math117: add trig integration
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@ -528,3 +528,71 @@ Please see [SL Math - Analysis and Approaches 2#Integration](/g11/mhf4u7/#52-inc
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- $\int\sec x\tan x dx = \sec x + C$
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- $\int\sec x\tan x dx = \sec x + C$
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- $\int\csc x\cot xdx = -\csc x + C$
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- $\int\csc x\cot xdx = -\csc x + C$
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- $\int\frac{1}{1+x^2}dx=\tan^{-1}x+C$
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- $\int\frac{1}{1+x^2}dx=\tan^{-1}x+C$
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- $\int\sec xdx = \ln|\sec x + \tan x| + C$
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- $\int\csc x dx = -\ln|\csc x + \cot x| + C$
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### Integration by parts
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IBP lets you replace an integration problem with a different, potentially easier one.
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$$
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\int u\ dv = uv-\int v\ du
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$$
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or, in function notation:
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$$
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\int u(x)v'(x)dx = u(x)v(x)-\int v(x)u'(x)dx
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$$
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Effectively, a product of two factors should be made simpler such that one is differentiable and the other is integratable. While there are integrals on both sides, the constant $C$ can be cancelled out for simplicity.
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Heuristics to be used:
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- $dv$ must be differentiable
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- $u$ should be simpler when differentiated
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- IBP might need to be used repeatedly
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- IBP and u-substitution might be needed together
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!!! example
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To solve $\int xe^xdx$:
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Let $u=x$, $dv=e^xdx$:
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$\therefore du=dx, v=e^x + C$
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via IBP:
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$$
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\begin{align*}
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\int udv &= xe^x - \int e^xdx \\
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&= xe^x-e^x + K
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\end{align*}
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$$
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Please see [SL Math - Analysis and Approaches 2#Area between two curves](/g11/mcv4u7/#area-between-two-curves) for more information.
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- A **Type 1** region is bounded by functions of $x$ — it's open-ended in the x-axis.
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- A **Type 2** region is bounded by functions of $y$, which can be solved by integrating $y$.
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- A **Type 3** region can be viewed as either Type 1 or 2.
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### Mean values
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The **mean value** of a continuous function $f(x)$ in $[a, b]$ is equal to:
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$$\text{m.v.} (f) = \frac{1}{b-a}\int_a^b f(x)dx$$
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The **root mean square** is equal to the square root of the mean value for each point:
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$$\text{r.m.s.} (f) = \sqrt{\frac{1}{b-a}\int_a^b f(x)^2dx}$$
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### Trigonometric substitution
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If $a\in\mathbb R$, functions of the form $\sqrt{x^2\pm a^2}$ or $\sqrt{a^2-x^2}$ can be rearranged in the form of a trig function.
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- In $\sqrt{x^2 + a^2} \rightarrow x=a\tan\theta$
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- In $\sqrt{x^2-a^2} \rightarrow x=a\sec\theta$
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- In $\sqrt{a^2-x^2} \rightarrow x=a\sin\theta$
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…which can be used to derive other trig identities to be integrated.
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