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Consider the cubic equation

ax³ + bx² + cx + d = 0 

where a, b, c, and d are real input coefficients. I was trying to develop a matlab program to find all roots of equation (1).

Your program can not use the matlab built-in functions fzero and roots.

You should turn in a .m file cubicxxx.m which contains a matlab function of the form

function [rts,info] = cubicxxx(a,b,c,d)

where xxx is your student id, rts is the vector of roots and info is your output message.

Your program will be stress-tested against cubic equations that may have

  1. random roots; or

  2. very large or very small roots; or

  3. multiple roots or nearly multiple roots; or

  4. less than 3 roots or more than 3 roots.

You will receive credit for a test polynomial only if your program gets the number of roots correctly, and only then will each correct root (accurate to within a relative error of at most 10^-10 as compared to the roots function in matlab) receive additional credit.

Do NOT use fzero or roots (both in lower case letters)

I will greatly appreciate if you could provide a draft of something that can simplify my analysis of this program.

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closed as not constructive by woodchips, Andrey, sarnold, Alex, Graviton Feb 7 '12 at 9:40

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3  
Have you actually tried any methods yet? Binary search, linear interpolation and Newton Raphson method immediately jump to my mind, the latter probably being the best. –  HexTree Jan 30 '12 at 9:16
    
Not familiar with these methods; Can you please provide your code snippets? –  Buddy Holly Jan 30 '12 at 9:57
2  
Sounds like homework to me –  Nzbuu Jan 30 '12 at 10:19
    
en.wikipedia.org/wiki/Newton's_method has the details for the Newton Raphson. Worth a read. You're required to know the derivative of your function at a point, which should be very possible in your well-constrained problem. Come back when you have had a go at implementing this, or any other method. –  Bill Cheatham Jan 30 '12 at 10:20
    
There's a long discussion on Wikipedia about the roots of a cubic. Although I'm not sure how a cubic can have more than 3 roots. –  Nzbuu Jan 30 '12 at 10:25

1 Answer 1

I won't give you code for your own function, you can do the research yourself. But I would recommend you write a test to verify your code before you hand in. The following code will give you a test harness that tests random polynomials (i.e. random roots) with both your code and roots. You can of course extend this to the other cases specified:

clear variables; clc; close all;

nTests = 100;
nPass = 0;
nAccurate = 0;
tolerance = 1e-10;

for i = 1:nTests
   p = rand(4,1); % or a function that generates a test polynomial
   referenceRoots = roots(p);

   [myRoots, info] = cubicxxx(p(1), p(2), p(3), p(4));

   try
      assert(numel(unique(myRoots))==numel(unique(referenceRoots)),'Not the correct number');
      nPass = nPass + 1;
      assert(all(abs(sort(myRoots)./sort(referenceRoots)-1)<tolerance),'Not accurate enough');
      nAccurate = nAccurate + 1;
   catch error
      fprintf(2,'%s\n',error.message);
      fprintf('Polynomial: %g x^3 + %g x^2 + %g x + %g\n', p(1), p(2), p(3), p(4));
      disp(info);

      disp('Reference, Mine');
      disp([referenceRoots, myRoots]);
   end 
end
fprintf('\n\n');
fprintf('Score: %d / %d for number of roots \n',nPass    , nTests);
fprintf('Score: %d / %d for accuracy        \n',nAccurate, nTests);

However, I think exercises like this are quite pointless, it is very easy to get the implementation of a root-finder that has equal performance as roots, but it will not help you understand anything about the problem (and might even be considered misconduct).

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