2210-90 Final Exam
Name
Spring 2013
KY
Instructions.
Show all work and include appropriate explanations when necessary. Correct answers
unaccompanied by work may not receive full credit. Please try to do all all work in the space provided and
circle your final answer.
1. (l6pts) Let u=i+3j—2kandv=i+j—k.
(a) (4pts) Find 2u + v
-
A.
‘
(b) (4pts) Find uH
(c) (4pts) Find u• v
Lt
)(‘) c;))
(-i)(-)
(d) (4pts) Find v x u
I
i
H
i
I’.
I
-1
I
i(-z3) (_)
3-I)
2. (lOpts) Find an equation for the plane which contains the point (1, 0, 1) and the line parameterized by
r ()
r(t)
(t +
1)i + (2
—
t)j + tk.
0’,
•%
<O)Z.J I)
F’
I
J
•-I
0
—2-
1(-)fz..)
A
1
1
-S(-’) fp-(-?)
3. (25pts) Consider the function
f(x, y)
(a) (4pts) Find Vf, the gradient of
Y
= x
y
2
—
y.
f.
Vf <Zx,j
(b) (6pts) Find the equation of the tangent plane to the graph of
V+(2.,I)
f at the point (2, 1).
<+3>
3
=
(c) (5pts) Find the critical points of
f.
(ito)
Oxi
Xt
(to)
4.
(d) (lOpts) Find the maximum and minimum values attained by the function on the disk 2 +y
2
Note: Check the values of the function at the critical points in the interior of the disk 2 + y
2 < 4,
then find the maximum and minimum on the boundary of the disk x2 + y
4. For the boundary,
2
you can use the technique of Lagrange multipliers, but other methods will work too.
O’-
l0d1O4J) )c.4--’+
So
=‘
-
-
3
Cy)
-
FA.1k. /rwti*
4 -FC
)
1
.‘
tL3
)4(_,)2)4(2)2)2)2
Sc
/UI I’1
Wa9L
C,\ie-c-c
crc.
re-s
2.
C4L
A.c44(rc-
ç: (L()
0
C..,
2-x
2-Xx
\—)
12_
)çt2j
L
l1
2
2
X)29
(
O,l)
-I
(o,-.)
N
_
/
+
(_i)
.t
2
x.
3.
4. (l2pts) Evaluate the following double integrals:
(a) (6pts)
[f
(2xy + 4y) dA, where R is the rectangle 0
J JR
f%I
‘1-
j (%
Coo
(b) (6pts)
[1 (
—
1,0
x
y
ft
9j)(
2 +y
2x + y
2
) dA, where S is the unit disk x
2
2.
Jxt)y
1.
JJS
ç
1
LL
-
o pr
COt7YC( .
1 1L’rbtocer1’A&
rZrt)?-
Jo
L3
I
10
,_jzcoe)Lo
j
5. (l6pts) Use triple integrals in cylindrical or spherical coordinates to compute the volumes of the
following solids. Remember,
V(S)
=
fff
1 dV
(a) (8pts) The solid ‘snocone’ shape bounded by the sphere of radius one and the cone
v
co
(‘+
ctt+ot
p=1
(
(
‘
i
z
(b) (8pts) The solid ‘gumdrop’ shape given by 0
z=1-x-y.
v ç
2ir
0
0
c
f0
I-r
I
1
r
2ir I
Jo
=I.
2
x+y
I
—
2ir(
0
3
r
—
—
.
2
y
=
6. (8pts) Match the following vector fields with the descriptions of the level surfaces to which they are
perpendicular by writing the letter in the blank provided.
F(x,y,z)=xi+2yj +3zk
‘P
A
F(z,y,z)=2i—3j+5k.
F(x,y,z)=xi+yj+zk
F(xy,z)=xi+yj+k
A. spheres
B. ellipsoids
C. paraboloids
D. planes
7. (l7pts) Consider the vector field F(x, y)
=
(x
—
p)i + (x + y)j.
(a) (6pts) Compute curl F. Note: Consider F as a vector field in three-space with zero k component.
c-tF
(b) (3pts) Is F a gradient (conservative) vector field? Circle one:
YES
(c) (8pts) Compute the line integral
IF
.
Jc
where C is the unit circle centered at the origin in the xy-plane, traversed counterclockwise.
rtt-)c
:
oç
+si-t
i- t-os
(cost
-SLwS
O2-r
tOS
t c4-t
9
to
4
(‘
?
cot
3 + y)j and let C denote the square with vertices (0,0), (1,0), (1, 1),
2 y)i + (z
8. (l6pts) Let F(x, y) = (x
and (0, 1) traversed counterclockwise.
—
(a) (8pts) Compute the line integral
r
I
fF
.
dr directly or by using Green’s Theorem.
Ij
(3x-i)
4,f
3
)c
(2_:1
C
(ê÷
(3it,.L
(b) (8pts) Compute the line integral
J’, F
n ds directly or by
using
‘
the plane Divergence Theorem.
2-x-1-j
1
9. (8pts) Consider the vector field F(x, y, z)
Theorem to compute
=
i + (yz
2
.ry
2 + zy)k. Use the Divergence
2 + z)j + (zx
ff
F n
S
where S is the surface of the unit sphere centered at the origin and n is the outward pointing unit
normal vector.
OQV
6’
-
t
S
ek
C-afl’LS
10. (6pts) Suppose F is a gradient (conservative) vector field. In other words, there is a potential function
f(x.y) such that F(x,y) = Vf(i,y). Suppose C is unit circle centered at the origin in the xy-plane,
traversed counterclockwise. Which two quantities below must be equal to zero (or the zero vector)?
Circle two letters.
fF.dr
B.
fF.nds
curlF
D.
divF
11. (l6pts) Let S denote the surface determined by
where x
2 +y
2 < 1 (S is the graph of
19
z
=
f(x, y)
=
+
12
2 + y
x
2 over the unit circle).
(a) (8pts) Find the surface area of S.
0
—
i)
2
(b) (8pts) Use Stokes’s Theorem to evaluate
ff
(curl F) n dS,
.
where F denotes the vector field
F
=
4--‘-
(1
—
yj + (z
2
2
2z + x)i + 4z
cii
êtYz
1 0.
1- crnos
-
6
—
)k.
2
y
ot’2-ir