<a href="http://www.codecogs.com/eqnedit.php?latex=\\ z^5=1=cis0=cis2k\pi\\ z=(cis2k\pi)^{\frac{1}{5}}=cis\frac{2}{5}k\pi_{(k=0,1,2,3,4,)}~\textrm{(By De Moivre's theorem)}\\ ~\\ z_1=cis0=1~~~~~~ z_2=cis\frac{2}{5}\pi~~~~~ z_3=cis\frac{4}{5}\pi~~~~~ z_4=cis\frac{6}{5}\pi~~~~~ z_5=cis\frac{8}{5}\pi\\ ~\\ \therefore w=z_2=cis\frac{2}{5}\pi~\textrm{(Since it's the root with the smallest positive argument)}\\ z_3=(z_2)^2,~~~~~ z_4=(z_2)^3,~~~~~ z_5=(z_2)^4~\textrm{(By De Doivre's theorem)}\\ \therefore \textrm{the other complex roots are}~w^2,w^3, w^4 ~\\~\\~\\~\\ \frac{-b}{a}=\alpha@plus;\beta=w@plus;w^2@plus;w^3@plus;w^4=-1~(\textrm{since}~1@plus;w@plus;w^2@plus;w^3@plus;w^4=0)\\ \therefore b=1\\ ~\\ \frac{c}{a}=\alpha \beta=(w@plus;w^4)(w^2@plus;w^3)\\ =w^3@plus;w^4@plus;w^6@plus;w^7=w^3@plus;w^4@plus;w@plus;w^2=-1~(\textrm{since}~w^5=1)\\ \therefore c=-1\\~\\ \therefore \textrm{the required quadratic equation is}~x^2@plus;x-1" target="_blank"><img src="http://latex.codecogs.com/gif.latex?\\ z^5=1=cis0=cis2k\pi\\ z=(cis2k\pi)^{\frac{1}{5}}=cis\frac{2}{5}k\pi_{(k=0,1,2,3,4,)}~\textrm{(By De Moivre's theorem)}\\ ~\\ z_1=cis0=1~~~~~~ z_2=cis\frac{2}{5}\pi~~~~~ z_3=cis\frac{4}{5}\pi~~~~~ z_4=cis\frac{6}{5}\pi~~~~~ z_5=cis\frac{8}{5}\pi\\ ~\\ \therefore w=z_2=cis\frac{2}{5}\pi~\textrm{(Since it's the root with the smallest positive argument)}\\ z_3=(z_2)^2,~~~~~ z_4=(z_2)^3,~~~~~ z_5=(z_2)^4~\textrm{(By De Doivre's theorem)}\\ \therefore \textrm{the other complex roots are}~w^2,w^3, w^4 ~\\~\\~\\~\\ \frac{-b}{a}=\alpha+\beta=w+w^2+w^3+w^4=-1~(\textrm{since}~1+w+w^2+w^3+w^4=0)\\ \therefore b=1\\ ~\\ \frac{c}{a}=\alpha \beta=(w+w^4)(w^2+w^3)\\ =w^3+w^4+w^6+w^7=w^3+w^4+w+w^2=-1~(\textrm{since}~w^5=1)\\ \therefore c=-1\\~\\ \therefore \textrm{the required quadratic equation is}~x^2+x-1" title="\\ z^5=1=cis0=cis2k\pi\\ z=(cis2k\pi)^{\frac{1}{5}}=cis\frac{2}{5}k\pi_{(k=0,1,2,3,4,)}~\textrm{(By De Moivre's theorem)}\\ ~\\ z_1=cis0=1~~~~~~ z_2=cis\frac{2}{5}\pi~~~~~ z_3=cis\frac{4}{5}\pi~~~~~ z_4=cis\frac{6}{5}\pi~~~~~ z_5=cis\frac{8}{5}\pi\\ ~\\ \therefore w=z_2=cis\frac{2}{5}\pi~\textrm{(Since it's the root with the smallest positive argument)}\\ z_3=(z_2)^2,~~~~~ z_4=(z_2)^3,~~~~~ z_5=(z_2)^4~\textrm{(By De Doivre's theorem)}\\ \therefore \textrm{the other complex roots are}~w^2,w^3, w^4 ~\\~\\~\\~\\ \frac{-b}{a}=\alpha+\beta=w+w^2+w^3+w^4=-1~(\textrm{since}~1+w+w^2+w^3+w^4=0)\\ \therefore b=1\\ ~\\ \frac{c}{a}=\alpha \beta=(w+w^4)(w^2+w^3)\\ =w^3+w^4+w^6+w^7=w^3+w^4+w+w^2=-1~(\textrm{since}~w^5=1)\\ \therefore c=-1\\~\\ \therefore \textrm{the required quadratic equation is}~x^2+x-1" /></a>
