Math 126-104 CRN20678
Study guide for Final
1. Integrals
(a) Compute the area that lies between the curves:
i. y = x3 − x2 + 1 and y = 1.
ii. y = x2 and y = x.
iii. y = x2 − x and y =
(b)
(c)
(d)
(e)
(f)
(g)
(h)
√
x for x ∈ [0, 2].
iv. y = sin (x) and y = cos (x) for x ∈ [0, π2 ]
R1
i. 0 x3 + x1/3 dx
R2
ii. 1 x12 dx
R4
iii. 1 (3x4 + 5x3 − 4x2 + 7) dx
R
iv. dx
ex
Rπ
i. 0 (1 + cos (x)) dx
R
ii. ex cos (ex ) dx
R
3
iii. x2 ex dx
R
iv. sin (x) cos5 (x) dx
R
i. xex dx
R
ii. x2 sin (2x) dx
R
iii. ex cos x dx
R
iv. x ln (x) dx
R
v. arcsin (x) dx
R
vi. arctan (x) dx
R
i. sec4 (x) dx
R
ii. sin5 (x) dx
R
iii. sin2 (x) cos2 (x) dx
R
iv. 2 sin (x) cos (x) dx
R dx
i. √36−x
2
R dx
√
ii.
2
R 9+x
iii. x√xdx
2
R x dx−25
iv. x2 +49
R
1
i. (x+1)(x−1)
2 dx
R
1
ii. (x+1)(x−1) dx
R
1
iii. (x2 +1)(x−1)
dx
R
dx
iv. x2 +5x−6
R (3x−5) dx
v. (x−2)(x+3)
R 1 dx
i. 0 √
x
R∞
2
ii. 0 2xe−x dx
1
Spring 2016
Carter
iii.
iv.
v.
R∞
1
R∞
0
R∞
0
1
dx
(x5/4 )
1
dx
(x2 +1)
1 −x/2
dx
2e
(a) Find the volume of the tetrahedron, by considering the triangular cross sections perpen-
3
4
y
z
5
x
dicular to the x-axis.
(b) Compute the volume obtained by rotating the region bounded by the curves y = x2 ,
y = 0, x = 1 about the x-axis.
(c) Compute the volume obtained by rotating the region bounded by the curves y = 2x,
y = 0, and x = 2 about the y-axis.
(d) Compute the volume obtained by rotating the region bounded by the curves y = e−x ,
y = 0, x = 0, x = 1 about the x-axis.
√
(e) Compute the volume obtained by rotating the region bounded by the curves y = 2,
x = y 2 , and x = 0 about the x-axis.
3
(a) Find the length of the
curve y = x 2 from x = 0 to x = 4. Recall that the formula for
Rbq
arc-length is L = a 1 + (f 0 (x))2 dx.
(b) Compute the length of the curve of the from 0 ≤ x ≤ 3 of the function
3
1
y = (x2 + 2) 2
3
2
y
−y
(c) Find the area of the surface generated by revolving the curve x = e +e
, for 0 ≤ y ≤
2
ln(2), about the y-axis.
√
(d) Find the surface area that is obtained by rotating y = 64 − x2 about the x-axis for
x ∈ [0, 8].
2
(a) A force of 2-Newtons will stretch a rubber band 100
meters. Assuming that Hooke’s
Law applies, how far with a force of 4-Newtons stretch the rubber band? How much
work does it take to stretch the rubber band this far? Recall: Hooke’s law states that
the force required to stretch a spring is proportional to the length that it is stretched.
(b) A force of 25-Newtons will stretch a spring 5 meters beyond its natural length. Assuming
that Hooke’s Law applies, how much work does it take to stretch the spring 10 meters
beyond its natural length? Recall: Hooke’s law states that the force required to stretch
a spring is proportional to the length that it is stretched.
(c) The half-life of the plutonium isotope is 24,360 years. If 10 grams of plotonium is released
into the atmosphere by a nuclear accident, how many years will it take for 80% of the
isotope to decay?
(d) A leaky bucket is being lifted 20 meters. It originally holds 10 kilograms of water, and
at the end of its journey it holds 5 kilos. How much work does it take to lift the bucket?
2. Determine which of the following sequences converge. If the sequence does converge, find the
limit.
n
(a) an = 1 + 31
(b) an =
n2 +n+3
3n2 +2n+1
(c) an =
n3
n5 +3n3 −2
cos(πn)
n
(d) an =
(e) an = ln(n) − ln(n + 1)
(f) an = (−1)n + n1
n
(g) an = 1 + −2
n
n
n
(h) an = n+3
(i) an =
(j) an =
(−8)n
n!
√
n
55n
3. For each of the series determine a formula for the nth partial sum:
(a)
1
1
1
+
+ ··· +
+ ···
2·3 3·4
(n + 1) · (n + 2)
(b)
1+
1
1
1
+
+ ··· + n + ···
5 25
5
3
(c)
9
9
9
+
+ ··· + n + ···
10 100
10
(d)
2 3 4
2
2
2
−
+ −
+ −
+ ···
3
3
3
4. Use any test that you like to determine if the given series converges.
(a)
∞
X
ln n
√
n
n=2
(b)
∞
X
1
100,001/100,000
n
n=1
(c)
∞
X
n=1
n2
n
+1
n3
n
−1
3n
1
−1
(d)
∞
X
n=1
(e)
∞
X
n=1
(f)
√
∞
X
n
2
n +3
n=1
(g)
∞
X
1
n!
n=1
(h)
∞ X
3 n
1+
n
n=1
(i)
X n!
(2n)!
n=1
(j)
∞
X
1
2/3
n
n=1
4
(k)
∞
X
1
n n2 − 1
n=2
√
(l)
∞ n
X
2
3
n=0
(m)
∞
X
1
1
√ −√
n
n+1
n=1
(n)
∞
X
n2 (n + 2)!
n!32n
n=1
(o)
∞
X
1
n1.1
n=1
(p)
∞ X
n=1
−2
1+
n
n
(q)
∞
X
n=0
n2
n
+1
(r)
∞
X
(−3)n
n!
n=0
5. Compute the interval of convergence for the series:
(a)
∞
X
(x − 2)n
3n
n=0
(b)
∞
X
(−1)n (x + 6)n
n=0
n · 3n
(c)
∞
X
n=1
5
nxn
(d)
∞
X
xn
(2n)!
n=1
6. Find the 4th Taylor polynomial, P4 , generated by f (x) =
1
x
at center a = 2
7. Use substitution and power series operations to find the Taylor series about x=0 of the
following functions:
x
(a) e− 2
(b) sin
πx
2
(c) x2 cos (3x)
(d)
1
3−x
(e) ln(1 + 34 x)
8. Compute the parametrization of the line segment from (1, 2) to (3, −8) for t ∈ [0, 1].
9. Give a parametrization of the ellipse
interval t ∈ [0, 2π].
x2
25
+
y2
9
= 1 that travels once counter-clockwise in an
10. Give the equation of the tangent line to the curve at the given point
(a)
x(t) = 2 cos (t) y(t) = 2 sin (t)
at t = π/6.
(b)
x(t) = 2t2 + 3
y(t) = t4
at t = −1.
(c)
x(t) = t + et
y(t) = 1 − et
at t = 0.
11. areas of polar graphs (and the graphs of the functions) such as
(a) r = 1 + cos (θ)
(b) one petal of r = cos (3θ)
(c) r = sin (θ) for θ ∈ [0, π].
6