{"id":433,"date":"2025-02-13T19:44:53","date_gmt":"2025-02-13T19:44:53","guid":{"rendered":"https:\/\/content.one.lumenlearning.com\/calculus2\/chapter\/determining-volumes-by-slicing-learn-it-3\/"},"modified":"2025-02-13T19:44:53","modified_gmt":"2025-02-13T19:44:53","slug":"determining-volumes-by-slicing-learn-it-3","status":"publish","type":"chapter","link":"https:\/\/content.one.lumenlearning.com\/calculus2\/chapter\/determining-volumes-by-slicing-learn-it-3\/","title":{"raw":"Determining Volumes by Slicing: Learn It 3","rendered":"Determining Volumes by Slicing: Learn It 3"},"content":{"raw":"\n

The Disk Method<\/h2>\n

When we use the slicing method with solids of revolution, it is often called the disk method<\/strong> because, for solids of revolution, the slices used to over approximate the volume of the solid are disks.<\/p>\n

To see this, consider the solid of revolution generated by revolving the region between the graph of the function [latex]f(x)={(x-1)}^{2}+1[\/latex] and the [latex]x\\text{-axis}[\/latex] over the interval [latex]\\left[-1,3\\right][\/latex] around the [latex]x\\text{-axis}\\text{.}[\/latex] <\/p>\n\n[caption id=\"\" align=\"aligncenter\" width=\"899\"]\"This Figure 9. (a) A thin rectangle for approximating the area under a curve. (b) A representative disk formed by revolving the rectangle about the [latex]x\\text{-axis}\\text{.}[\/latex] (c) The region under the curve is revolved about the [latex]x\\text{-axis},[\/latex] resulting in (d) the solid of revolution.[\/caption]\n\n

We already used the formal Riemann sum development of the volume formula when we developed the slicing method. We know that<\/p>\n

[latex]V={\\displaystyle\\int }_{a}^{b}A(x)dx[\/latex]<\/div>\n

The only difference with the disk method is that we know the formula for the cross-sectional area ahead of time; it is the area of a circle. <\/p>\n

\n

the disk method<\/h3>\n

Let [latex]f(x)[\/latex] be continuous and nonnegative.<\/p>\n

 <\/p>\n

Define [latex]R[\/latex] as the region bounded above by the graph of [latex]f(x),[\/latex] below by the [latex]x\\text{-axis,}[\/latex] on the left by the line [latex]x=a,[\/latex] and on the right by the line [latex]x=b.[\/latex]<\/p>\n

 <\/p>\n

Then, the volume of the solid of revolution formed by revolving [latex]R[\/latex] around the [latex]x\\text{-axis}[\/latex] is given by:<\/p>\n

[latex]V={\\displaystyle\\int }_{a}^{b}\\pi {\\left[f(x)\\right]}^{2}dx.[\/latex]<\/div>\n<\/section>\n

Returning to our example, the volume is given by:<\/p>\n

[latex]\\begin{array}{cc}\\hfill V& ={\\displaystyle\\int }_{a}^{b}\\pi {\\left[f(x)\\right]}^{2}dx\\hfill \\\\ & ={\\displaystyle\\int }_{-1}^{3}\\pi {\\left[{(x-1)}^{2}+1\\right]}^{2}dx=\\pi {\\displaystyle\\int }_{-1}^{3}{\\left[{(x-1)}^{4}+2{(x-1)}^{2}+1\\right]}^{2}dx\\hfill \\\\ & =\\pi {\\left[\\frac{1}{5}{(x-1)}^{5}+\\frac{2}{3}{(x-1)}^{3}+x\\right]|}_{-1}^{3}=\\pi \\left[(\\frac{32}{5}+\\frac{16}{3}+3)-(-\\frac{32}{5}-\\frac{16}{3}-1)\\right]=\\frac{412\\pi }{15}{\\text{units}}^{3}.\\hfill \\end{array}[\/latex]<\/div>\n

 <\/p>\n

\n

Use the disk method to find the volume of the solid of revolution generated by rotating the region between the graph of [latex]f(x)=\\sqrt{x}[\/latex] and the [latex]x\\text{-axis}[\/latex] over the interval [latex]\\left[1,4\\right][\/latex] around the [latex]x\\text{-axis}\\text{.}[\/latex]<\/p>\n\n[reveal-answer q=\"fs-id1167793419916\"]Show Solution[\/reveal-answer]
\n[hidden-answer a=\"fs-id1167793419916\"]\n\n

The graphs of the function and the solid of revolution are shown in the following figure.<\/p>\n\n[caption id=\"\" align=\"aligncenter\" width=\"740\"]\"This Figure 10. (a) The function [latex]f(x)=\\sqrt{x}[\/latex] over the interval [latex]\\left[1,4\\right].[\/latex] (b) The solid of revolution obtained by revolving the region under the graph of [latex]f(x)[\/latex] about the [latex]x\\text{-axis}.[\/latex][\/caption]\n\n

We have<\/p>\n

[latex]\\begin{array}{cc}\\hfill V& ={\\displaystyle\\int }_{a}^{b}\\pi {\\left[f(x)\\right]}^{2}dx\\hfill \\\\ & ={\\displaystyle\\int }_{1}^{4}\\pi {\\left[\\sqrt{x}\\right]}^{2}dx=\\pi {\\displaystyle\\int }_{1}^{4}xdx\\hfill \\\\ & ={\\frac{\\pi }{2}{x}^{2}|}_{1}^{4}=\\frac{15\\pi }{2}.\\hfill \\end{array}[\/latex]<\/div>\n

The volume is [latex]\\frac{(15\\pi )}{2}[\/latex] units3<\/sup>.<\/p>\n

[\/hidden-answer]<\/p>\n<\/section>\n

So far, our examples have all concerned regions revolved around the [latex]x\\text{-axis,}[\/latex] but we can generate a solid of revolution by revolving a plane region around any horizontal or vertical line.<\/p>\n

\n

the disk method for solids of revolution around the [latex]y[\/latex]-axis<\/h3>\n

Let [latex]g(y)[\/latex] be continuous and nonnegative.<\/p>\n

 <\/p>\n

Define [latex]Q[\/latex] as the region bounded on the right by the graph of [latex]g(y),[\/latex] on the left by the [latex]y\\text{-axis,}[\/latex] below by the line [latex]y=c,[\/latex] and above by the line [latex]y=d.[\/latex]<\/p>\n

 <\/p>\n

Then, the volume of the solid of revolution formed by revolving [latex]Q[\/latex] around the [latex]y\\text{-axis}[\/latex] is given by:<\/p>\n

[latex]V={\\displaystyle\\int }_{c}^{d}\\pi {\\left[g(y)\\right]}^{2}dy.[\/latex]<\/div>\n<\/section>\n

In the next example, we look at a solid of revolution that has been generated by revolving a region around the [latex]y\\text{-axis}\\text{.}[\/latex] The mechanics of the disk method are nearly the same as when the [latex]x\\text{-axis}[\/latex] is the axis of revolution, but we express the function in terms of [latex]y[\/latex] and we integrate with respect to [latex]y[\/latex] as well. <\/p>\n

\n

Let [latex]R[\/latex] be the region bounded by the graph of [latex]g(y)=\\sqrt{4-y}[\/latex] and the [latex]y\\text{-axis}[\/latex] over the [latex]y\\text{-axis}[\/latex] interval [latex]\\left[0,4\\right].[\/latex] Use the disk method to find the volume of the solid of revolution generated by rotating [latex]R[\/latex] around the [latex]y\\text{-axis}\\text{.}[\/latex]<\/p>\n\n[reveal-answer q=\"fs-id1167793368748\"]Show Solution[\/reveal-answer]
\n[hidden-answer a=\"fs-id1167793368748\"]\n\n

Figure 11 shows the function and a representative disk that can be used to estimate the volume. Notice that since we are revolving the function around the [latex]y\\text{-axis,}[\/latex] the disks are horizontal, rather than vertical.<\/p>\n\n[caption id=\"\" align=\"aligncenter\" width=\"740\"]\"This Figure 11. (a) Shown is a thin rectangle between the curve of the function [latex]g(y)=\\sqrt{4-y}[\/latex] and the [latex]y\\text{-axis}\\text{.}[\/latex] (b) The rectangle forms a representative disk after revolution around the [latex]y\\text{-axis}\\text{.}[\/latex][\/caption]\n\n

The region to be revolved and the full solid of revolution are depicted in the following figure.<\/p>\n\n[caption id=\"\" align=\"aligncenter\" width=\"740\"]\"This Figure 12. (a) The region to the left of the function [latex]g(y)=\\sqrt{4-y}[\/latex] over the [latex]y\\text{-axis}[\/latex] interval [latex]\\left[0,4\\right].[\/latex] (b) The solid of revolution formed by revolving the region about the [latex]y\\text{-axis}\\text{.}[\/latex][\/caption]\n\n

To find the volume, we integrate with respect to [latex]y.[\/latex] We obtain<\/p>\n

[latex]\\begin{array}{cc}\\hfill V& ={\\displaystyle\\int }_{c}^{d}\\pi {\\left[g(y)\\right]}^{2}dy\\hfill \\\\ & ={\\displaystyle\\int }_{0}^{4}\\pi {\\left[\\sqrt{4-y}\\right]}^{2}dy=\\pi {\\displaystyle\\int }_{0}^{4}(4-y)dy\\hfill \\\\ & ={\\pi \\left[4y-\\frac{{y}^{2}}{2}\\right]|}_{0}^{4}=8\\pi .\\hfill \\end{array}[\/latex]<\/div>\n

 <\/p>\n

The volume is [latex]8\\pi [\/latex] units3<\/sup>.<\/p>\n

[\/hidden-answer]<\/p>\n<\/section>\n

\n

[ohm_question hide_question_numbers=1]20075[\/ohm_question]<\/p>\n<\/section>\n","rendered":"

The Disk Method<\/h2>\n

When we use the slicing method with solids of revolution, it is often called the disk method<\/strong> because, for solids of revolution, the slices used to over approximate the volume of the solid are disks.<\/p>\n

To see this, consider the solid of revolution generated by revolving the region between the graph of the function [latex]f(x)={(x-1)}^{2}+1[\/latex] and the [latex]x\\text{-axis}[\/latex] over the interval [latex]\\left[-1,3\\right][\/latex] around the [latex]x\\text{-axis}\\text{.}[\/latex] <\/p>\n

\"This
Figure 9. (a) A thin rectangle for approximating the area under a curve. (b) A representative disk formed by revolving the rectangle about the [latex]x\\text{-axis}\\text{.}[\/latex] (c) The region under the curve is revolved about the [latex]x\\text{-axis},[\/latex] resulting in (d) the solid of revolution.<\/figcaption><\/figure>\n

We already used the formal Riemann sum development of the volume formula when we developed the slicing method. We know that<\/p>\n

[latex]V={\\displaystyle\\int }_{a}^{b}A(x)dx[\/latex]<\/div>\n

The only difference with the disk method is that we know the formula for the cross-sectional area ahead of time; it is the area of a circle. <\/p>\n

\n

the disk method<\/h3>\n

Let [latex]f(x)[\/latex] be continuous and nonnegative.<\/p>\n

 <\/p>\n

Define [latex]R[\/latex] as the region bounded above by the graph of [latex]f(x),[\/latex] below by the [latex]x\\text{-axis,}[\/latex] on the left by the line [latex]x=a,[\/latex] and on the right by the line [latex]x=b.[\/latex]<\/p>\n

 <\/p>\n

Then, the volume of the solid of revolution formed by revolving [latex]R[\/latex] around the [latex]x\\text{-axis}[\/latex] is given by:<\/p>\n

[latex]V={\\displaystyle\\int }_{a}^{b}\\pi {\\left[f(x)\\right]}^{2}dx.[\/latex]<\/div>\n<\/section>\n

Returning to our example, the volume is given by:<\/p>\n

[latex]\\begin{array}{cc}\\hfill V& ={\\displaystyle\\int }_{a}^{b}\\pi {\\left[f(x)\\right]}^{2}dx\\hfill \\\\ & ={\\displaystyle\\int }_{-1}^{3}\\pi {\\left[{(x-1)}^{2}+1\\right]}^{2}dx=\\pi {\\displaystyle\\int }_{-1}^{3}{\\left[{(x-1)}^{4}+2{(x-1)}^{2}+1\\right]}^{2}dx\\hfill \\\\ & =\\pi {\\left[\\frac{1}{5}{(x-1)}^{5}+\\frac{2}{3}{(x-1)}^{3}+x\\right]|}_{-1}^{3}=\\pi \\left[(\\frac{32}{5}+\\frac{16}{3}+3)-(-\\frac{32}{5}-\\frac{16}{3}-1)\\right]=\\frac{412\\pi }{15}{\\text{units}}^{3}.\\hfill \\end{array}[\/latex]<\/div>\n

 <\/p>\n

\n

Use the disk method to find the volume of the solid of revolution generated by rotating the region between the graph of [latex]f(x)=\\sqrt{x}[\/latex] and the [latex]x\\text{-axis}[\/latex] over the interval [latex]\\left[1,4\\right][\/latex] around the [latex]x\\text{-axis}\\text{.}[\/latex]<\/p>\n