From Mr. V Wiki Math
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| <math> | | <math> |
| \begin{align} | | \begin{align} |
| &u = \sec^{n-2}(x) \quad dv= \sec^{2}(x)dx \\[2ex] | | &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] | | &du = (n-2)\sec^{n-3} \cdot \sec(x) \tan(x) dx \quad &v= \tan(x) \\[2ex] |
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| \end{align} | | \end{align} |
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| \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] | | \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] |
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| &= 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_{}^{} \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_{}^{} \sec^{n-2}(x) \cdot [\sec^{2}(x)-1]dx \\[2ex] |
| &= x \ln(x)^{n} - n \int_{}^{} \left(\ln(x)^{n-1} \right)dx \\[2ex] | | &= \sec^{n-2}(x) \cdot \tan(x) - (n-2)\int_{}^{} \left[\sec^{n}(x) - \sec^{n-2}(x)\right]dx \\[2ex] |
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| \end{align} | | \end{align} |
| </math> | | </math> |
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| sec^{n-2}(x) \cdot \tan(x) - (n-2)\int_{}^{} \left[\sec^{n-2}(x) \cdot [\sec^{2}(x)-1]dx | | <math> |
| | \begin{align} |
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| | \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 |
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| | \end{align} |
| | </math> |
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| | <math> |
| | \begin{align} |
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| | &+(n-2)\int_{}^{} \sec^{2}(x)dx \quad &&&+(n-2)\int_{}^{} \sec^{2}(x)dx |
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| | \end{align} |
| | </math> |
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| | <math> |
| | \begin{align} |
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| | (n-1)\int_{}^{} \sec^{n}(x)dx= \sec^{2}(x)\tan(x) + (n-2) \int_{}^{} \sec^{n-2}(x)dx \\[2ex] |
| | &= \frac{\sec^{n-2}(x) \tan(x)}{n-1} + \frac{n-2}{n-1} \int_{}^{} \sec^{n-2}(x)dx \\[2ex] |
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| | \end{align} |
| | </math> |
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| | Note: |
| | <math> |
| | \begin{align} |
| | \tan^{2}(x) = \sec^{2}(x)-1 |
| | \end{align} |
| | </math> |
Latest revision as of 04:07, 30 November 2022
Prove
![{\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}}}](https://en.wikipedia.org/api/rest_v1/media/math/render/svg/1bbaa23d087901210ac3879be94d74f996c6e66f)
![{\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}}}](https://en.wikipedia.org/api/rest_v1/media/math/render/svg/3e4c14df7c27f2941c922da234e913467ed18598)
![{\displaystyle {\begin{aligned}(n-1)\int _{}^{}\sec ^{n}(x)dx=\sec ^{2}(x)\tan(x)+(n-2)\int _{}^{}\sec ^{n-2}(x)dx\\[2ex]&={\frac {\sec ^{n-2}(x)\tan(x)}{n-1}}+{\frac {n-2}{n-1}}\int _{}^{}\sec ^{n-2}(x)dx\\[2ex]\end{aligned}}}](https://en.wikipedia.org/api/rest_v1/media/math/render/svg/21baf05554e78b307f9be6eba7a4dde7077d559a)
Note:
