washer method

variables can be separated on opposite sides of the equation. This will help us visualize what we’re dealing with and will make it easier to come up with the function we’ll need to integrate later.

That a skill that may come in handy at some point. In both cases, the outer radius R is the distance from the axis of rotation to the All I will do here is plug these functions into Desmos, but see if you can graph these without the help of a calculator. Let’s take a minute to consider the dimensions of this particular washer. Notice that the outer radius and inner radius are finite, but the thickness We discuss convergence results for geometric series and telescoping series. In order to find the volume of a washer we will also need it’s height. All I will do here is plug these functions into Desmos, but see if you can graph these without the help of a calculator. We compute surface area of a frustrum then use the method of “Slice, Approximate, To find this distance we simply need to find the difference between their x-values because they will always have the same y-coordinate. We define a solid of revolution and discuss how to find the volume of one in two distances, so we can compute both by taking y_{top}-y_{bot}. We approximate the slice in the region by a rectangle. Vectors are lists of numbers that denote direction and magnitude. We draw a slice of thickness \Delta y at a fixed, but unspecified y-value on the region of $$V= \pi \int_0^1 4 – 4y \ dy$$ $$V= \pi \bigg[ 4y – 2y^2 \bigg]_0^1$$ $$V= \pi \bigg[ \Big( 4(1) – 2(1)^2 \Big) – \Big( 4(0) – 2(0)^2 \Big) \bigg]$$ $$V=\pi(4-2)$$ $$V=2 \pi$$. Your email address will not be published. rotation. The height of our infinitely thin washers is actually quite simple. curves. rectangle.

You are about to erase your work on this activity. We see from the picture that both R and r are verticalhorizontal revolution perpendicular to the axis of revolution, and we approximate each slice by a All we need to do now is evaluate the volume integral by finding the anti-derivative and evaluating the bounds.

will certainly depend at which y-value they are drawn, but to make the notation x.

Take a look at the drawing below. In the drawing above, this is shown in the smaller washer off to the side as the distance between the points labeled $(0, \ y)$ and $(x, \ y)$. All we need in this case is the power rule for integration. of the slice. r=0), it is sometimes referred to as a disk. integration. to compute volumes. I will do this using Wolfram Alpha. we could generate the solid of revolution by considering the corresponding slices in This is an important difference because adding up the volume of all of these washers will require us to move vertically throughout this figure to get the next washer and add its volume to the total. Step 2: Approximate Here, we have explicitly noted that these radii Regardless, your record of completion will remain. Projections tell us how much of one vector lies in the direction of another and are So the volume of this solid is $2 \pi$ cubic units! Finding the outer radius will be very similar to finding the inner radius. cleaner the rest of the way, we will only write R and r instead of R(y) and r(y). We could solve this problem using the cylinder method as well, but that’s for another lesson. The cross product is a special way to multiply two vectors in three-dimensional We discuss an approach that allows us to integrate rational functions. This will help us visualize what we’re dealing with and will make it easier to come up with the function we’ll need to integrate later. The two curves are parabolic in shape.

V= \int _{y=0}^{y=5} \pi (y+3) \d y Evaluating this integral gives that the total volume is \answer [given]{\frac {55}{2}\pi }. Use the Washer Method to set up an integral that gives the volume of the solid of revolution when is revolved about the following line. The result of rotating the slice appears on the solid just as before. There is an updated version of this activity. I encourage you to imagine this happening on your page and try drawing a rough sketch of the resulting figure. This gives R= \answer [given]{4-y^2} and r= \answer [given]{4-2}. recall, The outer cylinder has radius R(y) and its volume is \Delta V_{outer} = \pi [R(y)]^2 \Delta y, while the volume of the inner Some infinite series can be compared to geometric series. important in physical applications. You should also check out my other lessons and problems about integrals. Below you can see the graph of and and you can see the area that is bounded by these two functions. Step 1: Slice the volume of the solid of revolution is given by. A series is an infinite sum of the terms of sequence. . We can use substitution and trigonometric identities to find antiderivatives of certain

Alternating series are series whose terms alternate in sign between positive and Visualizing each step required to create the 3-D figure we’re looking for will make things a lot easier when we come up with the function that we need to integrate. In this case, the positive square root is the right half of the parabola and the negative square root represents the left half.

Each slice has a hole in … In order to do this we will need to think about how we can write x in terms of y. Since the bottom y-values lie on the axis of rotation y=-1, R= \answer [given]{\sqrt {x}-(-1)} and r= \answer [given]{0-(-1)}. Thus, the volume integral to be evaluated is. Calculus Calculus help and alternative explainations. Power series interact nicely with other calculus concepts. Built at The Ohio State UniversityOSU with support from NSF Grant DUE-1245433, the Shuttleworth Foundation, the Department of Mathematics, and the Affordable Learning ExchangeALX. All of the graphing and sketching is to help us visualize what is being described so we can correctly formulate our integral. First, note that we slice the region of outer curve and the inner radius r is the distance from the axis of rotation to We must now find the limits of integration and express \Delta y is thought of as quite small. information. This is the figure whose volume we need to find. This is the distinction between absolute and conditional convergence, Since we move in the y direction to get to the next washer, we need to integrate with respect to y. We compare infinite series to each other using limits. take the same region and revolve it about different lines. The y will be different depending on which washer we’re looking at, but since it lies on the y-axis we know that the x-coordinate will always be 0. To solve this problem, I’m going to use the same 4 step process as I did in my disk method lesson and my first washer method practice problem.

negative.

us to do this, and we may write. These must be expressed with respect to the variable of Find the volume obtained by rotating the region bounded by $y=\frac{1}{4} x^2,$ $x=2,$ and $y=0$ about the y-axis. The y-coordinate changes depending on which washer we are looking at in our figure, but these two points will have the same y-coordinate when they are on the same washer. We use the procedure of “Slice, Approximate, Integrate” to develop the washer $$V= \pi \int_0^1 4 – 4y \ dy$$, Now we’ve gotten through the hard part. (i.e. There is one key difference this time around: here we are rotating the region around a vertical line. method to compute volumes of solids of revolution. motivating example.

The volume of For this example, we will proceed using the washer method. Just like before, I’ll do this using Wolfram Alpha. We know that any point that lies on the line $x=2$ will have an x-coordinate of 2. Remember we also found the inner radius, outer radius, and height of the washers that make up our figure to be $$r=\sqrt{4y},$$ $$R=2,$$ $$h=dy.$$, Putting all of this into an integral along with the fact that this figure goes across all y-values between 0 and 1, give us $$V= \int_0^1 \pi (dy) \bigg( (2)^2 – \Big(\sqrt{4y}\Big)^2 \bigg).$$, Of course, this looks a little strange.

The dot product is an important operation between vectors that captures geometric They meet at (0,0) and (1,1), so the interval of integration is [0,1]. $$y=\frac{1}{4}x^2$$ $$4y=x^2$$ $$\pm \sqrt{4y}=x$$ Notice, in general when we take the square root of both sides of the equation we need the positive and negative square root. © 2013–2020, The Ohio State University — Ximera team, 100 Math Tower, 231 West 18th Avenue, Columbus OH, 43210–1174. Since they have the same y-value, to find the distance between them, we just need to find the distance between their x-coordinates. $(x, \ y)$ is some point that lies on the function $y=\frac{1}{4}x^2$. The limits of integration are: c = \answer [given]{0} and d = \answer [given]{\sqrt {2}}. Find the volume traced out by the region between the curves and y = x 2, when the region i rotated about the x-axis. If an infinite sum converges, then its terms must tend to zero. To illustrate the details, we start with a We can approximate sufficiently differentiable functions by polynomials. volume of the solid of revolution is given by, If slices taken perpendicular to the axis of revolution are horizontal, then Therefore, when we create our integral, it will all need to be in terms of y rather than x. A solid of revolution is formed by revolving this region about the y-axis. We use the procedure of “Slice, Approximate, Integrate” to develop the shell method situations. So we can simply say the height of each cylinder is $$h=dy.$$, Like I said before, all the integral will do is go through all the y values that our figure covers and add up the volumes of all of the infinitely thin washers. Although the y-coordinate changes as we move up the side of our figure, the x-coordinate stays equal to 2. V= \int _{y=\answer [given]{0}}^{y=\answer [given]{\sqrt {2}}} \answer [given]{\pi \left [(4-y^2)^2-(2)^2\right ]}\d y.