If `|z-2|=2|z-1|`, then show that `|z|^(2)=(4)/(3)Re(z)`.

If |Z-2|=2|Z-1| , then the value of (Re(Z))/(|Z|^(2)) is (where Z is a complex number and Re(Z) represents the real part of Z)

If z=x+iy and |z-1|+|z+1|=4 show that 3x^(2)+4y^(2)=12

If z_(1),z_(2),z_(3),z_(4) are the affixes of four point in the Argand plane,z is the affix of a point such that |z-z_(1)|=|z-z_(2)|=|z-z_(3)|=|z-z_(4)| ,then prove that z_(1),z_(2),z_(3),z_(4) are concyclic.

If |z^(2)|=2Re(z) then the locus of z is

if z_(1),z_(2),z_(3),…..z_(n) are complex numbers such that |z_(1)|=|z_(2)| =….=|z_(n)| = |1/z_(1) +1/z_(2) + 1/z_(3) +….+1/z_(n)| =1 Then show that |z_(1) +z_(2) +z_(3) +……+z_(n)|=1

If |z_(1)|=2.|z_(2)|=3.|z_(3)|=4and|z_(1),+z_(2)+z_(3)|=2, then the value of |4z_(2)z_(3)+9z_(3)z_(1)+16z_(1)z_(2)|

If z_1,z_2,z_3 are vertices of a triangle such that |z_1-z_2|=|z_1-z_3| then arg ((2z_1-z_2-z_3)/(z_3-z_2)) is :

If |z-3|=min{|z-1|,|z-5|} , then Re(z) equals to

If z be any complex number such that |3z-2|+|3z+2|=4 , then show that locus of z is a line-segment.