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I want to estimate the parameters of an AR model with Least square an Gaussian method. If the system is assumed to be represented by an AR model of order p, , then the output is given as where is a white Gaussian noise. I only have the observed samples assumed to be produced from this AR model and have no information about the number of regressors or about the order of the system. Then,

(A) How do I use mldivide or the the formula beta = x'*x\x'*y where beta = estimated coefficients. The concern is also in the data generation method. Since LS works with Gaussian noise, do I have to add the generated data with a white gaussian noise?

This is how I proceeded but the estimated parameters are way too different than the original

%Original parameters
a1 = 0.195;
b1=- .95;
rng(5);
noise = randn(256,1)';  % Normalized white Gaussian noise
%Generate Data
x = filter(1,[1 a1 b1],noise);

y=x';

 rng(5);
  innovation=randn(N,1);
 estimatedParam= [y -[0;y(1:end-1)] -[0;inn(1:end-1)]]\innovation

The estimated coefficients are : 0.2755 -0.2967 0.1607

(B) Is the representation of correct? Is the innovation used ? That is what is the correct way to formulate the problem mathematically?

(C) When calculating the residuals, the size of the original and the estimated signal will be different (length of estimated < original) and least square method does not pad with zeros. So, how do I apply the formula

Residual(k) = y(k) - \sum_{i=1}^P(-estimatedParam_i)*y(k+i)

where = guessed order, = instant of an iteration

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1 Answer 1

up vote 0 down vote accepted

You start out by laying out the correct mathematical system of equations to solve (in the part before the questions), but then your implementation is not quite right. You have to distinguish between x and X:

for an order p solution,

X =-[ x(1)     x(2)     ...  x(p-1) 
      x(2)     x(3)     ...  x(p)    
              ..............
      x(N+1-p) x(N+2-p) ...  x(N-1)]

where N=length(x), and

y = x(p+1:end)   % <-- column vector!!

Note the negative sign in the definition of X

The solution is found as

ph = (X'*X)\(X'*y) 

Defining your least-squares problem this way immediately solves problem (c) since you can compute the AR prediction as

xpred = X*ph;

and the residuals as

residuals = x(p+1:end)-xpred

To interpret the coefficients you should compare the equation of the filter you used to generate x to the AR equation.

Note for your system p=2 does the job...

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Thank you for your detailed reply. However, there are 2 things which I could not follow, could you please explain?(1) How do I represent X as a MATLAB command efficiently and why is there a negative sign?If the model is assumed to be ARMA instead,then there would not have been a negative sign?I have come across several representations of AR model,with and without negative sign & results vary if the sign is considered.So,what is the correct mathematical form? (2) What do you mean by this-compare the equation of the filter you used to generate x to the AR equation. –  Srishti M Aug 26 '13 at 20:42
    
And lastly, I have seen in some papers that LS method is called as as LS+ Gaussian method. Where is this Gaussian distribution ? –  Srishti M Aug 26 '13 at 20:44
    
I introduced the sign so that the resulting coefficients obtained from the least squares analysis would have the same sign as those you used to generate the data with the filter. Changing the sign in X ultimately changes the sign of ph, it is a matter of convention but also of convenience when you compare to the generating equation. –  Try Hard Aug 26 '13 at 21:09
    
When you set up a least-squares problem correctly a change in sign is not a problem because the least-squares coefficients ph will adjust "automatically" (just try it: substitute X with -X in the equations and see what happens to ph), that is the point of performing least squares. Once you have the coefficients however you want to interpret them. In your case the interpretation results from understanding that ph closely resembles the parameters you used in the filter. –  Try Hard Aug 26 '13 at 21:23
    
As for LS-Gaussian, I cannot give you a good answer, this specific implementation I am not familiar with (if you like you can link to an example and I can try to answer). –  Try Hard Aug 26 '13 at 21:27

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