# Specialised algorithm to find positive real solutions to quartic equations?

I'm looking for a specialised algorithm to find positive real solutions to quartic equations with real coefficients (also know as bi-quadratic or polynomial equations of order 4). They have the form:

a4 x4 + a3 x3 +a2 x2 +a1 x + a0 = 0

with a1, a2,... being real numbers.

It's supposed to run on a microcontroller, which will need to do quite a lot of those calculations. So performance is an issue. That's why I'm looking for a specialised algorithm for positive solutions. If possible I'd like it to compute the exact solutions.

I know there is a general way to compute the solution of a quartic equation but it is rather involved in terms of computation.

Can someone point me in the right direction?

### Edit:

Judging from the answers: Some seem to have misunderstood me (though I was pretty clear about it). I know of the standard ways of solving quartic equations. They don't do it for me - neither they fit in the memory nor are they sufficiently fast. What I would need is a high accuracy highly efficient algorithm to find only real solutions (if that helps) to quartic equations with real coefficients. I'm not sure there is such an algorithm, but I thought you guys might know. P.S.: The downvotes didn't come from me.

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Seriously, have you actually tried Newton's method (aka Newton-Raphson) or even plain old binary search, and found it not to fit in memory or not fast enough? This is what many calculators use and books on computer algebra recommend, and I'd be really curious exactly what sort of application you have where Newton's method isn't fast enough and you expect there exists something even better. –  ShreevatsaR Jul 3 '11 at 14:39
bi-quadratic is not the same as quartic: a bi-quadratic equation is a quartic equation in which there are no terms of odd order. –  lhf Jul 3 '11 at 14:42
Can you explain your application a bit more? Can you use floating point? Is it for a lookup table or a raytracer? –  whoplisp Jul 3 '11 at 16:13
If you can reliably refactor the quartic equation into a product of two quadratics you can use the standard formula from high school to solve for the roots of each one. The key is "reliably". –  duffymo Jul 4 '11 at 1:20
Are the a_i constants or do they vary at runtime? –  starblue Jul 11 '11 at 8:47
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## 5 Answers

This is one of those situations where it is probably easier to find all the roots using complex arithmetic than to only find the positive real roots. And since it sounds like you need to find multiple roots at once, I would recommend using the Durand-Kerner method, which is basically a refinement of the method of Weierstrass:

http://en.wikipedia.org/wiki/Durand%E2%80%93Kerner_method

Weierstrass' method is in turn a refinement of Newton's method that solves for for all the roots of the polynomial in parallel (and it has the big advantage that it is brain-dead easy to code up). It converges at about quadratic rate in general, though only linearly for multiple roots. For most quartic polynomials, you can pretty much nail the roots in just a few iterations. If you need a more general purpose solution, then you should use instead use Jenkins-Traub:

http://en.wikipedia.org/wiki/Jenkins%E2%80%93Traub_method

This is faster for higher degree polynomials, and basically works by converting the problem into finding the eigenvalues of the companion matrix:

http://en.wikipedia.org/wiki/Companion_matrix

EDIT: As a second suggestion, you could also try using the power method on the companion matrix. Since your equation has only non-negative coefficients, you may find it useful to apply the Perron-Frobenius theorem to the companion matrix. At minimal, this certifies that there exists at least one non-negative root:

http://en.wikipedia.org/wiki/Perron%E2%80%93Frobenius_theorem

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Yes, there are general ways. You need a root finding algorithm, like bracketing and bisection, secant, false position, Ridder, Newton-Raphson, deflation, Muller, Laguerre, or Jenkins-Traub - did I leave anyone out?

Check out "Numerical Recipes" for details.

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Newton-Raphson is a good choice I'd say, or possibly bisection. –  Paxinum Jul 3 '11 at 12:50
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Take a look at Ferrari's method. It involves quite a bit of computation, however, but may serve your needs.

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I know of the standard methods to solve those equation. I thought there might be a more efficient algorithm for computing only POSITIV solutions to equations with real coefficients. That's what I asked. –  con-f-use Jul 3 '11 at 14:07
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Can you supply good start values to ensure that you always find all solutions. Newtons method would converge fast.

I checked in Maxima:

``````solve(a*x^4+b*x^3+c*x^2+d*x+c=0,x);
``````

The solution looks indeed horrible. You can easily run into stability problems. This happens whenever you subtract two floating point numbers that have close values.

However, if the coefficients are constant you can just implement the direct formula. You can get the solution either by installing maxima or you can enter the equation on wolframalpha.com

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A common cause of stability problems from cancellation would be when there are two roots that are very close to each other. –  user85109 Jul 3 '11 at 14:33
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No. There is no magic way to find the roots of a 4th order polynomial equation, at least not without doing the work. Yes, there is a formula for 4th order polynomials that involves complex arithmetic, but it will return all the roots, complex, real positive, negative. Either use an iterative scheme, or do the algebra.

You are lucky there is an analytical solution at all. Had you a 5th order polynomial, that would not even exist.

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I think you got the number there off by one. Quartics are solvable by radicals, and you could even solve it exactly in rational arithmetic + some field extensions. On the other hand, Galois theory tells us that this method only breaks down for 5th order or higher polynomials. –  Mikola Jun 2 '12 at 20:45
@Mikola - Apparently you did not read what I said. I said, that If the polynomial was 5th order, it would be completely impossible, and that for a 4th order polynomial you must still go through the algebra. I did NOT say that a 4th order polynomial was unsolvable, merely that there was no trivial solution that would yield only the positive solutions. –  user85109 Jun 3 '12 at 2:37
The revised version is a bit more clear, but the phrase "Even if all you want are the positive real roots, it does not exist." threw me. I guess I was not sure what you meant by this, because it sounds like you were saying that no solution by radicals exists for the quartic (which is false). –  Mikola Jun 4 '12 at 19:05
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