7.1 Integration By Parts/50: Difference between revisions

Prove ${\displaystyle \int _{}^{}\sec ^{n}(x)dx={\frac {\tan(x)\cdot \sec ^{n-2}(x)}{n-1}}+{\frac {n-2}{n-1}}\int _{}^{}\sec ^{n-2}(x)dx}$

${\displaystyle \int _{}^{}\sec ^{n}(x)dx=\int _{}^{}\sec ^{2}(x)\cdot \sec ^{n-2}(x)dx}$

${\displaystyle {\begin{aligned}&u=\sec ^{n-2}(x)\quad &dv=\sec ^{2}(x)dx\\[2ex]&du=(n-2)\sec ^{n-3}\cdot \sec(x)\tan(x)dx\quad &v=\tan(x)\\[2ex]\end{aligned}}}$

${\displaystyle {\begin{aligned}\int _{}^{}\sec ^{2}(x)\cdot \sec ^{n-2}(x)dx&=\sec ^{n-2}(x)\cdot \tan(x)-\int _{}^{}\left[(n-2)\sec ^{n-3}(x)\cdot \sec(x)\tan(x)\right]\cdot \tan(x)dx\\[2ex]&=\sec ^{n-2}(x)\cdot \tan(x)-(n-2)\int _{}^{}\left[\sec ^{n-2}(x)\cdot \tan ^{2}(x)\right]dx\\[2ex]&=\sec ^{n-2}(x)\cdot \tan(x)-(n-2)\int _{}^{}\sec ^{n-2}(x)\cdot [\sec ^{2}(x)-1]dx\\[2ex]&=\sec ^{n-2}(x)\cdot \tan(x)-(n-2)\int _{}^{}\left[\sec ^{n}(x)-\sec ^{n-2}(x)\right]dx\\[2ex]\end{aligned}}}$

${\displaystyle {\begin{aligned}\int _{}^{}\sec ^{n}(x)dx=\sec ^{n-2}(x)\cdot \tan(x)-(n-2)\int _{}^{}\sec ^{n}(x)dx+(n-2)\int _{}^{}\sec ^{n-2}(x)dx\end{aligned}}}$

${\displaystyle {\begin{aligned}&+(n-2)\int _{}^{}\sec ^{2}(x)dx\quad &&&+(n-2)\int _{}^{}\sec ^{2}(x)dx\end{aligned}}}$

Failed to parse (unknown function "\begin{align}"): {\displaystyle \begin{align} = \frac{\sec^{n-2}(x)\tan(x)} \end{align} }