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These are the notes of Exam of Complex Analysis and its key important points are: Express, Compute, Real, Exponential Form, Formula, Integer, Clearly, Condition, Satisfies, Unit Circle
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United Arab Emirates University College of Sciences Department of Mathematical Sciences
Complex Analysis I
MATH 315 SECTION 01 CRN 23516
9:30 – 10:45 on Monday & Wednesday
Due Date: Monday, October 19, 2009
Complex Analysis I EXAM 1 – SOLUTION Fall, 2009
3 + i and w = 1 + i
(1.1) (5 points) Compute w − z, zw, and | z |. Express w/z in the form x + iy with real x and y.
Answer.
w − z = 1 + i
3 + i
3 + i
zw =
3 + i
1 + i
3 + i 2
3 + i
3 + i ( 3 + 1 ) = 4i
| z | =
3 + i =
w
z
1 + i
3 + i
1 + i
3 + i
3 − i √ 3 − i
1 + i
3 − i
3 + 2i
4
3 + i
2
.
(1.2) (5 points) Express z =
3 + i in the exponential form reiθ.
Answer. For the given z, we have
| z | = 2, −π < Arg(z) = tan
π
6
≤ π, z = | z | e i Arg(z) = 2e i π 6
.
Answer. Euler’s formula and de Movire’s formula are, respectively, as follows
e iθ = cos θ + i sin θ, [ cos θ + i sin θ ]
n = cos ( nθ ) + i sin ( nθ ) ,
where n is an integer.
Answer. z = i satisfies the condition Im(z) = 1 > 0. But, clearly z = i does not satisfy the inequality | z − i | = 0 < 2 = | z + i |.
(3.2) (2 points) If z ̸= 0 lies inside the unit circle centered at the origin, then 1/¯z lies outside the
Answer. With z = x + iy ̸= 0,
¯z
x − iy
x + iy
x^2 + y^2
, and
z¯
x^2 + y^2
If z = x + iy ̸= 0 lies inside the unit circle, then | z¯ |
2 = | z |
2 = x 2
Complex Analysis I EXAM 1 – SOLUTION Fall, 2009
1 / 3 .
Answer. We are asked to find all z’s satisfying z^3 = 1 + i. We start with the exponential forms of z, and 1 + i,
z = | z | e i arg( z ) , z 3 = | z |
3 e i3 arg( z ) , 1 + i = | 1 + i | e i arg( 1+i ) =
2 e i( π 4 +2nπ (^) )
where n = 0, ± 1 , ± 2 ,.... From z 3 = 1 + i, we obtain
| z |
3 e i3 arg( z ) = z 3 = 1 + i =
2 e i( π 4 +2nπ (^) ) , i.e., | z |
2 , 3 arg ( z ) =
π
4
It gives us
| z | =
1 / 6 , arg ( z ) =
π
12
2 nπ
3
, i.e., z = 2 1 / 6 e i( 12 π + 2 nπ 3 ) ,
where n = 0, ± 1 , ± 2 ,.... Putting n = − 1 , 0 , 1, we have all the 3rd^ roots:
c 2 = c− 1 = 2 1 / 6 e i( 12 π − 23 π ) =
− i
c 0 = 2 1 / 6 e i( 12 π ) =
− i
c 1 = 2 1 / 6 e
i( 12 π + 23 π ) = −
1 / 6 − i √ 2
.
(8.1) (5 points) Write f (z) = xy + iy 2 in terms of z and ¯z, where z = x + iy.
Answer. With z = x + iy, we have
x = Re ( z ) =
z + ¯z
2
, y = Im ( z ) =
z − ¯z
2 i
Before putting them into the function, we modify the given function
f (z) = xy + iy 2 = y ( x + iy ) = ( Im ( z ) ) z,
which gives us
f (z) = ( Im ( z ) ) z =
z − z¯
2 i
z = −i
z 2 − z z¯
2
= −i
z 2 − | z |
2
| z |
2 − z 2
i.
Complex Analysis I EXAM 1 – SOLUTION Fall, 2009
(8.2) (5 points) Write f (z) = z 2 − ¯z 2 in the form u(r, θ) + iv(r, θ), where r and θ are the modulus and the principal argument of z, respectively.
Answer. With z = re iθ and ¯z = re −iθ , we have
f (z) = z 2 − z¯ 2 = r 2 e 2 iθ − r 2 e − 2 iθ = r 2
e 2 iθ − e − 2 iθ
= r 2 [ cos ( 2θ ) + i sin ( 2θ ) − ( cos ( 2θ ) − i sin ( 2θ ) ) ]
= 0 + 2r 2 i sin ( 2θ ) = u(r, θ) + iv(r, θ).
That is, u(r, θ) = 0 and v(r, θ) = 2r^2 sin(2θ).
′ of the semi–infinite strip S given below under the trans- formation w = f (z) = ez^ :
S = { z = (x, y) ∈ C | − 1 ≤ x ≤ 1 , 0 ≤ y ≤ π }.
Answer. Using Exponential Form. For z = x + iy ∈ S, we use the exponential form,
ρe iϕ = w = f (z) = e x+iy = e x e iy , i.e., ρ = e x , ϕ = y.
For − 1 ≤ x ≤ 1 and 0 ≤ y ≤ π, we have e − 1 ≤ ρ = e x ≤ e and 0 ≤ ϕ = y ≤ π. It implies
′ = f (S) =
ρe iϕ ∈ C | e − 1 ≤ ρ ≤ e, 0 ≤ ϕ ≤ π
The inequality e − 1 ≤ ρ ≤ e represents the annulus between two disks centered at the origin with radii e−^2 and e^2. The other inequality 0 ≤ ϕ ≤ π represents the upper–half space in the w–plane. Therefore, the region S ′ is the part of annulus lying in the upper–half space.
Answer. Using Cartesian Form. For z = x + iy ∈ S, we have
u(x, y) + iv(x, y) = f (z) = e x+iy = e x e iy = e x ( cos y + i sin y ) = e x cos y + ie x sin y,
i.e., u(x, y) = e x cos y and v(x, y) = e x sin y. For − 1 ≤ x ≤ 1 and 0 ≤ y ≤ π, we have e − 1 ≤ e x ≤ e and − 1 ≤ cos y ≤ 1 and 0 ≤ sin y ≤ 1. It implies
−e ≤ u(x, y) = e x cos y ≤ e, 0 ≤ v(x, y) = e x sin y ≤ e.
That is, for z ∈ S, the real and imaginary parts of f (z) = u + iv, Re(f (z)) = u(x, y) = ex^ cos y and Im(f (z)) = v(x, y) = ex^ sin y, should be in the intervals, −e ≤ u ≤ e and 0 ≤ v ≤ e, respectively.
Finally we observe that for z ∈ S,
u 2
2
2 = e 2 x (^ cos 2 y + sin 2 y
= e 2 x , e − 2 ≤ u 2
because − 1 ≤ x ≤ 1. Therefore we deduce
′ = f (S) =
u + iv = (u, v) ∈ C | e − 1 ≤ u ≤ e, 0 ≤ v ≤ e, e − 2 ≤ u 2
The graphs of u^2 + v^2 = e−^2 and u^2 + v^2 = e^2 are circles centered at the origin with the radius e−^2 and e^2 , respectively. Thus, the region S′^ is the part of annulus between two disks centered at the origin with radii e−^2 and e^2 and (u, v) ∈ [ e−^1 , e ] × [ 0, e ].
United Arab Emirates University College of Sciences Department of Mathematical Sciences
Complex Analysis I MATH 315 SECTION 01 CRN 23516 9:30 { 10:45 on Monday & Wednesday Due Date: Wednesday, November 25, 2009
Complex Analysis I EXAM 2 { SOLUTION Fall, 2009
z .
Proof. With z = x + iy, e z = e x iy = e x cos y ie x sin y:
Let u(x; y) = e x cos y and v(x; y) = e x sin y. Then we observe
ux = e x cos y = u; uy = e x sin y = v; vx = e x sin y = v; vy = e x cos y = u:
Only when u = 0 and v = 0, u and v satisfy the Cauchy{Riemann equations, i.e.,
ux = u = vy; uy = v = vx:
However, ex^ 0 for any x and there is no y satisfying both cos y = 0 and sin y = 0 simultane- ously. Therefore, f(z) is not di erentiable at any point.