# Calculating complex numbers with rational exponents

Yesterday I created this piece of code that could calculate z^n, where z is a complex number and n is any positive integer.

``````--snip--
float real = 0;
float imag = 0;

// d is the power the number is raised to [(x + yi)^d]
for (int n = 0; n <= d; n++) {
if (n == 0) {
real += pow(a, d);
} else { // binomial theorem
switch (n % 4) {
case 1: // i
imag += bCo(d, n) * pow(a, d - n) * pow(b, n);
break;
case 2: // -1
real -= bCo(d, n) * pow(a, d - n) * pow(b, n);
break;
case 3: // -i
imag -= bCo(d, n) * pow(a, d - n) * pow(b, n);
break;
case 0: // 1
real += bCo(d, n) * pow(a, d - n) * pow(b, n);
break;
}
}
}
--snip--

int factorial(int n) {
int total = 1;
for (int i = n; i > 1; i--) { total *= i; }
}

// binomial cofactor
float bCo(int n, int k) {
return (factorial(n)/(factorial(k) * factorial(n - k)));
}
``````

I use the binomial theorem to expand z^n, and know whether to treat each term as a real or imaginary number depending on the power of the imaginary number.

What I want to do is to be able to calculate z^n, where n is any positive real number (fractions). I know the binomial theorem can be used for powers that aren't whole numbers, but I'm not really sure how to handle the complex numbers. Because i^0.1 has a real and imaginary component I can't just sort it into a real or imaginary variable, nor do I even know how to program something that could calculate it.

Does anyone know of an algorithm that can help me accomplish this, or maybe even a better way to handle complex numbers that will make this possible?

Oh, I'm using java.

Thanks.

-

Consider a complex number $z$ such that $z=x+iy$.

Thus, the polar form of $z$ is = ${r}{e^{i\theta}}$, where:

• $r$ is the magnitude of $z$, or $\sqrt{x^2+y^2}$, and
• $\theta$ is $arctan(y/x)$.

Once you have done so, you can use DeMoivre's Theorem to calculate $z^n$ like so:

$z^n={r^n}{e^{{i}{n}{\theta}}}$

or more simply as

$z^n={r^n}\left(cos(n\theta)+{i}sin(n\theta)\right)$

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Thanks, this is what I was looking for. I actually learnt about DeMoivre's Theorem last semester at school, so I feel a bit silly for not thinking to use it. –  Bumzur Jun 23 '10 at 7:26
See also `public Complex pow(double e)` jscience.org/api/org/jscience/mathematics/number/Complex.html –  trashgod Jun 23 '10 at 15:40
"z = r*e*i*theta" on the third line should be "z = r*e^(i*theta)" I'd change it myself, but I don't have the rep for that yet. –  andand Jun 23 '10 at 16:20
The formula is valid only for integer values of n –  belisarius Jun 23 '10 at 18:24
+1 this is what I was going to answer. Though DeMoivre's theorem is only valid for integer `n`, Euler's Theorem gives you the result that lies between the last and second-to-last step, which is valid for all real/complex n. Note that, like `sqrt()`, it only gives one of the roots. –  BlueRaja - Danny Pflughoeft Jun 23 '10 at 19:09

First of all, it may have multiple solutions. See Wikipedia: Complex number / exponentiation.

Similar considerations show that we can define rational real powers just as for the reals, so z1/n is the n:th root of z. Roots are not unique, so it is already clear that complex powers are multivalued, thus careful treatment of powers is needed; for example (81/3)4 ≠ 16, as there are three cube roots of 8, so the given expression, often shortened to 84/3, is the simplest possible.

I think you should break it down to polar notation and go from there.

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In addition to the above link, have a look at en.wikipedia.org/wiki/… and section 12.1.1 in suitcaseofdreams.net/De_Moivre_formula.htm –  Steve Jun 23 '10 at 7:06
Thanks, I hadn't thought of that. Polar notation should make it a bit neater. –  Bumzur Jun 23 '10 at 7:08
+1 for mentioning multiple values. –  Aryabhatta Jun 23 '10 at 12:35

I'm not really good at math, so probably I understood your task wrong. But as far as I got it - apache commons math can help you: http://commons.apache.org/math/userguide/complex.html

Example:

``````Complex first  = new Complex(1.0, 3.0);
Complex second = new Complex(2.0, 5.0);

Complex answer = first.log();        // natural logarithm.