Here is the differential work for the substitution.

\[du = 4{x^3}\,dx\hspace{0.25in} \to \hspace{0.25in}\,{x^3}dx = \frac{1}{4}du\]

Before doing the actual substitution it might be convenient to factor an \({x^3}\) out of the integrand as follows.

\[\int{{7{x^3}\cos \left( {2 + {x^4}} \right) - 8{x^3}{{\bf{e}}^{2 + {x^{\,4}}}}\,dx}} = \int{{\left[ {7\cos \left( {2 + {x^4}} \right) - 8{{\bf{e}}^{2 + {x^{\,4}}}}} \right]{x^3}dx}}\]

Doing this should make the differential part (i.e. the \(du\) part) of the substitution clearer.

Now, doing the substitution and evaluating the integral gives,

\[\begin{align*}\int{{7{x^3}\cos \left( {2 + {x^4}} \right) - 8{x^3}{{\bf{e}}^{2 + {x^{\,4}}}}\,dx}} &= \frac{1}{4}\int{{7\cos \left( u \right) - 8{{\bf{e}}^u}du}}\\ & = \frac{1}{4}\left[ {7\sin \left( u \right) - 8{{\bf{e}}^u}} \right] + c = \require{bbox} \bbox[2pt,border:1px solid black]{{\frac{1}{4}\left[ {7\sin \left( {2 + {x^4}} \right) - 8{{\bf{e}}^{2 + {x^{\,4}}}}} \right] + c}}\end{align*}\]

Be careful when dealing with the \(dx\) substitution here. Make sure that the \(\frac{1}{4}\) gets multiplied times the whole integrand and not just one of the terms. You can do this either by using parenthesis around the whole integrand or pulling the \(\frac{1}{4}\) completely out of the integral (as we’ve done here).

Do not forget to go back to the original variable after evaluating the integral!