Account for fact that varobs is row cell now, not char column array in GSA
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88ae542a8a
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a269bed26e
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@ -20,7 +20,7 @@ function [vdec, cc, ac] = mc_moments(mm, ss, dr)
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global options_ M_ estim_params_ oo_
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[nr1, nc1, nsam] = size(mm);
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nobs=size(options_.varobs,1);
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nobs=size(options_.varobs,2);
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disp('Computing theoretical moments ...')
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h = dyn_waitbar(0,'Theoretical moments ...');
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vdec = zeros(nobs,M_.exo_nbr,nsam);
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@ -1,6 +1,7 @@
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function [vdec, corr, autocorr, z, zz] = th_moments(dr,var_list)
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% [vdec, corr, autocorr, z, zz] = th_moments(dr,var_list)
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% Copyright (C) 2012 Dynare Team
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% Copyright (C) 2012-2015 Dynare Team
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%
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% This file is part of Dynare.
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%
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@ -17,37 +18,37 @@ function [vdec, corr, autocorr, z, zz] = th_moments(dr,var_list)
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% You should have received a copy of the GNU General Public License
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% along with Dynare. If not, see <http://www.gnu.org/licenses/>.
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global M_ oo_ options_
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global M_ oo_ options_
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nvar = size(var_list,1);
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if nvar == 0
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nvar = size(var_list,2);
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if nvar == 0
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nvar = length(dr.order_var);
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ivar = [1:nvar]';
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else
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else
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ivar=zeros(nvar,1);
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for i=1:nvar
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i_tmp = strmatch(var_list(i,:),M_.endo_names,'exact');
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i_tmp = strmatch(var_list(:,i),M_.endo_names,'exact');
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if isempty(i_tmp)
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error (['One of the variable specified does not exist']) ;
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error(['One of the variables specified does not exist']) ;
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else
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ivar(i) = i_tmp;
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end
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end
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end
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end
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[gamma_y,stationary_vars] = th_autocovariances(dr,ivar,M_, options_);
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m = dr.ys(ivar(stationary_vars));
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[gamma_y,stationary_vars] = th_autocovariances(dr,ivar,M_, options_);
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m = dr.ys(ivar(stationary_vars));
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% i1 = find(abs(diag(gamma_y{1})) > 1e-12);
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i1 = [1:length(ivar)];
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s2 = diag(gamma_y{1});
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sd = sqrt(s2);
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i1 = [1:length(ivar)];
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s2 = diag(gamma_y{1});
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sd = sqrt(s2);
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z = [ m sd s2 ];
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mean = m;
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var = gamma_y{1};
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z = [ m sd s2 ];
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mean = m;
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var = gamma_y{1};
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%'THEORETICAL MOMENTS';
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@ -56,9 +57,9 @@ z;
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%'VARIANCE DECOMPOSITION (in percent)';
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if M_.exo_nbr>1,
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vdec = 100*gamma_y{options_.ar+2}(i1,:);
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vdec = 100*gamma_y{options_.ar+2}(i1,:);
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else
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vdec = 100*ones(size(gamma_y{1}(i1,1)));
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vdec = 100*ones(size(gamma_y{1}(i1,1)));
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end
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%'MATRIX OF CORRELATIONS';
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if options_.opt_gsa.useautocorr,
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@ -67,8 +68,8 @@ if options_.opt_gsa.useautocorr,
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else
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corr = gamma_y{1}(i1,i1);
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end
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if options_.ar > 0
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%'COEFFICIENTS OF AUTOCORRELATION';
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if options_.ar > 0
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%'COEFFICIENTS OF AUTOCORRELATION';
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for i=1:options_.ar
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if options_.opt_gsa.useautocorr,
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autocorr{i} = gamma_y{i+1}(i1,i1);
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@ -77,7 +78,6 @@ end
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end
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zz(:,i) = diag(gamma_y{i+1}(i1,i1));
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end
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end
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end
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