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Solutions for a review of integration techniques for exam ii, including substitution, integration by parts, partial fractions, trigonometric substitutions, and improper integrals. It also covers the liate mnemonic, powers of trigonometric functions, and useful trigonometric derivatives and antiderivatives.
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Math 106: Review for Exam II - SOLUTIONS
by a multiplying constant) is also present in the integrand.
u dv = uv −
v du or
uv
′ dx = uv −
u
′ v dx
How to choose which part is u? Let u be the part that is higher up in the LIATE mnemonic below.
(The mnemonics ILATE and LIPET will work equally well if you have learned one of those instead;
in the latter A is replaced by P, which stands for “polynomial”.)
Logarithms (such as ln x)
Inverse trig (such as arctan x, arcsin x)
Algebraic (such as x, x
2 , x
3
Trig (such as sin x, cos 2x)
Exponentials (such as e
x , e
3 x )
or equal to the degree of the denominator, do long division then integrate the result.
Partial Fractions: here’s an illustrative example of the setup.
3 x
2
(x + 1)(x − 3) 2 (x 2
x + 1
x − 3
(x − 3) 2
Dx + E
x 2
Each linear term in the denominator on the left gets a constant above it on the right; the squared
linear factor (x − 3) on the left appears twice on the right, once to the second power. Each irreducible
quadratic term on the left gets a linear term (Dx + E here) above it on the right.
Radical Form
a 2 − x 2
a 2
x 2 − a 2
Substitution x = a sin t x = a tan t x = a sec t
sin
2 x + cos
2 x = 1 tan
2 x + 1 = sec
2 x
sin
2 x =
cos(2x)
cos
2 x =
cos(2x)
sin(2x) = 2 sin x cos x
sin
m x cos
n x dx Possible Strategy Identity to Use
m odd Break off one factor of sin x and substitute u = cos x. sin
2 x = 1 − cos
2 x
n odd Break off one factor of cos x and substitute u = sin x. cos
2 x = 1 − sin
2 x
m, n even Use sin
2 x + cos
2 x = 1 to reduce to only powers of sin x sin
2 x =
cos(2x)
or only powers of cos x, then use table of integrals #39-42 cos
2 x =
cos(2x)
or identities shown to right of this box.
tan
m x sec
n x dx Possible Strategy Identity to Use
m odd Break off one factor of sec x tan x and substitute u = sec x. tan
2 x = sec
2 x − 1
n even Break off one factor of sec
2 x and substitute u = tan x. sec
2 x = tan
2 x + 1
m even, n odd Use identity at right to reduce to powers of sec x alone. tan
2 x = sec
2 x − 1
Then use table of integrals #51.
Useful Trigonometric Derivatives and Antiderivatives
d
dx
tan x = sec
2 x
d
dx
sec x = sec x tan x
sec x dx = ln | sec x + tan x| + C
asymptote in the interval of integration. It may be useful to know the following limits.
lim x→∞
e
x = ∞
lim x→∞
e
−x = 0 Note: this is the same as lim x→−∞
e
x .
lim x→∞
1 /x = 0 Note: the answer is the same for lim x→∞
1 /x
2 and similar functions.
lim x→ 0
1 /x = ∞ Note: the answer is the same for lim x→ 0
1 /x
2 and similar functions.
lim x→∞
ln x = ∞
lim x→ 0 +
ln x = −∞
lim x→∞
arctan x = π/ 2
(a) Let u = sin x, so du = cos x dx.
sin
6 x cos
3 x dx =
sin
6 x(1 − sin
2 x) cos x dx Use cos
2 x = 1 − sin
2 x.
u
6 (1 − u
2 ) du
(u
6 − u
8 ) du
u 7
u 9
sin
7 x
sin
9 x
(b) Let x = 10 tan t, so dx = 10 sec
2 t dt.
x
y
t
x
2
2 = y
2 ⇒ y =
x 2
sec t =
hyp
adj
x^2 + 100
tan t =
opp
adj
x
3 x
2
2
Let x = 3. Then 20 = C(10), so C = 2.
Let x = 0. Then −13 = B(−3) + 2(1), so B = 5.
Let x = 1. Then −8 = (A(1) + 5)(−2) + 2(2), so A = 1.
3 x
2
(x − 3)(x 2
dx =
x + 5
x 2
x − 3
dx
x
x 2
x 2
x − 3
dx Let u = x
2
2 du
u
x 2
x − 3
dx
ln u
ln(x 2
5 arctan x + 2 ln |x − 3 | + D
(f) Since the degree of the numerator is greater than or equal to the degree of the denominator, we
do long division.
4 x
2 − 3 x + 2 +
x − 6
x − 6
4 x
3 − 27 x
2
4 x
3 − 24 x
2
− 3 x
2
− 3 x
2 +18x
2 x
2 x − 12
Now, we compute the integral. ∫ 4 x
3 − 27 x
2
x − 6
dx =
4 x
2 − 3 x + 2 −
x − 6
4 x
3
3 x
2
(g) This integral is improper at x = 1 because the integrand has a vertical asymptote there.
1
x − 1
dx = lim t→ 1 +
t
x − 1
dx
= lim t→ 1 +
ln |x − 1 |
3
t
= lim t→ 1 +
[ln | 3 − 1 | − ln |t − 1 |]
Since lim t→ 1 +
(− ln |t − 1 |) = ∞, this integral diverges (to ∞).
dy
dx
= 2xy + 6x
dy
dx
= 2x(y + 3)
dy
y + 3
= 2x dx Separate the variables.
dy
y + 3
2 x dx
ln |y + 3| = x
2
|y + 3| = e
x 2 +C Exponentiate each side to remove the ln.
y + 3 = ±e
C e
x 2 |w| = z means w = ±z.
y = −3 + Ae
x^2 Replace ±e
C with A.
Now we use the initial condition y(0) = 5 to find the value of A.
We have 5 = −3 + Ae
0 ⇒ A = 8, so the solution is y = −3 + 8e
x 2 .
f(x) = (^) x
f(x) = x
x centered at xxx = 100= 100= 100.
f(x) = x
1 / 2 f(100) = 10
f
′ (x) =
x
x
f
′ (100) =
f
′′ (x) =
x
4 x 3 / 2
f
′′ (100) =
3 / 2
P 2 (x) = f(100) + f
′ (100)(x − 100) +
f
′′ (100)
(x − 100)
2
x − 100
(x − 100)
2
the previous problem on the interval [100, 110]?
We know that |f(x) − Pn(x)| ≤
Kn+
(n + 1)!
|x − x 0 |
n+ .
In this case, n = 2, x 0 = 100, and x = 110 (the farthest from x 0 that we are considering).
K 3 = max of |f
′′′ (x)| on [100, 110] = max of |
8 x 5 / 2
| on [100, 110] =
5 / 2
Putting this all together, we have |f(x) − P 2 (x)| ≤
3 800 , 000
3!
integral converges, also give a good upper bound for its value.
(a)
1
6 + cos x
x
dx
For all x ≥ 1, we have
6 + cos x
x
x
x
because the minimum value of cos x is −1.
Since
∞
1
5 dx
x
diverges (compute yourself or notice that p = 0. 99 < 1), we know that the integral
in question must diverge too.