .

From interval , the top curve is  minus the bottom curve, , is .

Set up the integral.

To find the area under a curve, we usually want to use an integral. All of our answer choices are integrals though, so this doesn't narrow things down. Then next thing to look for are our limits of integration. In this case, we are on the interval [360,540], so look for an option that has the lower limit of integration as 360 and the higher limit as 540. Only one option has this:

For further clarification, to set up an integral, we want our function within the integral and our limits of integration on the integral sign itself. Once we have the correct integral set up, we can evaluate it to find the area under the curve.

The region bounded by the three functions represents a triangle.  It will be easier to determine the bounded region by subtracting the left curve from the right curve, and using  to integrate.  In order to integrate in terms of , any equation in terms of  must be rewritten in terms of .

Isolate .

Find the intersection of the lines  and .

The correct bounds are from .  Write the correct integral.

There are two steps to evaluating a definite integral. The first step is finding the anti-derivative of the function that we are integrating. In this problem, we are integrating the function , and the anti-derivative of this function is . (To check that your anti-derivative is correct, derive it. If you do not arrive back at the original function, go back and find where you may have made a mistake). 

The second step is evaluating the anti-derivative at the given endpoints, and subtracting the second from the first. To do this, we look at the two endpoints, or "limits of integration," and decide which is higher. In this case, the two limits are  and , and so we first evaluate the anti-derivative at . So, we get . Next, we evaluate at , and get , and subtracting this from the first value, we get .

First, in order to find the zeros of the function, we need to use the quadratic formula.

In our case,

.

These will be the lower and upper bounds of the integral.  

Set up the integral in terms of .

To find the volume, it is necessary to find the area of the disk, which is:

The radius is , since the function is rotated about the x-axis.

The volume is the antiderivative of the area.

The lower and upper bounds are defined by  and .  

Complete the integral.