Let’s first use the substitution to eliminate the root.

\[\sqrt {{y^2} - 25} = \sqrt {25{{\sec }^2}\left( \theta \right) - 25} = 5\sqrt {{{\tan }^2}\left( \theta \right)} = 5\left| {\tan \left( \theta \right)} \right|\] Show Step 3

Okay, in this case we have limits on \(y\) and so we can get limits on \(\theta \) that will allow us to determine if tangent is positive or negative to allow us to eliminate the absolute value bars.

So, let’s get some limits on \(\theta \).

\[\begin{align*}y & = - 7:\,\,\, - 7 = 5\sec \left( \theta \right)\hspace{0.25in} \to \hspace{0.25in}\sec \left( \theta \right) = - \frac{7}{5}\hspace{0.25in} \to \hspace{0.25in}\theta = {\sec ^{ - 1}}\left( { - \frac{7}{5}} \right) = 2.3664\\ y & = - 5:\,\,\,\, - 5 = 5\sec \left( \theta \right)\hspace{0.25in} \to \hspace{0.25in}\sec \left( \theta \right) = - 1\hspace{0.25in} \to \hspace{0.25in}\theta = \pi \end{align*}\]

So, \(\theta \)’s for this problem are in the range \(2.3664 \le \theta \le \pi \) and these are in the second quadrant. In the second quadrant we know that tangent is negative and so we can drop the absolute value bars provided we add in a minus sign. This gives,

\[\sqrt {{y^2} - 25} = - 5\tan \left( \theta \right)\]

For a final substitution preparation step let’s also compute the differential so we don’t forget to use that in the substitution!

\[dy = 5\sec \left( \theta \right)\tan \left( \theta \right)\,d\theta \] Show Step 4

Now let’s do the actual substitution.

\[\begin{align*}\int_{{ - 7}}^{{ - 5}}{{\frac{2}{{{y^4}\sqrt {{y^2} - 25} }}\,dy}} & = \int_{{2.3664}}^{\pi }{{\frac{2}{{{5^4}{{\sec }^4}\left( \theta \right)\left( { - 5\tan \left( \theta \right)} \right)}}\,\left( {5\sec \left( \theta \right)\tan \left( \theta \right)} \right)d\theta }}\\ & = - \frac{2}{{625}}\int_{{2.3664}}^{\pi }{{\frac{1}{{{{\sec }^3}\left( \theta \right)}}\,d\theta }}\end{align*}\]

Do not forget to substitute in the differential we computed in the previous step. This is probably the most common mistake with trig substitutions. Forgetting the differential can substantially change the problem, often making the integral very difficult to evaluate.

Also notice that upon doing the substation we replaced the \(y\) limits with the \(\theta \) limits. This will help with a later step.

Show Step 5

We now need to evaluate the integral. In terms of secants this integral would be pretty difficult, however we a quick change to cosines we get the following integral.

\[\int_{{ - 7}}^{{ - 5}}{{\frac{2}{{{y^4}\sqrt {{y^2} - 25} }}\,dy}} = - \frac{2}{{625}}\int_{{2.3664}}^{\pi }{{{{\cos }^3}\left( \theta \right)\,d\theta }}\]

This should be relatively simple to do so here is the integration work.

\[\begin{align*}\int_{{ - 7}}^{{ - 5}}{{\frac{2}{{{y^4}\sqrt {{y^2} - 25} }}\,dy}} & = - \frac{2}{{625}}\int_{{2.3664}}^{\pi }{{\left( {1 - {{\sin }^2}\left( \theta \right)} \right)\cos \left( \theta \right)\,d\theta }}\hspace{0.25in}u = \sin \left( \theta \right)\\ & = - \frac{2}{{625}}\int_{{\sin \left( {2.3664} \right)}}^{{\sin \left( \pi \right)}}{{1 - {u^2}\,du}}\\ & = - \frac{2}{{625}}\left. {\left[ {u - \frac{1}{3}{u^3}} \right]} \right|_{0.69986}^0 = \require{bbox} \bbox[2pt,border:1px solid black]{{0.001874}}\end{align*}\]

Don’t forget all the “standard” manipulations of the integrand that we often need to do in order to evaluate integrals involving trig functions. If you don’t recall them you’ll need to go back to the previous section and work some practice problems to get good at them.

Every trig substitution problem reduces down to an integral involving trig functions and the majority of them will need some manipulation of the integrand in order to evaluate.

Also, note that because we converted the limits at every substitution into limits for the “new” variable we did not need to do any back substitution work on our answer!