is
defined to be COMPLEX ANALYSIS: Maple Worksheets,
2001
(c) John H. Mathews Russell W. Howell
mathews@fullerton.edu howell@westmont.edu
Complimentary software to accompany the textbook:
COMPLEX ANALYSIS: for Mathematics &
Engineering, 4th Ed, 2001, ISBN: 0-7637-1425-9
Jones and Bartlett Publishers, Inc., 40 Tall Pine Drive, Sudbury, MA
01776
Tele. (800) 832-0034; FAX: (508) 443-8000, E-mail: mkt@jbpub.com,
http://www.jbpub.com/
CHAPTER 1 COMPLEX
NUMBERS
Section 1.2 The Algebra of
Complex Numbers
We have seen that complex numbers
came to be viewed as ordered pairs of real numbers. That is, a
complex number
is
defined to be
.
The reason we say
ordered
pair is because we are thinking of a
point in the plane. The point (2, 3), for example, is not the same as
(3, 2). The
order
in which we write 
and 
in the equation makes a difference.
Clearly, then, two complex numbers are equal if and only if their
coordinates are equal
and
their 
coordinates are equal. In other
words,
iff 
and
.
If we are to have a meaningful
number system, there needs to be a method for combining these ordered
pairs. We need to define algebraic operations in a consistent way so
that the sum, difference, product, and quotient of any two ordered
pairs will again be an ordered pair. The key to defining how these
numbers should be manipulated is to follow Gauss' lead and equate
with 
. Then, by letting ![z[1] = (x[1], y[1])](images/C01-212.gif){kind=small}
and ![z[2] = (x[2], y[2])](images/C01-213.gif){kind=small}
be arbitrary complex numbers, we
have
![z[1]+z[2] = (x[1], y[1])+(x[2], y[2])](images/C01-214.gif){kind=small}
![z[1]+z[2] = x[1]+i*y[1]+x[2]+i*y[2]](images/C01-215.gif){kind=small}
![z[1]+z[2] = x[1]+x[2]+i*(y[1]+y[2])](images/C01-216.gif){kind=small}
![z[1]+z[2] = (x[1]+x[2], y[1]+y[2])](images/C01-217.gif){kind=small}
Thus, if ![z[1] = (x[1], y[1])](images/C01-218.gif){kind=small}
and ![z[2] = (x[2], y[2])](images/C01-219.gif){kind=small}
are arbitrary complex numbers, the
following definitions should make sense.
Definition 1.1: Addition
Formula (1-6), Page 7.
![z[1]+z[2] = (x[1]+x[2], y[1]+y[2])](images/C01-220.gif){kind=small}
Definition 1.2: Subtraction
Formula (1-7), Page 7.
![z[1]-z[2] = (x[1]-x[2], y[1]-y[2])](images/C01-221.gif){kind=small}
The rules for addition,
subtraction, multiplication and division of complex numbers
are extensions of the rules for real numbers. They obey familiar
algebraic properties.
Example 1.1, Page
7. Find
![z[1]+z[2]](images/C01-222.gif){kind=small}
and ![z[1]-z[2]](images/C01-223.gif){kind=small}
.
> z:='z':
Z1 := 3 + 7*I:
Z2 := 5 - 6*I:
z[1] = Z1;
z[2] = Z2; ` `;
z[1] + z[2] = Z1 + Z2;
z[1] - z[2] = Z1 - Z2;
![z[1] = 3+7*I](images/C01-224.gif){kind=small}
![z[2] = 5-6*I](images/C01-225.gif){kind=small}
![z[1]+z[2] = 8+I](images/C01-227.gif){kind=small}
![z[1]-z[2] = -2+13*I](images/C01-228.gif){kind=small}
Definition 1.3: Multiplication
Formula (1-8), Page 8.
![z[1]*z[2] = (x[1]*x[2]-y[1]*y[2], x[1]*y[2]+x[2]*y[...](images/C01-229.gif){kind=small}
Example 1.2, Page
8. Find
![z[1]*z[2]](images/C01-230.gif){kind=small}
.
> z:='z':
Z1 := 3 + 7*I:
Z2 := 5 - 6*I:
z[1] = Z1;
z[2] = Z2; ` `;
z[1]*z[2] = Z1*Z2;
![z[1] = 3+7*I](images/C01-231.gif){kind=small}
![z[2] = 5-6*I](images/C01-232.gif){kind=small}
![z[1]*z[2] = 57+17*I](images/C01-234.gif){kind=small}
Definition 1.4: Division
Formula (1-9), Page 9.
![z[1]/z[2] = ((x[1]*x[2]+y[1]*y[2])/(x[2]^2+y[2]^2),...](images/C01-235.gif)
Example 1.3, Page
9. Find
![z[1]/z[2]](images/C01-236.gif){kind=small}
.
> z:='z':
Z1 := 3 + 7*I:
Z2 := 5 - 6*I:
z[1] = Z1;
z[2] = Z2; ` `;
z[1]/z[2] = Z1/Z2;
![z[1] = 3+7*I](images/C01-237.gif){kind=small}
![z[2] = 5-6*I](images/C01-238.gif){kind=small}
![z[1]/z[2] = -27/61+53/61*I](images/C01-240.gif){kind=small}
Derivation for
Multiplication,
Formula (1-8), Page 8. In general we can derive:
> x:='x': y:='y':
z:='z':
Z1:='Z1': Z1 := x[1] + I*y[1]:
Z2:='Z2': Z2 := x[2] + I*y[2]:
z[1] = Z1;
z[2] = Z2; ` `;
z[1]*z[2] = Z1*Z2;
z[1]*z[2] = expand(Z1*Z2);
![z[1] = x[1]+I*y[1]](images/C01-241.gif){kind=small}
![z[2] = x[2]+I*y[2]](images/C01-242.gif){kind=small}
![z[1]*z[2] = (x[1]+I*y[1])*(x[2]+I*y[2])](images/C01-244.gif){kind=small}
![z[1]*z[2] = x[1]*x[2]+I*x[1]*y[2]+I*y[1]*x[2]-y[1]*...](images/C01-245.gif){kind=small}
Derivation for
Division, Formula
(1-9), Page 9. In general we can derive:
> d:='d': n:='n':
x:='x': y:='y': z:='z':
Z1:='Z1': Z1 := x[1] + I*y[1]:
Z2:='Z2': Z2 := x[2] + I*y[2]:
z[1] = Z1;
z[2] = Z2; ` `;
z[1]/z[2] = Z1/Z2;
n := expand(Z1*(x[2]-I*y[2])):
d := expand(Z2*(x[2]-I*y[2])):
z[1]/z[2] = n/d;
![z[1] = x[1]+I*y[1]](images/C01-246.gif){kind=small}
![z[2] = x[2]+I*y[2]](images/C01-247.gif){kind=small}
![z[1]/z[2] = (x[1]+I*y[1])/(x[2]+I*y[2])](images/C01-249.gif){kind=small}
![z[1]/z[2] = (x[1]*x[2]-I*x[1]*y[2]+I*y[1]*x[2]+y[1]...](images/C01-250.gif){kind=small}
Definition 1.5: Real Part
The
real part of
denoted 
is the real number
.
Definition 1.6: Imaginary Part
The
imaginary part of
denoted 
is the real number
.
Definition 1.7: Conjugate
The
conjugate of
denoted 
is the complex number
.
Example 1.4a, Page
12. Find
![Re(z[1])](images/C01-260.gif){kind=small}
and ![Re(z[2])](images/C01-261.gif){kind=small}
.
> z:='z':
Z1 := -3 + 7*I: z[1] = Z1;
Re(z[1]) = Re(Z1); ` `;
Z2 := 9 + 4*I: z[2] = Z2;
Re(z[2]) = Re(Z2);
![z[1] = -3+7*I](images/C01-262.gif){kind=small}
![Re(z[1]) = -3](images/C01-263.gif){kind=small}
![z[2] = 9+4*I](images/C01-265.gif){kind=small}
![Re(z[2]) = 9](images/C01-266.gif){kind=small}
Example 1.4b, Page
12. Find
![Im(z[1])](images/C01-267.gif){kind=small}
and ![Im(z[2])](images/C01-268.gif){kind=small}
.
> z:='z':
Z1 := -3 + 7*I: z[1] = Z1;
`Im(z1) ` = Im(Z1); ` `;
Z2 := 9 + 4*I: z[2] = Z2;
`Im(z2) ` = Im(Z2);
![z[1] = -3+7*I](images/C01-269.gif){kind=small}
![z[2] = 9+4*I](images/C01-272.gif){kind=small}
Example 1.4c, Page
12. Find
![conjugate(z[1])](images/C01-274.gif){kind=small}
and ![conjugate(z[2])](images/C01-275.gif){kind=small}
.
> z:='z':
Z1 := -3 + 7*I:
z[1] = Z1;
conjugate(z[1]) = conjugate(Z1); ` `;
Z2 := 9 + 4*I:
z[2] = Z2;
conjugate(z2) = conjugate(Z2);
![z[1] = -3+7*I](images/C01-276.gif){kind=small}
![conjugate(z[1]) = -3-7*I](images/C01-277.gif){kind=small}
![z[2] = 9+4*I](images/C01-279.gif){kind=small}
Derivation of the Commutative Law
for Addition,
Property (P1), Page 10.
In general we can derive:
> x:='x': y:='y':
z:='z':
Z1:='Z1': Z1 := x[1] + I*y[1]:
Z2:='Z2': Z2 := x[2] + I*y[2]:
z[1] = Z1;
z[2] = Z2; ` `;
`z1 + z2` = Z1 + Z2;
`z2 + z1` = Z2 + Z1; ` `;
`Does z1 + z2 = z2 + z1 ?`;
Z1+Z2 = Z2+Z1;
evalb(Z1+Z2 = Z2+Z1);
![z[1] = x[1]+I*y[1]](images/C01-281.gif){kind=small}
![z[2] = x[2]+I*y[2]](images/C01-282.gif){kind=small}
![`z1 + z2` = x[1]+I*y[1]+x[2]+I*y[2]](images/C01-284.gif){kind=small}
![`z2 + z1` = x[1]+I*y[1]+x[2]+I*y[2]](images/C01-285.gif){kind=small}
![x[1]+I*y[1]+x[2]+I*y[2] = x[1]+I*y[1]+x[2]+I*y[2]](images/C01-288.gif){kind=small}
Derivation of the Associative Law
for Multiplication,
Property (P6), Page 10.
In general we can derive:
> x:='x':
y:='y':
Z1 := x[1] + I*y[1]: `z1 ` = Z1;
Z2 := x[2] + I*y[2]: `z2 ` = Z2;
Z3 := x[3] + I*y[3]: `z3 ` = Z3;
w1 := Z1*(Z2 + Z3):
w2 := Z1*Z2 + Z1*Z3: ` `;
`z1*(z2 + z3) ` = w1;
`z1*z2 + z1*z3 ` = w2;
w1 := expand(w1):
w2 := expand(w2): ` `;
`z1*(z2 + z3) ` = w1;
`z1*z2 + z1*z3 ` = w2; ` `;
`Does z1*(z2 + z3) = z1*z2 + z1*z3 ?`;
evalb(w1 = w2);
![`z1 ` = x[1]+I*y[1]](images/C01-290.gif){kind=small}
![`z2 ` = x[2]+I*y[2]](images/C01-291.gif){kind=small}
![`z3 ` = x[3]+I*y[3]](images/C01-292.gif){kind=small}
![`z1*(z2 + z3) ` = (x[1]+I*y[1])*(x[2]+I*y[2]+x[3]+I...](images/C01-294.gif){kind=small}
![`z1*z2 + z1*z3 ` = (x[1]+I*y[1])*(x[2]+I*y[2])+(x[1...](images/C01-295.gif){kind=small}
![`z1*(z2 + z3) ` = x[1]*x[2]+I*x[1]*y[2]+x[1]*x[3]+I...](images/C01-297.gif){kind=small}
![`z1*z2 + z1*z3 ` = x[1]*x[2]+I*x[1]*y[2]+x[1]*x[3]+...](images/C01-298.gif){kind=small}
Theorem 1.1, Page 12.
Suppose ![z[1]](images/C01-2102.gif){kind=small}
, ![z[2]](images/C01-2103.gif){kind=small}
, and ![z[3]](images/C01-2104.gif){kind=small}
are arbitrary complex numbers. Then
(1-10) 
,
(1-11) ![conjugate(z[1]+z[2]) = conjugate(z[1])+conjugate(z[...](images/C01-2106.gif){kind=small}
,
(1-12) ![conjugate(z[1]*z[2]) = conjugate(z[1])*conjugate(z[...](images/C01-2107.gif){kind=small}
,
(1-13) ![conjugate(z[1]/z[2]) = conjugate(z[1])/conjugate(z[...](images/C01-2108.gif)
,
(1-14) 
,
(1-15) 
,
(1-16) 
,
(1-17) 
.
End of Section 1.2.