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Title: Multi Variable Calculus UNIT-I-NOTES-02
Description: This is the continuation for the Multi Variable Calculus UNIT-I-NOTES-01
Description: This is the continuation for the Multi Variable Calculus UNIT-I-NOTES-01
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Problem :-02
...
x0
xa
yx
ya
i
...
[ Corresponds
to vertical strip method
...
i
...
x2
4
Solution:
From the given data, first integral with respect to x and second with respect to y
x0
x4
x2
4
y2 x
y
i
...
x 2 4 y
i
...
y 2 4 x
i
...
[corresponds to
vertical strip method]
The region of integration is
y2 = 4x
x2 = 4y
(4,4)
(0,0)
x=4
x=0
By changing the order,
Let us consider horizontal strip method, we have the following limits
x=y2/4, x=2(y)1/2, y=0, y=4
4
I
2 y
dx dy
0
y2
4
4
=
y2
dy
4
2 y
0
4
1
= 2 y2
0
=
y2
dy
4
4
4 3 y3
= y2
12 0
3
4 32 64
= 4
12
3
I=
16
3
Problem:-4
a
Change the order of integration and hence evaluate
2 a x
0
xy dy dx
2
x
a
Solution:
From the given data, first integral with respect to x and second integral with respect
to y
...
e
...
e
...
e the given order of integration is with respect to y first and x second [corresponds
to vertical strip method]
The region of integration is
x2 = ay
(0,2a)
(a,a)
(0,a)
y=a
(0,0)
x=a
x + y = 2a
x=0
By changing the order,
Let us consider the horizontal strip method,
i
...
therefore we must divide the whole region R into
two regions R1(region below the line y=a) and R2 (region above the line y=a)
...
therefore we have R=R1+R2
I xydxdy xydxdy
R1
R2
R1 (region below the line y=a)
R2(region above the line y=a)
...
a
I
0
a
ay
0
2a
xy dx dy
0
x2
y
2 0
1
ay
xy dx dy
0
2a
dy
2a y
a
2 a y
x2
y
2 0
aa 2
1 2a
2
y dy y 2a y dy
20
2a
dy
aa 2
1
I
y dy
20
2
2a
4a 2 y y 3 4ay 2 dy
a
a
2a
a y3 1
y 4 4ay 3
2
2ay
2 3 0 2
4
3 a
I
a 4 1 4
32a 4 4 a 4 4a 4
8a 4a 4
2a
6 2
3
4
3
9 4
a
24
Problem:-5
...
e the given order of integration is with respect to y first and x second [corresponds to
vertical strip method]
The region of integration is
By changing the order of integration,
Let us consider horizontal strip method
i
...
x
y, x a
y 0,
y a2
a x2
x( x
0 0
a2 a
2
2
y )dydx
0
a
x( x
2
y 2 )dxdy
y
2
a
(x
0
3
xy 2 )dxdy
y
a2
a
x4 x2 y2
dy
4
2 y
0
a2
a 4 a 2 y 2 y 2 y 3
dy
2 4
2
4
0
a2
a4 y a 2 y3 y 3 y 4
6
12 8 0
4
a 6 a8 a 6 84
4 6 12 8
6a 6 4a8 2a 6 3a8
24
6
8
4a a
24
a x2
2
2
x( x y )dydx
0 0
a 6 (a 2 4)
24
Problem:-06
a
Evaluate
a 2 x2
0
xydydx by changing the order of integration
0
Solution:
From the given, first integral with respect to x and second integral with respect to y
...
line parallal y axis)
i
...
i
...
a
x a2 y2
y 0
ya
a 2 x2
0
x0
0
a 2 y2
a
xydydx
0
xydxdy
0
a
x2
y
2 0
0
a 2 y2
dy
a
1
y a 2 y 2 dy
20
a
1
a 2 y y 3 dy
20
a
1 a2 y2 y 4
2 2
4 0
1 a4 a4
2 2 4
a
a 2 x2
0
0
a4
xydydx
8
Problem:-7
a
Evaluate by changing the order of integration
a2 y 2
0
y dy dx
a y
Solution:
From the given, first integral with respect to y and second integral with respect to x
...
e
...
e
...
e the given order of integration is with respect to x first and y second
...
i
...
a 2 x2
a
I
y dy dx
ax
0
a 2 x2
1a
2
=
y
dx
2 0 a x
1
=
2
a
a
2
x 2 (a x )2 dx
0
a
1
x 3 ( a x )3
a 2 x
2
3
3 0
I
1
2
I
a3
6
3 a3 a3
a 3 3
Problem:-8
1
Change the order of integration and hence evaluate
2 y
0
y
xy dx dy
2
Solution:
From the given, first integral with respect to y and second integral with respect to x
...
e
...
e integration with respect to x first and y second [ corresponds to horizontal strip
method]
The region of integration is bounded by
(0,2)
y2 = x
y=1
(1,1)
(2,0)
y=0
(0,0)
x=1
x+y=2
By changing the order,
Let us consider the vertical strip method,
i
...
therefore we must divide the whole region R into two
regions R1(region in left side of the line x=1) and R2 (region in right side of the line x=1)
...
therefore we have R=R1+R2
I xydxdy xydxdy
R1
R2
R1 (region in left side of the line x=1)
R2( region in right side of the line x=1)
y=0, y=(x)1/2
y=0, y=2-x
x=0,x=1
x=1,x=2
1
I
x
0
1
0
2 x
2
xy dy dx
0
1
x
y2
x dx
2 0
xy dy dx
0
2
1
2 x
y2
x dx
2 0
11 2
12
2
x dx x 2 x dx
20
21
11 2
1
x dx
20
2
1
2
4 x x3 4 x 2 dx
1
2
1 x3 1 2 x 4 4 x 3
2x
2 3 0 2
4
3 1
1 1
32
1 4
8 4 2
6 2
3
4 3
I
23
12
TRIPLE INTEGRAL
Consider a function f(x,y,z) defined at every point of the three dimensional finite
region V
...
Vn
...
Consider the sum
f ( x , y , z )V
r
r
r
r
r 1
The limits of this sum, if it exists, as n and Vr is called the triple integral
of f(x,y,z)over the region V and is denoted by
f ( x, y, z )dV
For purposes of evaluation it can also be expressed as the repeated integral
x2 y2 z2
f ( x, y, z) dxdydz
x1 y1 x z
If x1 , x2 are constants: y1 , y2 are either constants or functions of x and z1 , z2 are
either constants or functions of x and y then this integral is evaluated as follows:
First f(x,y,z)is integrated w
...
to z between the limits z1 and z2 keeping x and y fixed
...
r
...
The result just obtained is finally integrated w
...
to x between the limits x1 and x2
x2
Thus
I
y2 ( x )
x1
y1 ( x )
z2 ( x , y )
f ( x, y, z ) dz dy dx
z1 ( x , y )
Where the integration is carried out from the innermost rectangle to the outermost rectangle
...
Also any order of integration can be followed for evaluation
...
a x2 y 2 z2
Solution:The equation of sphere x2+y2+z2=a2 and the limits are
x0
xa
y0
y a2 x2
z0
z a2 x 2 y 2
2
2
2
a x y z
a 2 x2
a 2 x2 y2
0
0
0
a
dzdydx
2
a 2 x2
a
0
0
a
a 2 x2
(a x 2 y 2 ) z 2
z
sin 1
(a 2 x 2 y 2 )
0
sin 1 1 sin 1 0 dydx
0
dzdydx
2
0
a
20
a 2 x2
dydx
0
a
a2 x 2
y
dx
0
2 0
a 2 x 2 dx
20
a
a
x 2 2 a 2 1 x
a x sin
2 2
2
a 0
a 2 1
0 sin 1 0
2
2
a2
2 2 2
2a2
8
a 2 x2 y 2
dydx
Title: Multi Variable Calculus UNIT-I-NOTES-02
Description: This is the continuation for the Multi Variable Calculus UNIT-I-NOTES-01
Description: This is the continuation for the Multi Variable Calculus UNIT-I-NOTES-01