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Delft University of Technology
Faculty of Electrical Engineering, Mathematics and Computer Science
Mekelweg 4, Delft
Answers Test Calculus for AE (wi1276LR)
Wednesday, October 29, 2008, 9:00 - 10:30 a.m.
1. H. Suppose that x = arcsin( 45 ), then we have: sin x = 54 and x ∈ [− π2 , π2 ]. In fact it
is easily seen that 0 < x < π/2. Now we p
look for: sin(2x) = 2 sin x cos x. We have
that: sin2 x + cos2 x = 1. Hence: cos x = ± 1 − (4/5)2 = ±3/5. Since x ∈ [− π2 , π2 ] we
conclude that cos x = 3/5 ≥ 0. Hence: sin(2x) = 2 sin x cos x = 2 · 45 · 35 = 24
25 .
2. A. An equation of the tangent line at the point (−1, 1) has the form y − 1 = r(x + 1),
dy . Using implicit
where r denotes the rate of increase. Now we have r = dx
(−1,1)
differentiation we obtain:
3x2 + 6xy + 3x2
dy
dy
+ 6y 2
=0
dx
dx
dy
3x2 + 6xy
x2 + 2xy
=− 2
=
−
.
dx
3x + 6y 2
x2 + 2y 2
=⇒
This implies that r = 1/3.
3. G. Using integration by parts we find that
Z
arctan x dx = x arctan x −
= x arctan x −
Z
x d arctan x = x arctan x −
Z
x
dx
1 + x2
1
ln(1 + x2 ) + C.
2
4. F. Using the substitution ln x = t we obtain
e4
Z
e
dx
√
=
x ln x
Z
e4
e
d ln x
√
=
ln x
Z
4
1
√ 4
dt
√ = 2 t = 2(2 − 1) = 2.
1
t
5. H. Note that the integrand becomes infinite for x = 0 ∈ (−1, 2). Further we have:
Z
0
2
dx
= lim
↓0
x4
Z
2
dx
1
= lim − 3
↓0
x4
3x
Hence the integral is divergent.
2
= lim −
↓0
1
1
= ∞.
+
24 33
6. F. The differential equation is separable:
(1 + y 2 ) dy = cos x dx
=⇒
1
y + y 3 = sin x + C.
3
From y(0) = 1 it follows that: C = 4/3.
7. A. The differential equation is linear. Look for an integrating factor I(x):
I(x)y 0 (x) + 2I(x)y(x) = 6I(x)ex .
For I(x) we must have that: I 0 (x) = 2I(x) which implies that I(x) = e2x (for instance).
Then we have:
i
d h 2x
e y(x) = 6e3x
dx
e2x y(x) = 2e3x + C
=⇒
8. F. In the polar form we have:
√
=⇒
y(x) = 2ex + Ce−2x .
√
3 − i = 2e−iπ/6 en 1 − i 3 = 2e−iπ/3 . Then we have:
√
10
( 3 − i)10
210 e− 6 π i
πi
5 ( 53 − 10
6 )
√
=
=
2
e
= 25 e0 = 32.
5
−3π i
5
(1 − i 3)5
2 e
9. B. The auxiliary equation is: r2 − 4r + 5 = 0 or equivalently (r − 2)2 + 1 = 0. This
implies that: r = 2±i. Hence: yh (x) = c1 e2x cos x+c2 e2x sin x. For a particular solution
we then have: yp (x) = Ae−x . Substitution leads to: 10A = 5 or equivalently A = 1/2.
Hence the general solution is: y(x) = yp (x) + yh (x) = 21 e−x + c1 e2x cos x + c2 e2x sin x.
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