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documents/by-course/math-6a/course-notes/main.typ
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@ -1152,6 +1152,43 @@ $
integral.double_(x^2 + y^2 <= 1) f(x,y) dif x dif y integral.double_(x^2 + y^2 <= 1) f(x,y) dif x dif y
$ $
#example[
Show both ways of setting up the integral of a function $f(x,y)$ over the region bounded by $y - x = 2$ and $y = x^2$.
Hopefully we can visualize what this looks like, now let's solve for the
intersection points.
$
(x,y) = (-1,1) "or" (2,4)
$
In AP Calculus we know we can compute this by subtracting the functions, but
let's consider it as a double integral instead.
We want the part of the plane that lies above the parabola, but below the
line. Let's think about this as a system of inequalities.
$
&y >= x^2 \
&y - x <= 2
$
First let's imagine we let $x$ be the outer integral. Solving for $y$,
$
x^2 <= y <= x + 2
$
Hence, we get the integral
$
integral^2_(x=-1) integral^(x+2)_(y=x^2)
$
If we put $y$ as the outer integral, we see that $y$ ranges from 0 to 4.
However we actually have a system of 3 inequalities. So we'll need to write a
sum of integrals and it's very annoying.
]
== Swapping the order of integration == Swapping the order of integration
If our function is nice, then this is easy. If our function is nice, then this is easy.
@ -1166,3 +1203,36 @@ Otherwise, we want to swap the order of integration. We convert the limits of
integration back into inequality/region format, getting a region $cal(R)$ like integration back into inequality/region format, getting a region $cal(R)$ like
discussed in the previous section. Then evaluate that integral using standard discussed in the previous section. Then evaluate that integral using standard
methods. methods.
#example[
Evaluate the double integral
$
integral^2_(x=0) integral^1_(y=x / 2) e^(y^2) dif y dif x
$
To evaluate this, note that integrating $e^(y^2)$ is hard. So let's swap the
order. Convert to region format:
$
cal(R) = cases(0 <= x <= 2, x/2 <= y <= 1)
$
If we graph the region being integrated on an $x y$-plane, we see a
triangular area. Solving for $x$ in terms of $y$ gives us three conditions.
In addition to $0 <= x <= 2$ we need $x <= 2y$. Since $y <= 1$ we can ignore
$x <= 2$, and the region becomes
$
cal(R) = cases(0 <= y <= 1, 0 <= x <= 2y)
$
Converting back into double integral gives
$
integral_(y=0)^1 integral_(x=0)^(2y) e^(y^2) dif y dif x
$
The inner integral is with respect to $x$ but the integrand is independent of
$x$. So the inner integral is
$
integral^(2y)_(x=0) e^(y^2) dif x = 2y dot e^(y^2)
$
and evaluating
$
integral_(y=0)^1 (2y dot e^(y^2)) dif y dif x = lr(e^(y^2) |)^(y=1)_(y=0) = e - 1
$
]