Functions of Complex Variables
Functions of Complex Variables
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| |This unit is mainly devoted in presenting basic concepts on Complex Numbers, Complex Analytic Functions, the Cauchy-Riemann | |
| |Equations, Laplace’s Equations, Elementary Complex Functions (Exponential Functions, Ttrigonometric Functions and Hyperbolic | |
| |Functions), Line Integral in the Complex Plane, Cauchy’s Integral Theorems, Derivatives of Analytic Functions, Power Sseries, Taylor| |
| |Series, Laurent Series, Residue Integration and Evaluation of Real Integrals. | |
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4.1 Definition of Complex Numbers
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| |The concept of complex number basically arises from the need of solving equations that has no real solutions. Though the Italian | |
| |mathematician GIROLAMO CARDANO used the idea of complex numbers for soving cubic equation the term “complex numbers” was introduced | |
| |by the German mathematician CARL FRIEDRICH GAUSS. | |
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|Definition 4.1 A complex number z is an ordered pair (x, y) of real numbers |
|x and y, written z = (x, y), x is called the real part and y the imaginary |
|part of z, usually the real and imaginary parts of the complex number |
|z = (x, y) are denoted by |
|x = Re z and y = Im z. |
| |
|Definition 4.2 Two complex numbers are equal if and only if their |
|corresponding real and imaginary parts are equal. |
Example 4.1 Find the values of ( and ( for which the complex numbers[pic].
Solution By definition 4.2
[pic] ( [pic] ( [pic].
Therefore, [pic].
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|Definition 4.3 The complex number (0,1) usually denoted by i = (0,1) is |
|called imaginary unit |
4.1.1 Addition and Multiplication on Complex Numbers
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|Definition 4.4 For any two complex numbers [pic] and [pic] |
|i) [pic] ( [pic] = [pic] |
|ii) [pic] |
Note that: Any real number x can be written as x = (x, 0) and hence the set of complex numbers
extend the reals.
Example 4.2 Let[pic],[pic]( (. Then from definition 4.4 we get:
[pic] +[pic] = [pic] and [pic][pic] = [pic]
Furthermore; for any real numbers x and y,
i y = [pic](y, 0) = (0, y) and (x, y) = (x, 0) + (0, y) = x + i y.
Conequentely; for any real numbers x and y,
i y = (0, y) and (x, y) = x + i y.
Note that: 1. For any non-zero real number y, z = i y is called pure imaginary number.
2. Any point on the x-axis has coordinates of the form (x, 0) that corresponds to the
complex number x = x + 0 i, due to this reason the x-axis is called the real axis.
3. Any point on the y-axis has coordinates of the form (0, y) that corresponds to the
complex number i y = 0 + i y, and hence it is called the imaginary axis.
4.1.2 Properties of Addition and Multiplication
Let [pic], [pic]and [pic] be complex numbers. Then
i) [pic]+[pic] = [pic]+ [pic]and [pic][pic] = [pic][pic]
ii) ([pic]+[pic]) + [pic] = [pic]+ ([pic]+[pic]) and ([pic][pic])[pic]=[pic]([pic][pic])
iii) [pic]([pic] +[pic]) = [pic][pic] +[pic][pic]
iv) 0 +[pic]= [pic], [pic]+ (( [pic]) = 0 and[pic]= [pic]
Furthermore; for any non-zero complex number z = x + i y, there is a complex number [pic] such that [pic].
The complex number [pic]is usually denoted [pic].
Consequentely;
[pic]= [pic] = [pic]= [pic].
Therore, any non-zero complex number z = x + i y has a unique multiplicative inverse given by:
[pic] = [pic].
The set of complex numbers form a field. However, it is not possible to define an order relation on the set of complex numbers. Since the expressions like z > 0, [pic]< [pic]etc are meaningless unless these complex numbers are reals.
4.1.3 Complex Plane
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| |The concept of expressing a complex number (x, y) as a point in the coordinate plane was first introduced by Jean Robert Argand | |
| |(1768-1822), a swiss bookkeeper. The plane formed by a one to one correspondence of complex numbers and points on the coordinate | |
| |plane is called the Argand diagram, or the complex plane or the z-plane. | |
| | | |
In the Argand diagram the x-axis is the real axis and the y-axis is called the imaginary axis
|[pic] |In a complex plane any complex number |
| |z = x + i y is represented as the point z with co-ordinate x and |
| |ordinate y, and we say the point z in the complex plane. |
The sum of two complex numbers can be geometrically interpreted as the sum of two position vectors in the Argand diagram.
|[pic] |
4.1.4 Complex Conjugate
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|Definition 4.5 Let z = x + i y be a complex number. Then the complex conjugate |
|of z (or simply the conjugate of z) denoted [pic] is defined by |
|[pic]= x ( i y |
For any complex number z = x + i y in the complex plane, the complex conjugate of z,[pic]= x ( i y
is obtained by reflecting z in the real axis.
Example 4.3 Let z = x + i y be any complex number. Then verify that
i) [pic] ii) Re z = [pic](z + [pic]) iii) Im z = [pic](z ( [pic])
Solutions Using properties of addition and multiplication on complex numbers and definition 4.5 we get:
i) [pic]= [pic]= [pic]= [pic].
Therefore, [pic]= [pic].
ii) [pic](z + [pic]) = [pic][pic] = x = Re z .
Therefore, Re z = [pic](z +[pic]).
iii) [pic][pic]= [pic][pic]= y = Im z.
Therefore, z = [pic](z ( [pic]).
Example 4.4 Let [pic]and [pic]be two complex numbers. Show that:
i) [pic] = [pic] ( [pic] ii) [pic] =[pic][pic] iii) [pic], provided that[pic]( 0.
Solutions Let [pic]and[pic]. Then From the properties of addition and
multiplication on complex numbers and definition 4.5 we get:
i) [pic] = [pic] = [pic]
= [pic]=[pic]=[pic] ( [pic]
Therefore, [pic] = [pic] ( [pic] for any two complex numbers[pic]and[pic].
ii) [pic] =[pic] = [pic]
= [pic]= [pic]=[pic][pic].
Therefore, [pic] =[pic][pic]for any two complex numbers[pic]and[pic].
iii) [pic]= [pic]= [pic]= [pic]= [pic] = [pic].
Therefore, [pic]= [pic], provided that[pic]( 0.
4.1.5 Polar Form of Complex Numbers
The Cartesian coordinates x and y can be transformed into polar coordinates r and ( by
x = r cos ( and y = r sin (
For any complex number z = x + i y the form
z = r (cos ( + i sin ()
is called the polar form of z, where r is the absolute value or modulus of z. The modulus of z is usually denoted and defined by
[pic] = r = [pic] = [pic]
while ( is called the argument of z and is denoted and defined by
arg z = ( = [pic] , up to multiples of 2(.
The value of ( that lies in the interval ( ( < ( ( ( is called the principal value of the argument of z and denoted by Arg z.
Note that: the value of (, measured in radian, depends on the quadrant in which the complex
number z belongs.
Example 4.5 Write z = (1 + i in polar form.
Solution To write z in polar form first we need to find [pic]and Arg z.
[pic]= ((1 + i) ((1 ( i) = 2 and hence [pic] = [pic]
and ( = arg z = [pic]= [pic] where n ( Z, but z lies in the second quadrant ,
hence, Arg z = [pic].
Therefore, z = [pic][pic].
Example 4.6 Write z = (1 ( i in polar form.
Solution To write z in polar form first we need to find[pic]and Arg z.
[pic]= ((1 ( i) ((1 + i) = 2 and hence [pic] = [pic]
and ( = arg z =[pic]= [pic] where n ( Z, but z lies in the third quadrant ,
hence, Arg z = [pic].
Therefore, z = [pic][pic].
4.1.6 Important Inequalities
For any two complex numbers[pic] and[pic]
[pic]([pic]+[pic] (Triangle Inequality)
To show that this holds true, let [pic]= [pic] and [pic]=[pic].
Then [pic]= [pic]
= [pic]+ [pic] + [pic]
( [pic]+ [pic] + [pic]( [pic]
Therefore, [pic]([pic]+[pic].
Furthermore; for any finite number of complex numbers [pic],[pic], . . . , [pic]
[pic] ( [pic] (Generalized triangle inequality)
Verify! (Hint: use the principle of Mathematical induction on n)
Example 4.7 Let [pic]= [pic] and [pic]= [pic]. Find [pic]and [pic]+[pic].
Solution [pic]= [pic]= [pic]=[pic],
[pic]=[pic]=[pic]= [pic]
and [pic]=[pic]=[pic] =[pic].
Therefore, [pic]( [pic] +[pic].
4.1.7 Multiplication and Division in Polar Form
Let [pic]= [pic]and [pic]= [pic].
Multiplication
[pic]= [pic]
= [pic]
Therefore,[pic] = [pic][pic]and arg ([pic]) = arg ([pic]) + arg ([pic]) up to multiplies of 2(.
Division
The quotient [pic]is the number z = [pic]satisfying z[pic]= [pic].
Thus arg (z[pic]) = arg z + arg [pic]= arg [pic]and [pic] = [pic][pic]= [pic].
Hence, [pic]= [pic] and arg ([pic]) = arg ([pic]) ( arg ([pic]) up to multiplies of 2(.
Therefore, [pic]= [pic].
Example 4.8 Let [pic]= [pic]and [pic]= [pic]. Express [pic][pic] and [pic]in polar forms.
Solution [pic]= [pic]= 2 and [pic]= [pic]= 3
and arg ([pic]) = [pic] = [pic] where n ( Z.
But [pic]lies in the [pic]quadrant, hence Arg [pic]= [pic] arg [pic]= [pic], where n ( Z. But [pic]
lies in the positive imaginary axis, hence Arg [pic]= [pic]. Thus[pic]= [pic]and [pic]= [pic].
Therefore, [pic][pic] = 6 [pic] and [pic]= [pic].
4.1.8 Integer powers of Complex Numbers
For any non-zero complex number[pic]
[pic]for any n ( Z.
In particular if [pic] = 1, then we get the De Moivre formula
[pic]for any n ( Z.
Example 4.9 Use the De moivre formula to show that for any angle (
[pic]and [pic]
Solution If n = 2, then
[pic]
and from the De Moivre formula we get:
[pic]
Therefore, [pic]and [pic]
4.1.9 Roots of Complex Numbers
Suppose Z is a non-zero complex number. Now we need to solve [pic], where n ( N and n ( 1.
Note that: Each values of ( is called an [pic]root of z, and we write
[pic]
Let z = [pic] and ( = [pic].
Then [pic]( [pic]= [pic]
( [pic], cos ( = cos n ( and sin ( = sin n ( .
( [pic], [pic], where k ( Z.
Note that: For any k ( Z, there exist integers m and h such that
k = m n + h, where h ((0, 1, 2, 3, . . . , n ( 1(
Let [pic]. Then [pic]= [pic]
and [pic]= [pic]
Therefore, [pic], where, k = 0, 1, 2, 3, . . . , n ( 1.
Note that: These n values lie on a circle of radius [pic]with center at the origin and constitute the
vertices of a regular n-gon.
The value of [pic]obtained by taking the principal value of arg z is called the principal value of
( = [pic].
Example 4.1.10 [pic]root of unity
Solve the equation [pic]= 1.
Solution Now [pic]=[pic], k = 0, 1, 2, 3, . . . , n ( 1.
If ( denotes the value corresponding to k = 1, then the n values of [pic] can be written as
1,[pic],[pic], . . .,[pic]
Hence let ( = [pic].
Therefore, 1,[pic],[pic], . . .,[pic]are the [pic]roots of unity.
Example 4.1.11 Solve the equation[pic]= 1.
Solution Now [pic]= [pic], where k = 0, 1, 2, 3.
Then for k = 1 we get ( =[pic].
Therefore, 1,[pic],(1 and ([pic] are the [pic]roots of unity.
Note that: The n values of[pic] are:
[pic],[pic],[pic], . . . ,[pic]
where [pic]= [pic] and [pic]is real.
Note that: For any complex number[pic],
[pic]= [pic] [pic] ( [pic],
where [pic].
= [pic].
Therefore, [pic]= ([pic], where [pic].
Exercise 4.1
1. Write in the form x ( i y, where [pic]= 4 ( 5 i and [pic] = 2 + 3 i
i) [pic] ii) [pic] iii) [pic]
2. Find the real and the imaginary parts of i) ( iii) in exercise 1.
3. Let [pic]and[pic]be complex numbers, if [pic][pic]= 0, then show that either[pic]= 0 or[pic]= 0.
4. Compute [pic]
5. Represent [pic]in polar form.
6. Determine the principal value of the argument of
i) [pic] ii) [pic]
7. Represent each of the following in the form [pic]
i) [pic] ii) [pic]
8. Solve the equation
i) [pic] ii) [pic]
9. For any two complex numbers [pic]and [pic] show that
[pic] + [pic]= [pic] (Parallelogram equality)
4.2 Curves and Regions in the Complex Plane
4.2.1 Circles and Disks
The distance between two points z and [pic] in the complex plane is denoted by[pic]. Hence a circle C of radius[pic]and center [pic]can be given by
[pic] = [pic]
In particular the unit circle with center at the origin is given by[pic] = 1
Furthermore;
i) [pic][pic] represents the exterior of the circle C.
iii) [pic] 9 is the exterior of the circle of radius 9 centered at ( 2 + [pic].
4.2.2 Half plane
i) (open) upper half - plane = [pic]
ii) (open) lower half-plane = [pic]
iii) (open) right half plane = [pic]
iv) (open) left -half plane = [pic]
4.2.2.1 Concepts Related to Sets in the Complex Plane
Now we need to define some important terms.
i) Neighborhoods
A delta, δ neighborhood of a point [pic]is the set of all points z such that [pic]< δ where δ is any given positive number. (a deleted δ-neighborhood of [pic]is a neighborhood of [pic]in which the point [pic]is omitted i.e. 0 ................
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