Modulus of (z^3): [ |z^3| = \sqrt(-8\sqrt2)^2 + (8\sqrt2)^2 = \sqrt128 + 128 = \sqrt256 = 16. ] Argument of (z^3): [ \tan\theta = \frac8\sqrt2-8\sqrt2 = -1. ] Point is in 2nd quadrant (negative real, positive imag), so [ \arg(z^3) = \pi - \frac\pi4 = \frac3\pi4. ] Thus [ z^3 = 16 e^i(3\pi/4 + 2k\pi). ] Taking cube roots: [ z = \sqrt[3]16 ; e^i\left(\frac\pi4 + \frac2k\pi3\right), \quad k=0,1,2. ] (\sqrt[3]16 = 16^1/3 = 2^4/3 = 2\sqrt[3]2) but wait — check carefully: Actually (16^1/3 = (2^4)^1/3 = 2^4/3). Yes. But sometimes they keep as (2\sqrt[3]2). We’ll keep exact.
(c) Find the exact area of the triangle formed by these three roots. Mjc 2010 H2 Math Prelim
(b) On a single Argand diagram, sketch the three roots. Modulus of (z^3): [ |z^3| = \sqrt(-8\sqrt2)^2 +
The complex number (z) satisfies the equation [ z^3 = -8\sqrt2 + 8\sqrt2 i. ] ] Thus [ z^3 = 16 e^i(3\pi/4 + 2k\pi)
(a) Find the modulus and argument of (z^3), hence find the three roots of the equation in the form (r e^i\theta) where (r>0) and (-\pi < \theta \le \pi).
So roots: [ z_0 = \sqrt[3]16 , e^i\pi/4, \quad z_1 = \sqrt[3]16 , e^i11\pi/12, \quad z_2 = \sqrt[3]16 , e^-i5\pi/12. ] Argand diagram: points on circle radius (\sqrt[3]16 \approx 2.52), arguments (\pi/4) (45°), (165°), (-75°). (c) Area of triangle = (\frac3\sqrt34 R^2) where (R = \sqrt[3]16).