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Is it possible to calculate n complex roots of a given number using Python? I've shortly checked it, and it looks like Python gives me wrong/incomplete answers:

(-27.0j)**(1.0/3.0) produces (2.598076211353316-1.4999999999999998j)

but proper roots should be 3 complex numbers, because every non-zero number has n different complex number nth roots. Is it possible in Python?

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related: How to compute the nth root of a very big integer in python [not a dupe because in this question the OP doesn't want integer, but any number] –  amit Sep 13 '11 at 13:22
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Actually, zero has n roots too - they're just all the same :) –  Tom Zych Sep 13 '11 at 13:23
    
@amit: this is absolutely another question, the keyword is "all roots" –  psihodelia Sep 13 '11 at 13:26
    
@psihodelia: I didn't vote it as duplicate, I just think a you/future reader which is interested in your question, might be interested in the other one as well. –  amit Sep 13 '11 at 13:32
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@amit: It's not very closely related, at all. –  Tom Zych Sep 13 '11 at 13:36
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3 Answers

up vote 6 down vote accepted

I don't think standard Python will do this unless you write a function for it, but you can do it with Numpy:

http://docs.scipy.org/doc/numpy/reference/generated/numpy.roots.html

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There are many multi-valued complex functions - functions that can have more than one value corresponding to any point in their domain. For example: roots, logarithms, inverse trigonometric functions...

The reason these functions can have multiple values is usually because they are the inverse of a function that has multiple values in the domain map to the same value.

When doing calculations with such functions, it would be impractical to always return all possible values. For the inverse trigonometric functions, there are infinitely many possible values.

Usually the different function values can be expressed as a function of an integer parameter k. For example, the values of log z with z = r*(cos t + i*sin t is log r + i*(t + k*2*pi) with k any integer. For the nth root, it is r**(1/n)*exp(i*(t+k*2*pi)/n with k=0..n-1 inclusive.

Because returning all possible values is impractical, mathematical functions in Python and almost all other common programming languages return what's called the 'principal value' of the function. (reference) The principal value is usually the function value with k=0. Whatever choice is made, it should be stated clearly in the documentation.

So to get all the complex roots of a complex number, you just evaluate the function for all relevant values of k:

def roots(z, n):
    nthRootOfr = abs(z)**(1.0/n)
    t = phase(z)
    return map(lambda k: nthRootOfr*exp((t+2*k*pi)*1j/n), range(n))

(You'll need to import the cmath module to make this work.) This gives:

>>> roots(-27j,3)
[(2.59808-1.5j), (1.83691e-16+3j), (-2.59808-1.5j)]
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If you want to get all roots on clean python you can create simple function to do this:

import math

def root(num, r):
    base = num ** (1.0/r)
    roots = [base]
    for i in range(1, r):
        roots.append(complex(base * math.cos(2*math.pi * i / r), base * math.sin(2*math.pi * i / r)))
    return roots
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