As others said, the atan2 takes two arguments to be able to determine the quadrant of the output angle properly...

However, it still outputs an angle between `[-pi,pi]`

, which is not always useful (positive `[0,pi]`

for 1st and 2nd quadrants; and negative `[-pi,0]`

for 3rd and 4th).

It's possible to define an `atan`

function that returns an angle in `[0,2pi]`

, as theodore panagos showed.

Improving on theodore panagos' answer, here is a python version using numpy

```
import numpy
# defining the atan function
myatan = lambda x,y: numpy.pi*(1.0-0.5*(1+numpy.sign(x))*(1-numpy.sign(y**2))\
-0.25*(2+numpy.sign(x))*numpy.sign(y))\
-numpy.sign(x*y)*numpy.arctan((numpy.abs(x)-numpy.abs(y))/(numpy.abs(x)+numpy.abs(y)))
#testing
u = numpy.array([[numpy.sqrt(3.0)/2.0,0.5], # expected: 30
[0.5,numpy.sqrt(3.0)/2.0], # expected: 60
[0.0,1.0], # expected: 90
[-0.5,numpy.sqrt(3.0)/2.0], # expected: 120
[-numpy.sqrt(3.0)/2.0,0.5], # expected: 150
[-1.0,0.0], # expected: 180
[-numpy.sqrt(3.0)/2.0,-0.5], # expected: 210
[-0.5,-numpy.sqrt(3.0)/2.0], # expected: 240
[0.0,-1.0], # expected: 270
[0.5,-numpy.sqrt(3.0)/2.0], # expected: 300
[numpy.sqrt(3.0)/2.0,-0.5], # expected: 330
[1.0,0.0]]) # expected: 0 or 360
theta = myatan(u[:,0],u[:,1])
print(theta * 180.0/numpy.pi) # converting to degrees
```

output:

```
[ 30. 60. 90. 120. 150. 180. 210. 240. 270. 300. 330. 0.]
```

it does not output 360 exactly, but it goes through up to it, then it cycles, as expected

`atan2`

actually provides the correct quadrant with respect to the unit circle for your angle.