Question

How do you convert $-2+2i$ to polar form?

Answer 1

We will try to convert to polar form by determining the modulus form and the angle of the complex number $-2+2i$. The polar form $z=x+iy$ is $z=r\left( \cos \alpha +i\sin \alpha \right)$. We need to take the angle of the complex number according to its position on the plane.

Complete step-by-step answer:
We will follow the process of converting regular forms of complex numbers to their polar form.
Let’s assume the general form of the complex number is $z=x+iy$.
Here $i$ represents the complex number and $x$ and $y$ are real constants.
Then we find the modulus value for the complex number as $r=\left| z \right|=\sqrt{{{x}^{2}}+{{y}^{2}}}$.
Also, to find the angle $\alpha$ we can say that $x=r\cos \alpha ,y=r\sin \alpha$.
The simplest form for the angle $\alpha$ is $\tan \alpha =\dfrac{y}{x}$.
Therefore, the polar form representation of the complex number $z=x+iy$ is
$z=r\left( \cos \alpha +i\sin \alpha \right)$.
Now for our given complex number $-2+2i$, we equate it with $z=x+iy$.
We try to find the polar form of the $-2+2i$.
Equating values, we get $x=-2,y=2$.
The modulus value for the complex number will be $r=\sqrt{{{\left( -2 \right)}^{2}}+{{2}^{2}}}=2\sqrt{2}$.
Now we find the angle value which is $\alpha$.
The representation of the $-2+2i$ gives the point at the second quadrant.
This means the angle will be in the interval of $\dfrac{\pi }{2}\le \alpha \le \pi$
We get $\tan \alpha =\dfrac{y}{x}=\dfrac{2}{-2}=-1$. We need to find the exact solution for the inverse where the angle is in the second quadrant.
So, $\tan \alpha =-1=\tan \left( \dfrac{\pi }{2}+\dfrac{\pi }{4} \right)$. The angle is $\left( \dfrac{3\pi }{4} \right)$.
Now we form the polar form and get $-2+2i=2\sqrt{2}\left[ \cos \left( \dfrac{3\pi }{4} \right)+i\sin \left( \dfrac{3\pi }{4} \right) \right]$.

Note: The usual angle value for $\tan \alpha =-1$ would have been $\left( -\dfrac{\pi }{4} \right)$. But the position of the complex number is in the angle interval of $\dfrac{\pi }{2}\le \alpha \le \pi$. That’s why we had to place the angle in that position to get the value of $\tan \alpha =-1$.