Answer:
[tex]V=61.66[/tex]
Step-by-step explanation:
This problem can be solved by using the expression for the Volume of a solid with the washer method
[tex]V=\pi \int \limit_a^b[R(x)^2-r(x)^2]dx[/tex]
where R and r are the functions f and g respectively (f for the upper bound of the region and r for the lower bound).
Before we have to compute the limits of the integral. We can do that by taking f=g, that is
[tex]f(x)=g(x)\\ln(x)=\frac{1}{2}x-2[/tex]
there are two point of intersection (that have been calculated with a software program as Wolfram alpha, because there is no way to solve analiticaly)
x1=0.14
x2=8.21
and because the revolution is around y=-5 we have
[tex]R=ln(x)-(-5)\\r=\frac{1}{2}x-2-(-5)\\[/tex]
and by replacing in the integral we have
[tex]V=\pi \int \limit_{x1}^{x2}[(lnx+5)^2-(\frac{1}{2}x+3)^2]dx\\[/tex]
[tex]V=\pi [28x+\frac{1}{x}+xln^2x-12xlnx-6lnx][/tex]
and by evaluating in the limits we have
[tex]V=61.66[/tex]
Hope this helps
regards
