How do you use the intermediate value theorem to explain why $f(x)=-4/x+tan((pix)/8)$ has a zero in the interval [1,3]?

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Answer 1 · 2016-11-30T07:33:12

See explanation...

Given:

$f(x) = -4/x+tan((pix)/8)$

Note that:

The function $-4/x$ has a vertical asymptote at $x=0$ , but is otherwise defined and continuous. So is defined and continuous on $[1, 3]$
The function $tan theta$ is defined for all $theta in (-pi/2, pi/2)$ , including all $theta in [pi/8, (3pi)/8]$ , and is continous in that interval.

Hence $f(x)$ is defined and continuous over the interval $x in [1, 3]$

We find:

$f(1) = -4/1+tan(pi/8) = -4+(sqrt(2)-1) = sqrt(2)-5 < 0$

$f(3) = -4/3+tan((3pi)/8) = -4/3+(sqrt(2)+1) = sqrt(2)-1/3 > 0$

In summary:

So by the intermediate value theorem, $f(x)$ takes every value between $f(1) = sqrt(2)-5 < 0$ and $f(3) = sqrt(2)-1/3 > 0$ for some $x in [1, 3]$ .

In particular, there is some value $a in [1, 3]$ such that $f(a) = 0$

graph{((x-1)^2+(y-sqrt(2)+5)^2-0.01)((x-3)^2+(y-sqrt(2)+1/3)^2-0.01)(y+4/x-tan((pix)/8)) = 0 [-8.94, 11.06, -6.24, 3.76]}

How do you use the intermediate value theorem to explain why f(x)=-4/x+tan((pix)/8)f(x)=-4/x+tan((pix)/8) has a zero in the interval [1,3]?