# Faster numpy cartesian to spherical coordinate conversion?

I have an array of 3 million data points from a 3-axiz accellerometer (XYZ), and I want to add 3 columns to the array containing the equivalent spherical coordinates (r, theta, phi). The following code works, but seems way too slow. How can I do better?

``````import numpy as np
import math as m

def cart2sph(x,y,z):
XsqPlusYsq = x**2 + y**2
r = m.sqrt(XsqPlusYsq + z**2)               # r
elev = m.atan2(z,m.sqrt(XsqPlusYsq))     # theta
az = m.atan2(y,x)                           # phi
return r, elev, az

def cart2sphA(pts):
return np.array([cart2sph(x,y,z) for x,y,z in pts])

def appendSpherical(xyz):
np.hstack((xyz, cart2sphA(xyz)))
``````
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This is similar to Justin Peel's answer, but using just `numpy` and taking advantage of its built-in vectorization:

``````def appendSpherical_np(xyz):
ptsnew = np.hstack((xyz, np.zeros(xyz.shape)))
xy = xyz[:,0]**2 + xyz[:,1]**2
ptsnew[:,3] = np.sqrt(xy + xyz[:,2]**2)
ptsnew[:,4] = np.arctan2(np.sqrt(xy), xyz[:,2]) # for elevation angle defined from Z-axis down
#ptsnew[:,4] = np.arctan2(xyz[:,2], np.sqrt(xy)) # for elevation angle defined from XY-plane up
ptsnew[:,5] = np.arctan2(xyz[:,1], xyz[:,0])
return ptsnew
``````

Note that, as suggested in the comments, I've changed the definition of elevation angle from your original function. On my machine, testing with `pts = np.random.rand(3000000, 3)`, the time went from 76 seconds to 3.3 seconds. I don't have Cython so I wasn't able to compare the timing with that solution.

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Great job, my Cython solution is only a little bit faster (1.23 seconds vs. 1.54 seconds on my machine). For some reason, I didn't see the vectorized arctan2 function when I looked for doing it straight with numpy. +1 –  Justin Peel Nov 7 '10 at 15:41
Clear, brief, and fast. Many thanks! –  BobC Nov 8 '10 at 4:24
Anon suggested `ptsnew[:,4] = np.arctan2(np.sqrt(xy),xyz[:,2])` –  Sam Saffron Jan 27 '11 at 22:27
–  Sam Saffron Jan 27 '11 at 22:28

Here's a quick Cython code that I wrote up for this:

``````cdef extern from "math.h":
long double sqrt(long double xx)
long double atan2(long double a, double b)

import numpy as np
cimport numpy as np
cimport cython

ctypedef np.float64_t DTYPE_t

@cython.boundscheck(False)
@cython.wraparound(False)
def appendSpherical(np.ndarray[DTYPE_t,ndim=2] xyz):
cdef np.ndarray[DTYPE_t,ndim=2] pts = np.empty((xyz.shape[0],6))
cdef long double XsqPlusYsq
for i in xrange(xyz.shape[0]):
pts[i,0] = xyz[i,0]
pts[i,1] = xyz[i,1]
pts[i,2] = xyz[i,2]
XsqPlusYsq = xyz[i,0]**2 + xyz[i,1]**2
pts[i,3] = sqrt(XsqPlusYsq + xyz[i,2]**2)
pts[i,4] = atan2(xyz[i,2],sqrt(XsqPlusYsq))
pts[i,5] = atan2(xyz[i,1],xyz[i,0])
return pts
``````

It took the time down from 62.4 seconds to 1.22 seconds using 3,000,000 points for me. That's not too shabby. I'm sure there are some other improvements that can be made.

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To complete the previous answers, here is a Numexpr implementation (with a possible fallback to Numpy),

``````import numpy as np
from numpy import arctan2, sqrt
import numexpr as ne

def cart2sph(x,y,z, ceval=ne.evaluate):
""" x, y, z :  ndarray coordinates
ceval: backend to use:
- eval :  pure Numpy
- numexpr.evaluate:  Numexpr """
azimuth = ceval('arctan2(y,x)')
xy2 = ceval('x**2 + y**2')
elevation = ceval('arctan2(z, sqrt(xy2))')
r = eval('sqrt(xy2 + z**2)')
return azimuth, elevation, r
``````

For large array sizes, this allows a factor of 2 speed up compared to pure a Numpy implementation, and would be comparable to C or Cython speeds. The present numpy solution (when used with the `ceval=eval` argument) is also 25% faster than the `appendSpherical_np` function in the @mtrw answer for large array sizes,

``````In [1]: xyz = np.random.rand(3000000,3)
...: x,y,z = xyz.T
In [2]: %timeit -n 1 appendSpherical_np(xyz)
1 loops, best of 3: 397 ms per loop
In [3]: %timeit -n 1 cart2sph(x,y,z, ceval=eval)
1 loops, best of 3: 280 ms per loop
In [4]: %timeit -n 1 cart2sph(x,y,z, ceval=ne.evaluate)
1 loops, best of 3: 145 ms per loop
``````

although for smaller sizes, `appendSpherical_np` is actually faster,

``````In [5]: xyz = np.random.rand(3000,3)
...: x,y,z = xyz.T
In [6]: %timeit -n 1 appendSpherical_np(xyz)
1 loops, best of 3: 206 µs per loop
In [7]: %timeit -n 1 cart2sph(x,y,z, ceval=eval)
1 loops, best of 3: 261 µs per loop
In [8]: %timeit -n 1 cart2sph(x,y,z, ceval=ne.evaluate)
1 loops, best of 3: 271 µs per loop
``````
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I was unaware of numexpr. My long-term hope is to eventually switch to pypy when numpypy can do all I need, so a "pure Python" solution is preferred. While this is 2.7x faster than appendSpherical_np(), appendSpherical_np() itself provided the 50x improvement I was looking for without needing another package. But still, you met the challenge, so +1 to you! –  BobC May 14 at 8:12

how big are x, y and z? 16bit? do you have lots of memory?

you could store a lookup table of common values for n**2? or a map for XsqPlusYsq?

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The raw hardware data is 32-bit signed integer, which becomes float when I convert it to normal physics units (m/s) –  BobC Nov 8 '10 at 4:33