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As part of a program I'm writing, I need to solve a cubic equation exactly (rather than using a numerical root finder):

a*x**3 + b*x**2 + c*x + d = 0.

I'm trying to use the equations from here. However, consider the following code (this is Python but it's pretty generic code):

a =  1.0
b =  0.0
c =  0.2 - 1.0
d = -0.7 * 0.2

q = (3*a*c - b**2) / (9 * a**2)
r = (9*a*b*c - 27*a**2*d - 2*b**3) / (54*a**3)

print "q = ",q
print "r = ",r

delta = q**3 + r**2

print "delta = ",delta

# here delta is less than zero so we use the second set of equations from the article:

rho = (-q**3)**0.5

# For x1 the imaginary part is unimportant since it cancels out
s_real = rho**(1./3.)
t_real = rho**(1./3.)

print "s [real] = ",s_real
print "t [real] = ",t_real

x1 = s_real + t_real - b / (3. * a)

print "x1 = ", x1

print "should be zero: ",a*x1**3+b*x1**2+c*x1+d

But the output is:

q =  -0.266666666667
r =  0.07
delta =  -0.014062962963
s [real] =  0.516397779494
t [real] =  0.516397779494
x1 =  1.03279555899
should be zero:  0.135412149064

so the output is not zero, and so x1 isn't actually a solution. Is there a mistake in the Wikipedia article?

ps: I know that numpy.roots will solve this kind of equation but I need to do this for millions of equations and so I need to implement this to work on arrays of coefficients.

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Do you need the imaginary root? –  J. Polfer Dec 1 '09 at 22:19
    
No, only real roots –  astrofrog Dec 1 '09 at 22:21
    
I had some working code that solved for the real roots in VB.NET and I know it worked... I'll try to see if I can find it amongst my folders and post it tomarrow (no net access at home). –  J. Polfer Dec 1 '09 at 22:23
    
For the x1 solution in the wikipedia article, you add s and t. s has imaginary part theta/3, and t has imaginary part -theta/3, so for that solution the imaginary parts should cancel exactly. –  astrofrog Dec 1 '09 at 22:24
    
Can you be sure that, for those coefficients, the imaginary part is unimportant? After all delta is not zero. –  pavium Dec 1 '09 at 22:25

4 Answers 4

up vote 19 down vote accepted

Wikipedia's notation (rho^(1/3), theta/3) does not mean that rho^(1/3) is the real part and theta/3 is the imaginary part. Rather, this is in polar coordinates. Thus, if you want the real part, you would take rho^(1/3) * cos(theta/3).

I made these changes to your code and it worked for me:

theta = arccos(r/rho)
s_real = rho**(1./3.) * cos( theta/3)
t_real = rho**(1./3.) * cos(-theta/3)

(Of course, s_real = t_real here because cos is even.)

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There it is. Can't believe I read through that several times. –  John Dec 1 '09 at 22:52
    
Thanks so much for spotting this! I was going crazy trying to understand why it wouldn't work. –  astrofrog Dec 1 '09 at 23:01

I've looked at the Wikipedia article and your program.

I also solved the equation using Wolfram Alpha and the results there don't match what you get.

I'd just go through your program at each step, use a lot of print statements, and get each intermediate result. Then go through with a calculator and do it yourself.

I can't find what's happening, but where your hand calculations and the program diverge is a good place to look.

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I did go through very carefully, and also tried using a calculator, and I'm pretty confident I'm not doing anything wrong. Could this be a problem with the wikipedia article? –  astrofrog Dec 1 '09 at 22:45
    
See A. Rex's answer. As they say, "Well, THERE'S your problem!" –  John Dec 1 '09 at 22:52

Here's A. Rex's solution in JavaScript:

a =  1.0;
b =  0.0;
c =  0.2 - 1.0;
d = -0.7 * 0.2;

q = (3*a*c - Math.pow(b, 2)) / (9 * Math.pow(a, 2));
r = (9*a*b*c - 27*Math.pow(a, 2)*d - 2*Math.pow(b, 3)) / (54*Math.pow(a, 3));
console.log("q = "+q);
console.log("r = "+r);

delta = Math.pow(q, 3) + Math.pow(r, 2);
console.log("delta = "+delta);

// here delta is less than zero so we use the second set of equations from the article:
rho = Math.pow((-Math.pow(q, 3)), 0.5);
theta = Math.acos(r/rho);

// For x1 the imaginary part is unimportant since it cancels out
s_real = Math.pow(rho, (1./3.)) * Math.cos( theta/3);
t_real = Math.pow(rho, (1./3.)) * Math.cos(-theta/3);

console.log("s [real] = "+s_real);
console.log("t [real] = "+t_real);

x1 = s_real + t_real - b / (3. * a);

console.log("x1 = "+x1);
console.log("should be zero: "+(a*Math.pow(x1, 3)+b*Math.pow(x1, 2)+c*x1+d));
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The program below perfectly solves the Cubic Equation of the form Ax^3 + Bx^2 + Cx + D.

The flawless code is written in .Net C#.

The real and imaginary roots are separated by black and red colors respectively.

Simply update the value of variables A, B, C and D to see the answers i.e. the solution of the equation.

To find the 2 roots, solution of a Quadratic equation please visit here.

enter image description here

Source

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