Sketch the region bounded by the curves y=9x3,y=9 and x=0 then find the volume of the solid generated by revolving this region about the x-axis.
Accepted Solution
A:
volumes of revolution are so fun lets say you have 2 functions f(x) and g(x) where they intersect at c and d where c<d, and f(x) is on top of g(x) (like for a value r where c<r<d, f(r)>g(r)), the volume is [tex] \pi \int\limits^d_c {f(x)^2-g(x)^2} \, dx [/tex]
ok, so find the intersection points of [tex]y=9x^3[/tex] and y=9
9=9x^3 1=x^3 at x=1
so then the area will be from x=0 to x=1 which ones's higher? try x=0.5 at x=0.5, 9(0.5)^3<9 so the y=9 is on top therfor
limits are from 0 to 1 higher one is y=9 bottom function is y=9x^3 so the volume is [tex] \pi \int\limits^1_0 {(9)^2-(9x^3)^2} \, dx =[/tex] [tex] \pi \int\limits^1_0 {81-81x^6} \, dx =[/tex] we can factor out the 81 [tex] \pi \int\limits^1_0 {81(1-x^6)} \, dx =[/tex] factor out the constant [tex] 81 \pi \int\limits^1_0 {1-x^6} \, dx =[/tex] integrate [tex]81 \pi [x-\frac{1}{7}x^7]^1_0=[/tex] [tex]81 \pi [(1-\frac{1}{7}(1)^7)-(0-\frac{1}{7}(0)^7)]=[/tex] [tex]81 \pi (1-\frac{1}{7}-0)=[/tex] [tex]81 \pi -\frac{81}{7}[/tex]
the area is [tex]81 \pi-\frac{81}{7}[/tex] square units