To get the coefficient on the trig function notice that we need to turn the 25 into a 13 once we’ve substituted the trig function in for \(x\) and squared the substitution out. With that in mind it looks like the substitution should be,

\[x = \frac{{\sqrt {13} }}{5}\tan \left( \theta \right)\]

Now, all we have to do is actually perform the substitution and eliminate the root.

Show Step 3

\[\begin{align*}\sqrt {13 + 25{x^2}} & = \sqrt {13 + 25{{\left( {\frac{{\sqrt {13} }}{5}\tan \left( \theta \right)} \right)}^2}} = \sqrt {13 + 25\left( {\frac{{13}}{{25}}} \right){{\tan }^2}\left( \theta \right)} \\ & = \sqrt {13 + 13{{\tan }^2}\left( \theta \right)} = \sqrt {13} \sqrt {1 + {{\tan }^2}\left( \theta \right)} \\ & = \sqrt {13} \sqrt {{{\sec }^2}\left( \theta \right)} = \require{bbox} \bbox[2pt,border:1px solid black]{{\sqrt {13} \left| {\sec \left( \theta \right)} \right|}}\end{align*}\]

Note that because we don’t know the values of \(\theta \) we can’t determine if the secant is positive or negative and so cannot get rid of the absolute value bars here.