Basic Algebraic Properties For Complex Numbers





Basic Algebraic Properties

Note. We use several algebraic properties of the real numbers to verify corresponding properties of complex numbers. As we should at this level, we give the results in a theorem/proof format.

Theorem:
\[For\;any\;\;{z_1},{z_2},{z_3} \in C\;\;\;\;,\;we\;have\;the\;following:\]

1. Commutivity of addition and multiplication:
\[{z_1} + {z_2} = {z_2} + {z_1}\;\;\;\;\;\;,\;and\;\;\;{z_1}{z_2} = {z_2}{z_1}\;\]

2. Associativity of addition and multiplication:
\[\left( {{z_1} + {z_2}} \right) + {z_3} = {z_1} + ({z_2} + {z_3})\;\;\;\;\;,\;and\;\left( {\;{z_1}{z_2}} \right){z_3} = {z_1}({z_2}{z_3})\]

3. Distribution of multiplication over addition:
\[{z_1}({z_2} + {z_3}) = {z_1}{z_2} + {z_2}{z_3}\]

4. There is an additive identity 0 = 0 + i0 such that 0 + z = z for all z C. There is a multiplicative identity 1 = 1 + i0 such that z1 = z for all z C. Also, z0 = 0 for all z C.

5. For each z C there is z' C such that z' + z = 0. z0 is the additive inverse of z (denoted -z). If z doesn't equal 0, then there is z'' C such that z'' z = 1. z'' is the multiplicative inverse of z (denoted z-1).




Note. When we consider division it is, by definition, multiplication by the multiplicative inverse.
\[\begin{array}{l} So\;for\;z \ne 0\;,\;{z^{ - 1}}\;is\;denoted\;\frac{1}{z}\;and\;so\;\frac{{{z_1}}}{{{z_2}}}\;means\;{z_1}z_2^{ - 1}\;.\\ \;We\;see\;that\;for\;z = x + iy\;:\\ {z^{ - 1}} = \frac{1}{z} = \frac{x}{{{x^2} + {y^2}}} + i\frac{{ - y}}{{{x^2} + {y^2}}} \end{array}\]

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