⧼exchistory⧽
8 exercise(s) shown, 0 hidden
BBy Bot
Nov 03'24
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[/math]
Integrate each of the following.
- [math]\int \cos 5x \sin 2x \; dx[/math]
- [math]\int \cos 3x \cos x \; dx[/math]
- [math]\int \sin 3x \sin x \; dx[/math]
- [math]\int \cos 4z \cos 7z \; dz[/math]
- [math]\int \cos 3x \sin \pi x \; dx[/math]
- [math]\int \cos 2\pi y \sin \pi y \; dy[/math]
- [math]\int \sin x \sin 6x \; dx[/math]
- [math]\int \cos 7w \sin 17w \; dw[/math].
BBy Bot
Nov 03'24
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[/math]
- lab{7.2.2a} Integrate [math]\int \sin^3\theta \; d\theta[/math] by using the fact that the exponent of [math]\sin \theta[/math] is an odd positive integer.
- lab{7.2.2b} Integrate [math]\int \sin^3 \theta \; d \theta[/math] by making use of the identity [math]\sin 3\theta = 3 \sin \theta - 4 \sin^3\theta[/math].
- Show that the answers obtained in \ref{ex7.2.2a} and \ref{ex7.2.2b} differ by a constant.
BBy Bot
Nov 03'24
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- lab{7.2.3a} Integrate [math]\int \sin^5 2x \; dx[/math] by using the fact that the exponent of the sine is an odd positive integer.
- lab{7.2.3b} Integrate [math]\int \sin^5 2x \; dx[/math] by using the recursion formula given in Problem.
- Show that the answers obtained in \ref{ex7.2.3a} and \ref{ex7.2.3b} differ by a constant.
BBy Bot
Nov 03'24
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[/math]
Integrate each of the following.
- [math]\int \tan^4 x \; dx[/math]
- [math]\int \tan^3 4y \; dy[/math]
- [math]\int \sec^4\theta \; d\theta[/math]
- [math]\int \sec^3 2x \; dx[/math]
- [math]\int \sec^4x \tan^4x \; dx[/math]
- [math]\int \sec^3x \tan^3x \; dx[/math]
- [math]\int \sec^4x \tan^5x \; dx[/math]
- [math]\int \sec^6x \sqrt{\tan x} \; dx[/math]
- [math]\int \frac{dx}{\sec x \tan x}[/math].
BBy Bot
Nov 03'24
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[/math]
- lab{7.2.8a} Let [math]n \geq 2[/math] be an integer, and derive a reduction formula for [math]\int \cot^nx x \; dx[/math] analogous to \ref{thm 7.2.1}.
- Use the formula derived in \ref{ex7.2.8a} to integrate [math]\int \cot^5 3\theta \; d\theta[/math].
BBy Bot
Nov 03'24
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[/math]
By a method analogous to that used previously to find [math]\int \sec x \; dx[/math], prove that
[[math]]
\int \csc x \; dx = -\ln|\csc x + \cot x| + c
.
[[/math]]
BBy Bot
Nov 03'24
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[/math]
- Use integration by parts to derive the reduction formula \ref{thm 7.2.4} for [math]\int \csc^nx \; dx[/math].
- Use this formula to integrate [math]\int \csc^6y \; dy[/math].
BBy Bot
Nov 03'24
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[/math]
Integrate each of the following.
- [math]\int \csc^5\theta \; d\theta[/math]
- [math]\int \sin 3x \cot 3x \; dx[/math]
- [math]\int \cot^4y \; dy[/math]
- [math]\int \csc^4x \cot^2x \; dx[/math]
- [math]\int \csc^32y \cot^3 2y \; dy[/math]
- [math]\int \csc^3\phi \cot^2\phi \; d\phi[/math].