5.4 Indefinite Integrals and the Net Change Theorem/17: Difference between revisions

Revision as of 17:47, 13 September 2022

$\int (1+\tan ^{2}{\alpha })\,d\alpha =\int \sec ^{2}\alpha \,d\alpha =\tan \alpha +C$

Note: $1+\tan ^{2}{\alpha }=\sec ^{2}\alpha$

Or,

$\int (1+\tan ^{2}{\alpha })\,d\alpha \int 1+{\frac {sin^{2}\alpha }{cos^{2}\alpha }}d\alpha =\int {\frac {cos^{2}\alpha +sin^{2}\alpha }{cos^{2}\alpha }}d\alpha \cos ^{2}x+sin^{2}x=1\int {\frac {1}{cos^{2}x}}dx=\int \sec ^{2}xdx=\tan {x}+C$

@@ Line 11: / Line 11: @@
 <math>
-\int_{}^{}1+tan^2xdx =
+\int(1+\tan^2{\alpha})\,d\alpha
-\int_{}^{}1+\frac{sin^2x}{cos^2x}dx =
+\int 1+\frac{sin^2\alpha}{cos^2\alpha}d\alpha =
-\int_{}^{}\frac{cos^2x+sin^2x}{cos^2x}dx
+\int\frac{cos^2\alpha+sin^2\alpha}{cos^2\alpha}d\alpha
 \cos^2x+sin^2x=1
-\int_{}^{}\frac{1}{cos^2x}dx =
+\int\frac{1}{cos^2x}dx =
-\int_{}^{}\sec^2xdx =
+\int\sec^2xdx =
-tanx+C
+\tan{x}+C
 </math>

5.4 Indefinite Integrals and the Net Change Theorem/17: Difference between revisions

Revision as of 17:47, 13 September 2022

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