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.

`numpy`

is involved in this process? Also, have a look at`(5+8.660254037844384j)**3`

!`-1000`

!`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.