Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have data that I should interpolate with a function which must be of the following kind:

f(x) = ax4 + bx2 + c

with a > 0 and b ≤ 0. Unfortunately, MATLAB's polyfit does not allow any constraints on the coefficients of the polynomial. Does anybody know if there is a MATLAB function to do this? Otherwise, how can I implement it?

Thank you very much in advance,

Elisabetta

share|improve this question
    
why a>0 and not a>=0? suppose your optimization results with a=0, then setting it to a=\epsilon would change very little... –  Shai Jul 1 '13 at 14:36
    
Yes, you're right, I said a>0 just because my data never "behave" like a function with a closed to 0, but I don't necessarily have to set it as a constraint –  bettaberg Jul 1 '13 at 15:34
    
@bettaberg: I'm still anxious to know where those constraints come from...? What are you trying to model, and why the constraints on the parameters? –  Rody Oldenhuis Jul 1 '13 at 15:40

3 Answers 3

up vote 10 down vote accepted

You can try using fminsearch, fminunc defining your objective function manually.

Alternatively, you can define your problem slightly different:

f(x) = a2x4 - b2x2 + c

Now, the new a and b can be optimized for without constraints, while ensuring that the final a and b you are looking for are positive (negative resp.).

share|improve this answer
3  
+1 for suggesting the transformation, good one –  Rody Oldenhuis Jul 1 '13 at 15:03

Without constraints, the problem can be written and solved as a simple linear system:

% Your design matrix ([4 2 0] are the powers of the polynomial)
A = bsxfun(@power, your_X_data(:), [4 2 0]);

% Best estimate for the coefficients, [a b c], found by 
% solving A*[a b c]' = y in a least-squares sense
abc = A\your_Y_data(:)

Those constraints will of course automatically be satisfied iff that constrained model indeed underlies your data. For example,

% some example factors
a = +23.9;
b = -15.75;
c = 4;

% Your model
f = @(x, F) F(1)*x.^4 + F(2)*x.^2 + F(3);

% generate some noisy XY data
x = -1:0.01:1;
y = f(x, [a b c]) + randn(size(x));

% Best unconstrained estimate a, b and c from the data
A = bsxfun(@power, x(:), [4 2 0]);
abc = A\y(:);

% Plot results
plot(x,y, 'b'), hold on
plot(x, f(x, abc), 'r')
xlabel('x (nodes)'), ylabel('y (data)')

enter image description here

However, if you impose constraints on data that are not accurately described by that constrained model, things might go wrong:

% Note: same data, but flipped signs 
a = -23.9;
b = +15.75;
c = 4;

f = @(x, F) F(1)*x.^4 + F(2)*x.^2 + F(3);

% generate some noisy XY data
x = -1:0.01:1;
y = f(x, [a b c]) + randn(size(x));

% Estimate a, b and c from the data, Forcing a>0 and b<0
abc = fmincon(@(Y) sum((f(x,Y)-y).^2), [0 0 0], [-1 0 0; 0 +1 0; 0 0 0], zeros(3,1));

% Plot results
plot(x,y, 'b'), hold on
plot(x, f(x, abc), 'r')
xlabel('x (nodes)'), ylabel('y (data)')

enter image description here

(this solution has a == 0, indicative of an incorrect model choice).

If the exact equality of a == 0 is a problem: there is of course no difference if you set a == eps(0). Numerically, this will not be noticeable for real-world data, but it's nonzero nonetheless.

Anyway, I have a suspicion that your model is not well chosen and the constraints are a "fix" to get everything to work, or your data should actually be unbiased/rescaled before trying to make any fit, or that some similar preconditions apply (I've often seen people do this sort of thing, so yes, I'm a bit biased in this respect :).

So...what are the real reasons behind those constraints?

share|improve this answer
    
it's a bit naive to say "since we assumed this model, the constraints should be automatically satisfied by the data"... –  Shai Jul 1 '13 at 15:05
    
@Shai: where exactly did I say that? There was a pretty explicit IF there... –  Rody Oldenhuis Jul 1 '13 at 15:07
    
I probably should have rephrased my comment differently, but the point is: if you have constraints on your parameters you should use them and not hope that they will be miraculasly satisfied... –  Shai Jul 1 '13 at 15:34
    
Most importantly: +1 for a detailed solution. –  Shai Jul 1 '13 at 15:37
    
Yes, I understand :) well, actually I'm not an expert Matlab user and the only way I found to find the best fit for a polynomial function was polyfit, which does not even allow to set the coefficients of x and x^3 to 0.. the fact that a is >0 and b<=0 effectively comes directly from my data so I don't necessarily have to set it as a constraint, I guess.. Sorry if I formulated my question in a rather ambiguous way and thank you for your help, now everything is clear! :) –  bettaberg Jul 1 '13 at 15:53

If you have the curve fitting toolbox then fit does allow for setting constraints using the 'upper' and 'lower' options. You would want something like.

M=fit(x, f, 'poly4', 'upper', [-inf, 0, -inf, 0, -inf], 'lower', [0, 0, 0, 0, -inf]);

Note use -inf to set a particular coefficient to be unconstrained.

This will give a cfit object with the relevant coefficients. You can access these using for example M.p1 for the x^4 term. Alternatively you can evaluate the function at whatever points you want using feval.

I think you can do a similar thing using lsqcurvefit in the optimization toolbox as well.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.