On multiplying numerator and denominator by (1-i), which is the inverse of the denominator, we get = {(1-i)^2}/{(1^2) - (i^2)} = {1 + (i^2) - 2i}/{(1^2) - (i^2)} = (1 - 1 - 2i)/{1 - (-1)} = (0 - ...

(-1-3i)/(1-3i) Complex Division Determine the conjugate of the denominator : The conjugate of  ( 1 -  3i)  is  ( 1 +  3i)  Multiply the numerator and denominator by the conjugate:  ( -  1 -  3i)•( ...

\displaystyle\frac{{{1}+{3}{i}}}{{{2}+{2}{i}}}={1}+\frac{{1}}{{2}}{i} Explanation: Multiply numerator and denominator by the Complex conjugate of the numerator first: \displaystyle\frac{{{1}+{3}{i}}}{{{2}+{2}{i}}}=\frac{{{\left({1}+{3}{i}\right)}{\left({2}-{2}{i}\right)}}}{{{\left({2}+{2}{i}\right)}{\left({2}-{2}{i}\right)}}}=\frac{{{8}+{4}{i}}}{{8}}={1}+\frac{{1}}{{2}}{i}

Notice: \left|\frac{z}{s}\right|=\frac{\left|z\right|}{\left|s\right|} So: \left|\frac{-4-6i}{17+i}\right|=\frac{\left|-4-6i\right|}{\left|17+i\right|}=\frac{\sqrt{(-4)^2+(-6)^2}}{\sqrt{(17)^2+(1)^2}}=\frac{\sqrt{52}}{\sqrt{290}}=\sqrt{\frac{26}{145}}=\frac{\sqrt{3770}}{145}

\frac{1-ia}{1+ia} =\frac{(1-ia)^2}{1-i^2a^2} =\frac{1-a^2-2ia}{1+a^2} =\frac{1-a^2}{1+a^2}+i\frac{-2a}{1+a^2} So we have arg\left(\frac{1-ia}{1+ia}\right)=\arctan\left(\frac{2a}{1-a^2}\right)=2\arctan a = \arccos \left(\frac{1-a^2}{1+a^2}\right)

Hint: If p and q are both real, then one complex equation becomes two simultaneous real equations. Substitute one of the roots to obtain (1+2i)^2 + (p+5i)(1+2i) + q(2-i) = 0 (-3 + 4i) + (p-10) + (5+2p)i + (2q - qi) = 0 ...