The fourth root of (12) or any other number in Python 3

I'm trying to make a simple code for power 12 to 4(12 ** 4) . I have the output num (20736) but when I want to figure returns (20736) to its original value (12). I don't know how to do that in Python .. in Real mathematics I do that by the math phrase {12؇}

The question is how to make {12؇} in Python ?? I'm using sqrt() but sqrt only for power 2

``````  #!/usr/bin/env python3.3
import math
def pwo():
f=12 ** 4 #f =20736 #
c=        # should  c = 12 #
return f,c
print pwo()
``````
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`20736 ** 0.25` might be a bit off, or exact, I don't know for sure. The `n`-th root of `x` is `x^(1/n)`, so `20736 ** (1.0/4)`. – Daniel Fischer Jul 11 '13 at 22:09
Hint: `n^(1/4) = (n^(1/2))^(1/2)`. Or use `n ** 0.25`. – Matt Ball Jul 11 '13 at 22:10
In math, `12؇4` is the 12th root of 4, not the 4th root of 12. In other words, it's the inverse of `4 ** 12`, not the inverse of `12 ** 4`. Which one do you actually want? – abarnert Jul 11 '13 at 22:23
@DanielFischer: And if you want it exact to a given number of decimal places, just use `20736 ** decimal.Decimal(1)/4` instead. – abarnert Jul 11 '13 at 22:24
@abarnert :12؇ is the 4th root of 12 ; 12*12*12*12=20736 :(20736؇4=12) – Mr Sam Jul 12 '13 at 14:27

For scientific purposes (where you need a high level of precision), you can use numpy:

``````>>> def root(n, r=4):
...     from numpy import roots
...     return roots([1]+[0]*(r-1)+[-n])
...
>>> print(root(12))
[ -1.86120972e+00+0.j          -3.05311332e-16+1.86120972j
-3.05311332e-16-1.86120972j   1.86120972e+00+0.j        ]
>>>
``````

The output may look strange, but it can be used just as you would use a list. Furthermore, the above function will allow you to find any root of any number (I put the default for r equal to 4 since you asked for the fourth root specifically). Finally, numpy is a good choice because it will return the complex numbers that will also satisfy your equations.

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Thank u this is the True Answer – Mr Sam Jul 12 '13 at 14:34
So, it seems this may not be quite as precise as a simpler Python method for finding the first non-imaginary positive root in some cases. E.g.: (Sorry, oneliners…) `import numpy as np`, `numpy_root = lambda n, r: float(np.real(filter(lambda n: np.imag(n) == 0 and n > 0, np.roots(np.double([1]+[0]*(r-1)+[-n])))[0]))`, `py_root = lambda n, r: float(n)**(1.0/float(r))`. On my box, `numpy_root(2, 12) == 1.0594630943592955`, but `py_root(2, 12) == 1.0594630943592953`, which is better according to komsta.net/digits/12roots . Am I doing something bad? Would another numpy API be better…? – Mark Gollnick Sep 18 '15 at 5:29
``````def f(num):
return num**0.25
``````

or

``````import math
def f(num):
return math.sqrt(math.sqrt(num))
``````
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+1 Yup. Sometimes the simplest solution is to think in terms of Math, before touching the keyboard ;) – Tadeck Jul 12 '13 at 0:23