Can someone help me to find a solution on how to calculate a cubic root of the negative number using python?
>>> math.pow(3, float(1)/3)
nan
it does not work. Cubic root of the negative number is negative number. Any solutions?
You could use:
Or more generally:



A simple use of De Moivre's formula, is sufficient to show that the cube root of a value, regardless of sign, is a multivalued function. That means, for any input value, there will be three solutions. Most of the solutions presented to far only return the principle root. A solution that returns all valid roots, and explicitly tests for noncomplex special cases, is shown below.
Edit: As requested, in cases where it is inappropriate to have dependency on numpy, the following code does the same thing.






You can get the complete (all n roots) and more general (any sign, any power) solution using:
Explanation: a is using the equation x^{u} = exp(u*log(x)). This solution will then be one of the roots, and to get the others, rotate it in the complex plane by a (full rotation)/t. 


Taking the earlier answers and making it into a oneliner:



The cubic root of a negative number is just the negative of the cubic root of the absolute value of that number. i.e. x^(1/3) for x < 0 is the same as (1)*(x)^(1/3) Just make your number positive, and then perform cubic root. 


You can also wrap the
gives the expected



Primitive solution:
Probably massively nonpythonic, but it should work. 


You can use
This also works for arrays. 


I just had a very similar problem and found the NumPy solution from this forum post. In a nushell, we can use of the NumPy
So going back to the original cube root problem:
I hope this helps. 


For an arithmetic, calculatorlike answer in Python 3:
or For the algebraic solution of



float(1)
is more conveniently written as "1.". Or you can usefrom __future__ import division
and stop worrying about integer division (1/3 returns 0.3333...). – EOL Sep 1 '09 at 13:44math.pow()
there's no way to specify the cube root. – David Thornley Nov 20 '09 at 15:04