# Python conversion between coordinates

Are there functions for conversion between different coordinate systems?

For example, Matlab has `[rho,phi] = cart2pol(x,y)` for conversion from cartesian to polar coordinates. Seems like it should be in numpy or scipy.

Using numpy, you can define the following:

``````import numpy as np

def cart2pol(x, y):
rho = np.sqrt(x**2 + y**2)
phi = np.arctan2(y, x)
return(rho, phi)

def pol2cart(rho, phi):
x = rho * np.cos(phi)
y = rho * np.sin(phi)
return(x, y)
``````
• In case one doesn't have x and y separately, but inside one numpy array, `numpy.linalg.norm(arr)` comes in handy as alternative to `np.sqrt(arr[:, 0]**2....)` Commented Feb 20, 2016 at 5:27
• Alternately arr**2 will square all the elements independently, next you np.sum(arr,axis=1) the rows, then finally **.5 to sqrt it as well. Commented Apr 18, 2017 at 23:16
• and then what? what do you do with x,y? Commented Sep 9, 2017 at 1:08

The existing answers can be simplified:

``````from numpy import exp, abs, angle

def polar2z(r,theta):
return r * exp( 1j * theta )

def z2polar(z):
return ( abs(z), angle(z) )
``````

Or even:

``````polar2z = lambda r,θ: r * exp( 1j * θ )
z2polar = lambda z: ( abs(z), angle(z) )
``````

Note these also work on arrays!

``````rS, thetaS = z2polar( [z1,z2,z3] )
zS = polar2z( rS, thetaS )
``````
• I like this, but since the question starts with x and y (not z), I would add the simple line `z = x + 1j * y` Commented Aug 14, 2017 at 12:49
• how does this work? polar2z returns a single argument! Commented Sep 9, 2017 at 1:06
• @johnktejik `z = polar2z(r,theta)` then `x = np.real(z)` and `y = np.imag(z)` Also, `np.angle()` has a `deg` option which returns degrees instead of radians. You could just pass that through `z2polar()` if you want degrees. Commented Dec 21, 2017 at 0:47
• This seems to assume that `z` is expressed as a complex number. For other forms, you'd have to first convert to complex, then apply this function. Commented Jul 2, 2018 at 16:39
• `np.angle(z)` internally extracts the real and imaginary part of the complex number `z` and uses `np.arctan2(zimag, zreal)` on them. The answer by @nzh avoids unnecessary conversions Commented Oct 30, 2019 at 15:46

You can use the cmath module.

If the number is converted to a complex format, then it becomes easier to just call the polar method on the number.

``````import cmath
input_num = complex(1, 2) # stored as 1+2j
r, phi = cmath.polar(input_num)
``````

If you can't find it in numpy or scipy, here are a couple of quick functions and a point class:

``````import math

def rect(r, theta):
"""theta in degrees

returns tuple; (float, float); (x,y)
"""
return x,y

def polar(x, y):
"""returns r, theta(degrees)
"""
r = (x ** 2 + y ** 2) ** .5
theta = math.degrees(math.atan2(y,x))
return r, theta

class Point(object):
def __init__(self, x=None, y=None, r=None, theta=None):
"""x and y or r and theta(degrees)
"""
if x and y:
self.c_polar(x, y)
elif r and theta:
self.c_rect(r, theta)
else:
raise ValueError('Must specify x and y or r and theta')
def c_polar(self, x, y, f = polar):
self._x = x
self._y = y
self._r, self._theta = f(self._x, self._y)
def c_rect(self, r, theta, f = rect):
"""theta in degrees
"""
self._r = r
self._theta = theta
self._x, self._y = f(self._r, self._theta)
def setx(self, x):
self.c_polar(x, self._y)
def getx(self):
return self._x
x = property(fget = getx, fset = setx)
def sety(self, y):
self.c_polar(self._x, y)
def gety(self):
return self._y
y = property(fget = gety, fset = sety)
def setxy(self, x, y):
self.c_polar(x, y)
def getxy(self):
return self._x, self._y
xy = property(fget = getxy, fset = setxy)
def setr(self, r):
self.c_rect(r, self._theta)
def getr(self):
return self._r
r = property(fget = getr, fset = setr)
def settheta(self, theta):
"""theta in degrees
"""
self.c_rect(self._r, theta)
def gettheta(self):
return self._theta
theta = property(fget = gettheta, fset = settheta)
def set_r_theta(self, r, theta):
"""theta in degrees
"""
self.c_rect(r, theta)
def get_r_theta(self):
return self._r, self._theta
r_theta = property(fget = get_r_theta, fset = set_r_theta)
def __str__(self):
return '({},{})'.format(self._x, self._y)
``````

There is a better way to write a method to convert from Cartesian to polar coordinates; here it is:

``````import numpy as np
def polar(x, y) -> tuple:
"""returns rho, theta (degrees)"""
return np.hypot(x, y), np.degrees(np.arctan2(y, x))
``````
• Why should it be better? It isn't vectorized. Commented Jun 13, 2018 at 10:07
• Ok, then use np.hypot. The point is that you should never write sqrt(x2+y2). hypot exists for a reason. Commented Jun 14, 2018 at 8:15
• From KeithB's comment, `return np.hypot(x, y), np.arctan2(y, x)` Commented May 10, 2019 at 4:45
• @mLstudent33: Obviously `polar` converts Cartesian (x,y) into polar (rho theta), what you need if the function which converts (rho, theta) into (x,y), see other answers for sophisticated methods or just use simple cos/sin as in this answer.
– mins
Commented Mar 27, 2021 at 14:33
• Sorry for the necro. Why "you should never write `sqrt(x**2+y**2)`"?. In my test `sqrt(x**2+y**2)` is more then 50% faster then `np.hypot(x,y)`. Commented Oct 26, 2022 at 8:11

If your coordinates are stored as complex numbers you can use cmath

Mix of all the above answers which suits me:

``````import numpy as np

def pol2cart(r,theta):
'''
Parameters:
- r: float, vector amplitude
- theta: float, vector angle
Returns:
- x: float, x coord. of vector end
- y: float, y coord. of vector end
'''

z = r * np.exp(1j * theta)
x, y = z.real, z.imag

return x, y

def cart2pol(x, y):
'''
Parameters:
- x: float, x coord. of vector end
- y: float, y coord. of vector end
Returns:
- r: float, vector amplitude
- theta: float, vector angle
'''

z = x + y * 1j
r,theta = np.abs(z), np.angle(z)

return r,theta
``````

In case, like me, you're trying to control a robot that accepts a speed and heading value based off of a joystick value, use this instead (it converts the radians to degrees:

``````def cart2pol(x, y):
rho = np.sqrt(x**2 + y**2)
phi = np.arctan2(y, x)
return(rho, math.degrees(phi))
``````

If you have an array of `(x,y)` coordinates or `(rho, phi)` coordinates you can transform them all at once with numpy.

The functions return an array of converted coordinates.

``````import numpy as np

def combine2Coord(c1, c2):
return np.concatenate((c1.reshape(-1, 1), c2.reshape(-1, 1)), axis=1)

def cart2pol(xyArr):
rho = np.sqrt((xyArr**2).sum(1))
phi = np.arctan2(xyArr[:,1], xyArr[:,0])
return combine2Coord(rho, phi)

def pol2cart(rhoPhiArr):
x = rhoPhiArr[:,0] * np.cos(rhoPhiArr[:,1])
y = rhoPhiArr[:,0] * np.sin(rhoPhiArr[:,1])
return combine2Coord(x, y)
``````

Do you care about speed? Use `cmath`, it's an order faster than `numpy`. And it's already included in any python since `python 2`!

Using `ipython`:

``````import cmath, numpy as np

def polar2z(polar):
rho, phi = polar
return rho * np.exp( 1j * phi )

def z2polar(z):
return ( np.abs(z), np.angle(z) )

def cart2polC(xy):
x, y = xy
return(cmath.polar(complex(x, y))) # rho, phi

def pol2cartC(polar):
rho, phi = polar
z = rho * cmath.exp(1j * phi)
return z.real, z.imag

def cart2polNP(xy):
x, y = xy
rho = np.sqrt(x**2 + y**2)
phi = np.arctan2(y, x)
return(rho, phi)

def pol2cartNP(polar):
rho, phi = polar
x = rho * np.cos(phi)
y = rho * np.sin(phi)
return(x, y)

xy = (100,100)
polar = (100,0)

%timeit cart2polC(xy)
%timeit pol2cartC(polar)

%timeit cart2polNP(xy)
%timeit pol2cartNP(polar)

%timeit z2polar(complex(*xy))
%timeit polar2z(polar)

373 ns ± 4.76 ns per loop (mean ± std. dev. of 7 runs, 1,000,000 loops each)
337 ns ± 0.976 ns per loop (mean ± std. dev. of 7 runs, 1,000,000 loops each)
4.3 µs ± 34.2 ns per loop (mean ± std. dev. of 7 runs, 100,000 loops each)
3.41 µs ± 5.78 ns per loop (mean ± std. dev. of 7 runs, 100,000 loops each)
3.4 µs ± 5.4 ns per loop (mean ± std. dev. of 7 runs, 100,000 loops each)
1.39 µs ± 3.86 ns per loop (mean ± std. dev. of 7 runs, 1,000,000 loops each)
``````

You can use the built-in function spherical_to_cartesian from astropy.

Thinking about it in general, I would strongly consider hiding coordinate system behind well-designed abstraction. Quoting Uncle Bob and his book:

``````class Point(object)
def setCartesian(self, x, y)
def setPolar(self, rho, theta)
def getX(self)
def getY(self)
def getRho(self)
def setTheta(self)
``````

With interface like that any user of Point class may choose convenient representation, no explicit conversions will be performed. All this ugly sines, cosines etc. will be hidden in one place. Point class. Only place where you should care which representation is used in computer memory.

• No need for getters and setters in Python. Just use properties. Commented Feb 20, 2016 at 5:26
• @K.-MichaelAye, I think he's talking about overloading the initializer and using methods to convert the class attributes under the hood. I don't he realized the question is about converting the attributes under the hood. Commented Aug 2, 2017 at 17:38