Raise to 1/3 gives complex number

I cannot understand the following output. I would expect Numpy to return -10 (or an approximation). Why is it a complex number?

print((-1000)**(1/3.))

(5+8.660254037844384j)

Numpy official tutorial says the answer is nan. You can find it in the middle of this tutorial.

• Why do you think numpy is involved in this process? Also, have a look at (5+8.660254037844384j)**3! Jul 5 '15 at 13:59
• For the answer to the mathematical half of this question, see e.g. math.stackexchange.com/questions/25528/…. There is more than one cubic root of -1000! Jul 5 '15 at 14:12
• Thank you jonrsharpe. I completely forgot about roots of unity. How can I force python to return -10? Jul 5 '15 at 14:33
• I'm not sure you can. Jul 5 '15 at 14:34
• @user1700890: You could write your own cbrt function, using something like: def cbrt(x): return copysign(abs(x)**(1/3.), x). If you import copysign from numpy instead of math, this definition should work for arrays as well as floats. Jul 5 '15 at 14:36

You are exponentiating a regular Python scalar rather than a numpy array.

Try this:

import numpy as np

print(np.array(-1000) ** (1. / 3))
# nan

The difference is that numpy does not automatically promote the result to a complex type, whereas a Python 3 scalar gets promoted to a complex value (in Python 2.7 you would just get a ValueError).

As explained in the link @jonrsharpe gave above, negative numbers have multiple cube roots. To get the root you are looking for, you could do something like this:

x = -1000
print(np.copysign(np.abs(x) ** (1. / 3), x))
# -10.0

Update 1

Mark Dickinson is absolutely right about the underlying cause of the problem - 1. / 3 is not exactly the same as a third because of rounding error, so x ** (1. / 3) is not quite the same thing as the cube root of x.

A better solution would be to use scipy.special.cbrt, which computes the 'exact' cube root rather than x ** (1./3):

from scipy.special import cbrt

print(cbrt(-1000))
# -10.0

Update 2

It's also worth noting that versions of numpy >= 0.10.0 will have a new np.cbrt function based on the C99 cbrt function.

• Thank you, ali_m! Why would not Numpy return -10? Jul 5 '15 at 14:35
• All real (non-zero) numbers have a pair of complex cube roots in addition to a real cube root, not just the negative ones. Jul 5 '15 at 23:14
• @user1700890: Note that this isn't computing the cube root: it's computing -1000 to the power 0.333333333333333314829616256247390992939472198486328125, which isn't the same thing at all. Having the power operation guess that you actually wanted a cube root and defer to cbrt in this situation would break continuity and in general be a horrible thing to do. (Should it also guess for 5th roots? 7th roots? Using what criterion?) IEEE 754 does define a rootn function, which behaves the way you'd expect for odd n, giving finite results for negative finite inputs. Jul 6 '15 at 7:28
• @ali_m: Nice find with scipy.special.cbrt. It would be nice to see Python's math module grow either a cbrt or a rootn function for this situation. Jul 6 '15 at 17:42
• @MarkDickinson Yes, I was hoping there would be a generic rootn function somewhere in the Python standard libraries (or at least in numpy). The scipy source for cbrt ultimately comes from cephes, which unfortunately lacks a rootn. Jul 6 '15 at 18:59