General Double Integrals Over Nonrectangular Domains

General Double Integrals
We will define double integrals over two types of
nonrectangular domains:

Type1: A domain that is bounded
up and down by continuous
functions y=f(x) and y=g(x)
where f(x) > g(x) with a < x < b.

where f(x) > g(x) with a < x < b. a b
Type1
y=f(x)
y=g(x)

where f(x) > g(x) with a < x < b. a b
Type1
y=f(x)
y=g(x)
D = {a < x < b, g(x) < y < f(x)}

left and right by continuous
functions x= f(y) and x=g(y)
where f(y) > g(y) with c < y < d.
a b
Type1
y=f(x)
y=g(x)
D = {a < x < b, g(x) < y < f(x)}

left and right by continuous
functions x= f(y) and x=g(y)
where f(y) > g(y) with c < y < d.
a b
x=f(y)x=g(y)
d
c
Type1
Type2
y=f(x)
y=g(x)
D = {a < x < b, g(x) < y < f(x)}
D = {c < y < d, g(y) < x < f(y)}

Given a type 1 domain D, a fixed x defines a
vertical cross-section with the y changes from
g(x) to f(x).
a b
y=f(x)
y=g(x)
D (Type1)
x

g(x) to f(x).
a b
y=f(x)
y=g(x)
D (Type1)
x
We decribe D as
{(x, y)| a < x < b; g(x) < y < f(x)}.

g(x) to f(x).
a b
y=f(x)
y=g(x)
D (Type1)
x
We decribe D as
{(x, y)| a < x < b; g(x) < y < f(x)}.
Example: Describe D as shown
in the figure.
2y + x = 4
0 4
2
x

g(x) to f(x).
a b
y=f(x)
y=g(x)
D (Type1)
x
We decribe D as
{(x, y)| a < x < b; g(x) < y < f(x)}.
in the figure.
The x runs from 0 to 4. 2y + x = 4
0 4
2
x

g(x) to f(x).
a b
y=f(x)
y=g(x)
D (Type1)
x
We decribe D as
{(x, y)| a < x < b; g(x) < y < f(x)}.
in the figure.
The x runs from 0 to 4.
For a fixed x, the y-coordinate of
(x, y)'s run from 0 to (4 – x)/2.
2y + x = 4
0 4
2
x

g(x) to f(x).
a b
y=f(x)
y=g(x)
D (Type1)
x
We decribe D as
{(x, y)| a < x < b; g(x) < y < f(x)}.
in the figure.
The x runs from 0 to 4.
For a fixed x, the y-coordinate of
(x, y)'s run from 0 to (4 – x)/2.
2y + x = 4
0 4
2
So D ={(x, y)| 0 < x < 4; 0 < y < (4 – x)/2}
x

Theorem: Let z = z(x, y) over the domain
D = {(x, y)| a < x < b; g(x) < y < f(x)}.
a b
y=f(x)
y=g(x)
D (Type1)
x

D = {(x, y)| a < x < b; g(x) < y < f(x)}.
a b
y=f(x)
y=g(x)
D (Type1)
x
Then
∫ f(x, y)dA =∫ ∫
x=a
b
dxD

D = {(x, y)| a < x < b; g(x) < y < f(x)}.
a b
y=f(x)
y=g(x)
D (Type1)
x
Then
∫ f(x, y)dA =∫ ∫ z(x, y)dy ]dx.
x=a
b
∫y=g(x)
y=f(x)
[
D

D = {(x, y)| a < x < b; g(x) < y < f(x)}.
a b
y=f(x)
y=g(x)
D (Type1)
x
Then
∫ f(x, y)dA =∫ ∫ z(x, y)dy ]dx.
x=a
b
∫y=g(x)
y=f(x)
[
The important thing here is the order of the
integration. It is set according to the the description
of the domain D.
D

D = {(x, y)| a < x < b; g(x) < y < f(x)}.
a b
y=f(x)
y=g(x)
D (Type1)
x
Then
∫ f(x, y)dA =∫ ∫ z(x, y)dy ]dx.
x=a
b
∫y=g(x)
y=f(x)
[
The important thing here is the order of the
integration. It is set according to the the description
of the domain D.
Note that if D is the rectangle [a, b] x [c, d], then
D = {a < x < b; c < y < d} and the double integral is
∫ f(x, y)dA =∫ ∫ z(x, y)dy ]dx.
x=a
b
∫y=c
d
[
D
D

Example: Draw the domain D that is bounded by y = x, and
y = 2x – x2
. Find the volume of z = xy over D.

y = 2x – x2
0 1
D
y = x
y = 2x – x2

y = 2x – x2
To solve for intersection, set x = 2x – x2
and get two solutions x = 0, and 1.
0 1
D
y = x
y = 2x – x2

y = 2x – x2
So D is bounded above by f(x) = 2x – x2
below by g(x) =x, from x = 0 to x = 1.
0 1
D
y = x
y = 2x – x2

y = 2x – x2
0 1
D
y = 2x – x2
y = x
So D ={(x, y)| 0 < x < 1; x < y < 2x – x2
}

y = 2x – x2
0 1
D
y = 2x – x2
y = x
So D ={(x, y)| 0 < x < 1; x < y < 2x – x2
}
Set the iterated integral in the given
order:

y = 2x – x2
xy dy dx∫∫ y=xx=0
1 2x–x2
0 1
D
y = 2x – x2
y = x
So D ={(x, y)| 0 < x < 1; x < y < 2x – x2
}
Set the iterated integral in the given
order:

1 y=2x–x2
0 1
D
y = x
y = 2x – x2

=
xy2
∫ y=x
x=0
1
2
| dx
y=2x–x2
0 1
D
y = x
y = 2x – x2
1 y=2x–x2

=
xy2
∫ y=x
x=0
1
2
| dx
= x(2x – x2
)2
– x3
∫
x=0
1
dx1
2
y=2x–x2
0 1
D
y = x
y = 2x – x2
1 y=2x–x2

=
xy2
∫ y=x
x=0
1
2
| dx
= x(2x – x2
)2
– x3
∫
x=0
1
dx1
2
= 4x3
– 4x4
+ x5
– x3
dx∫
x=0
1
1
2
y=2x–x2
0 1
D
y = x
y = 2x – x2
1 y=2x–x2

=
xy2
∫ y=x
x=0
1
2
| dx
= x(2x – x2
)2
– x3
∫
x=0
1
dx1
2
= 4x3
– 4x4
+ x5
– x3
dx∫
x=0
1
1
2
= x5
– 4x4
+ 3x3
dx∫
x=0
1
1
2
y=2x–x2
0 1
D
y = x
y = 2x – x2
1 y=2x–x2

=
xy2
∫ y=x
x=0
1
2
| dx
= x(2x – x2
)2
– x3
∫
x=0
1
dx1
2
= 4x3
– 4x4
+ x5
– x3
dx∫
x=0
1
1
2
= x5
– 4x4
+ 3x3
dx∫
x=0
1
1
2
=
1
2 6
( x6
+5
4x5
)|
1
0
y=2x–x2
–
4
3x4
0 1
D
=
120
7
y = x
y = 2x – x2
1 y=2x–x2

Given a type 2 domain D,
x=f(y)x=g(y)
d
c
D Type2
x

Given a type 2 domain D, a fixed y defines a
vertical cross-section with the x changes from
g(y) to f(y).
x=f(y)x=g(y)
d
c
D Type2
x
y

g(y) to f(y).
We decribe D as
{(x, y)| c < y < d; g(y) < x < f(y)}.
x=f(y)x=g(y)
d
c
D Type2
x
y

g(y) to f(y).
We decribe D as
{(x, y)| c < y < d; g(y) < x < f(y)}.
in the figure.
2y + x = 4
0 4
2
y
x=f(y)x=g(y)
d
c
D Type2
x
y

g(y) to f(y).
We decribe D as
{(x, y)| c < y < d; g(y) < x < f(y)}.
in the figure.
The y run from 0 to 2. 2y + x = 4
0 4
2
y
x=f(y)x=g(y)
d
c
D Type2
x
y

g(y) to f(y).
We decribe D as
{(x, y)| c < y < d; g(y) < x < f(y)}.
in the figure.
The y run from 0 to 2.
For a fixed y, the x-coordinate of
(x, y)'s run from 0 to 4 – 2y.
2y + x = 4
0 4
2
y
x=f(y)x=g(y)
d
c
D Type2
x
y

g(y) to f(y).
We decribe D as
{(x, y)| c < y < d; g(y) < x < f(y)}.
in the figure.
The y run from 0 to 2.
For a fixed y, the x-coordinate of
(x, y)'s run from 0 to 4 – 2y.
2y + x = 4
0 4
2
So D ={(x, y)| 0 < y < 2; 0 < x < 4 – 2y}
y
x=f(y)x=g(y)
d
c
D Type2
x
y

D = {(x, y)| c < y < d; g(y) < x < f(y)}. x=f(y)x=g(y)
d
c
D Type2
x
y

D = {(x, y)| c < y < d; g(y) < x < f(y)}.
Then
∫ f(x, y)dA =∫ ∫ dy.
y=c
d
D
x=f(y)x=g(y)
d
c
D Type2
x
y

D = {(x, y)| c < y < d; g(y) < x < f(y)}.
Then
∫ f(x, y)dA =∫ ∫ z(x, y)dx ]dy.
y=c
d
∫x=g(y)
f(y)
[
D
x=f(y)x=g(y)
d
c
D Type2
x
y

D = {(x, y)| c < y < d; g(y) < x < f(y)}.
Then
∫ f(x, y)dA =∫ ∫ z(x, y)dx ]dy.
y=c
d
∫x=g(y)
f(y)
[
The order of the integration is set according to the the
description of the domain D with ∫ dy outside and ∫ dx
inside to be calculated first.
D
x=f(y)x=g(y)
d
c
D Type2
x
y

D = {(x, y)| c < y < d; g(y) < x < f(y)}.
Then
∫ f(x, y)dA =∫ ∫ z(x, y)dx ]dy.
y=c
d
∫x=g(y)
f(y)
[
The order of the integration is set according to the the
description of the domain D with ∫ dy outside and ∫ dx
inside to be calculated first.
Again, if D is the rectangle [a, b] x [c, d], then
D = {c < y < d; a < x < b } and the double integral is
∫ f(x, y)dA =∫ ∫ z(x, y)dx ]dy.
y=c
d
∫x=a
b
[
D
D
x=f(y)x=g(y)
d
c
D Type2
x
y

Example: D is bounded by x = 2y, and x = y2
+ 1 from y = 0
to y = 1. Draw D. Find the volume of z = 2x + y over D.

+ 1 from y = 0
To solve for intersection, set 2y = y2
+ 1
and get y =1.

+ 1 from y = 0
+ 1
and get y =1.
1 x = y2
+ 1
x = 2y

+ 1 from y = 0
So D is bounded to the right by y2
+ 1,
to the left 2y, from y = 0 to y = 1.
+ 1
and get y =1.
1 x = y2
+ 1
x = 2y

+ 1 from y = 0
+ 1,
+ 1
and get y =1.
To set the iterated integral, write D in
correct order as
{(x, y)| 0 < y < 1;
1 x = y2
+ 1
x = 2y

+ 1 from y = 0
+ 1,
+ 1
and get y =1.
correct order as
{(x, y)| 0 < y < 1; 2y < x < y2
+1 }
1 x = y2
+ 1
x = 2y

+ 1 from y = 0
+ 1,
+ 1
and get y =1.
correct order as
{(x, y)| 0 < y < 1; 2y < x < y2
+1 }
then set the integral in this order:
dy∫y=0
1
1 x = y2
+ 1
x = 2y
2x + y dx
x=y2
+1
∫x=2y

dy∫y=0
1
2x + y dx
x=y2
+1
∫x=2y
1 x = y2
+ 1
x = 2y

=∫y=0
1
dy∫y=0
1
2x + y dx
x=y2
+1
∫x=2y
x2
+ yx| dy
x=2y
x=y2
+1
1 x = y2
+ 1
x = 2y

=∫y=0
1
= (y2
+ 1)2
+ y(y2
+1) – (2y)2
– y(2y)dy∫y=0
1
dy∫y=0
1
2x + y dx
x=y2
+1
∫x=2y
x2
+ yx| dy
x=2y
x=y2
+1
1 x = y2
+ 1
x = 2y

=∫y=0
1
= (y2
+ 1)2
+ y(y2
+1) – (2y)2
– y(2y)dy∫y=0
1
=∫y=0
1
dy∫y=0
1
2x + y dx
x=y2
+1
∫x=2y
x2
+ yx| dy
x=2y
x=y2
+1
1 x = y2
+ 1
x = 2y
y4
+ y3
– 4y2
+ y + 1 dy

=∫y=0
1
= (y2
+ 1)2
+ y(y2
+1) – (2y)2
– y(2y)dy∫y=0
1
=∫y=0
1
dy∫y=0
1
2x + y dx
x=y2
+1
∫x=2y
x2
+ yx| dy
x=2y
x=y2
+1
1 x = y2
+ 1
x = 2y
y4
+ y3
– 4y2
+ y + 1 dy
=
37
60

Its possible that a
domain is both type 1
and type 2:

Its possible that a
and type 2:
y=2x or x=y/2
1
2
D

Its possible that a
and type 2:
y=2x or x=y/2
1
Let f(x, y) = e .
2
D
x2

Its possible that a
and type 2:
y=2x or x=y/2
1
Let f(x, y) = e . The double integral may be set in
two ways over D.
2
D
x2

= dy∫y=0
2
dx
x=1
∫x=y/2
Its possible that a
and type 2:
y=2x or x=y/2
1
two ways over D. If we set the iterated integral as
∫ D
dA∫
2
D
x2
x2
e
x2
e

= dy∫y=0
2
dx
x=1
∫x=y/2
Its possible that a
and type 2:
y=2x or x=y/2
1
∫D
dA∫
2
D
it won't be not computable.
x2
x2
e
x2
e

= dy∫y=0
2
dx
x=1
∫x=y/2
Its possible that a
and type 2:
y=2x or x=y/2
1
∫D
dA∫
2
D
it won't be not computable. But if we switch the order:
x2
x2
e
x2
e
=∫D
dA∫
x2
e

= dy∫y=0
2
dx
x=1
∫x=y/2
Its possible that a
and type 2:
y=2x or x=y/2
1
∫D
dA∫
2
D
x2
x2
e
x2
e
= dx∫x=0
1
dy
y=2x
∫y=0
∫D
dA∫
x2
e
x2
e

= dy∫y=0
2
dx
x=1
∫x=y/2
Its possible that a
and type 2:
y=2x or x=y/2
1
∫D
dA∫
2
D
x2
x2
e
x2
e
= dx∫x=0
1
dy
y=2x
∫y=0
∫D
dA∫
x2
e
x2
e = dx∫x=0
1 y=2x
y=0
x2
e y|

= dy∫y=0
2
dx
x=1
∫x=y/2
Its possible that a
and type 2:
y=2x or x=y/2
1
∫D
dA∫
2
D
x2
x2
e
x2
e
= dx∫x=0
1
dy
y=2x
∫y=0
∫D
dA∫
x2
e
x2
e = dx∫x=0
1 y=2x
y=0
x2
e y| = dx∫x=0
1
x2
2xe

= dy∫y=0
2
dx
x=1
∫x=y/2
Its possible that a
and type 2:
y=2x or x=y/2
1
∫D
dA∫
2
D
x2
x2
e
x2
e
= dx∫x=0
1
dy
y=2x
∫y=0
∫D
dA∫
x2
e
x2
e = dx∫x=0
1 y=2x
y=0
x2
e y| = dx∫x=0
1
2xe
x=0
1
x2
e |= = e – 1
x2

= dy∫y=0
2
dx
x=1
∫x=y/2
Its possible that a
and type 2:
y=2x or x=y/2
1
∫D
dA∫
2
D
x2
x2
e
x2
e
= dx∫x=0
1
dy
y=2x
∫y=0
∫D
dA∫
x2
e
x2
e = dx∫x=0
1 y=2x
y=0
x2
e y| = dx∫x=0
1
2xe
x=0
1
x2
e |= = e – 1
We say we reverse the order of integration in this case
x2

The area of a 2D shape D is the same numerically
as the volume of the cylinder with height 1 over D.

=Area Volume
1
(numerically)

Therefore we may compute area of D by computing
the volume of the cylinder with ht=1 over D.
=Area Volume
1
(numerically)

Example:
Find the area
enclosed by y = x2
and y = 2x + 3.
=Area Volume
1
(numerically)

Example:
Find the area
enclosed by y = x2
and y = 2x + 3.
=Area Volume
1
(numerically)
-1 3
1

Example:
Find the area
enclosed by y = x2
and y = 2x + 3.
=Area Volume
1
(numerically)
Set x2
= 2x + 3, we get x = -1, and 3. Set the integral
-1 3
1

Let z = f(x, y) = 1.
x=-1
-1 3
1

Let z = f(x, y) = 1. It defines the cylinder whose
volume is the integral:
dx∫x=-1
3
dy
y=2x+3
∫y=x2
1
x=-1
-1 3
1

dx∫x=-1
3
dy
y=2x+3
∫y=x2
1 = dx∫x=-1
3
y |
y=2x+3
y=x2
=
x=-1
-1 3
1

dx∫x=-1
3
dy
y=2x+3
∫y=x2
1 = dx∫x=-1
3
y |
y=2x+3
y=x2
= dx∫x=-1
3
2x + 3 – x2
x=-1
-1 3
1

dx∫x=-1
3
dy
y=2x+3
∫y=x2
1 = dx∫x=-1
3
y |
y=2x+3
y=x2
= dx∫x=-1
3
2x + 3 – x2
= x2
+ 3x – x3
/3 |
x=-1
3
=
-1 3
1
x=-1

dx∫x=-1
3
dy
y=2x+3
∫y=x2
1 = dx∫x=-1
3
y |
y=2x+3
y=x2
= dx∫x=-1
3
2x + 3 – x2
= x2
+ 3x – x3
/3 |
x=-1
3
=
28
3
-1 3
1
x=-1
which is the measurement of the area.

dx∫x=-1
3
dy
y=2x+3
∫y=x2
1 = dx∫x=-1
3
y |
y=2x+3
y=x2
= dx∫x=-1
3
2x + 3 – x2
= x2
+ 3x – x3
/3 |
x=-1
3
=
28
3
-1 3
1
x=-1
which is the measurement of the area.
To summarize: ∫ dA = area of D.∫ 1
D

General Double Integrals Over Nonrectangular Domains

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