function [a,VAR,S,a_aux,b_aux,e_aux,MLE,pos] = rmle(arg1,arg2); % RMLE estimates AR Parameters using the Recursive Maximum Likelihood % Estimator according to [1] % % Use: [a,VAR]=rmle(x,p) % Input: % x is a column vector of data % p is the model order % Output: % a is a vector with the AR parameters of the recursive MLE % VAR is the excitation white noise variance estimate % % Reference(s): % [1] Kay S.M., Modern Spectral Analysis - Theory and Applications. % Prentice Hall, p. 232-233, 1988. % % Version 0.1 % 16 Ago 2004 % Copyright (C) 2004 by Jose Luis Gutierrez % Grupo GENESIS - UTN - Argentina % This library is free software; you can redistribute it and/or % modify it under the terms of the GNU Library General Public % License as published by the Free Software Foundation; either % Version 2 of the License, or (at your option) any later version. % % This library is distributed in the hope that it will be useful, % but WITHOUT ANY WARRANTY; without even the implied warranty of % MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU % Library General Public License for more details. % % You should have received a copy of the GNU Library General Public % License along with this library; if not, write to the % Free Software Foundation, Inc., 59 Temple Place - Suite 330, % Boston, MA 02111-1307, USA. x=arg1*1e-6; p=arg2; N=length(x); S=zeros(p+1,p+1); a_aux=zeros(p+1,p);, a_aux(1,:)=1; b_aux=ones(p+1,p); e_aux=zeros(p,1);, p_aux=zeros(p,1); MLE=zeros(3,1); pos=1; for i=0:p for j=0:p for n=0:N-1-i-j S(i+1,j+1)=S(i+1,j+1)+x(n+1+i)*x(n+1+j); end end end e0=S(1,1); c1=S(1,2); d1=S(2,2); coef3=1; coef2=((N-2)*c1)/((N-1)*d1); coef1=-(e0+N*d1)/((N-1)*d1); ti=-(N*c1)/((N-1)*d1); raices=roots([coef3 coef2 coef1 ti]); for o=1:3 if raices(o)>-1 & raices(o)<1 a_aux(2,1)=raices(o); b_aux(p+1,1)=raices(o); end end e_aux(1,1)=S(1,1)+2*a_aux(2,1)*S(1,2)+(a_aux(2,1)^2)*S(2,2); p_aux(1,1)=e_aux(1,1)/N; for k=2:p Ck=S(1:k,2:k+1); Dk=S(2:k+1,2:k+1); ck=a_aux(1:k,k-1)'*Ck*b_aux(p+1:-1:p+2-k,k-1); dk=b_aux(p+1:-1:p+2-k,k-1)'*Dk*b_aux(p+1:-1:p+2-k,k-1); coef3re=1; coef2re=((N-2*k)*ck)/((N-k)*dk); coef1re=-(k*e_aux(k-1,1)+N*dk)/((N-k)*dk); tire=-(N*ck)/((N-k)*dk); raices=roots([coef3re coef2re coef1re tire]); for o=1:3 if raices(o,1)>-1 & raices(o,1)<1 MLE(o,1)=((1-raices(o)^2)^(k/2))/(((e_aux(k-1)+2*ck*raices(o)+dk*(raices(o)^2))/N)^(N/2)); end end [C,I]=max(MLE); k_max=raices(I); for i=1:k-1 a_aux(i+1,k)=a_aux(i+1,k-1)+k_max*a_aux(k-i+1,k-1); end a_aux(k+1,k)=k_max; b_aux(p+1-k:p+1,k)=a_aux(1:k+1,k); e_aux(k,1)=e_aux(k-1,1)+2*ck*k_max+dk*k_max^2; p_aux(k,1)=e_aux(k,1)/N; end a=a_aux(:,p)'; VAR=p_aux(p)*1e12;