368 lines
15 KiB
Matlab
368 lines
15 KiB
Matlab
function pm3(n1,n2,ifil,B,tit1,tit2,tit3,tit_tex,names1,names2,name3,DirectoryName,var_type)
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% pm3(n1,n2,ifil,B,tit1,tit2,tit3,tit_tex,names1,names2,name3,DirectoryName,var_type)
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% Computes, stores and plots the posterior moment statistics.
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%
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% Inputs:
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% n1 [scalar] size of first dimension of moment matrix
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% n2 [scalar] size of second dimension of moment matrix
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% ifil [scalar] number of moment files to load
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% B [scalar] number of subdraws
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% tit1 [string] Figure title
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% tit2 [string] not used
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% tit3 [string] Save name for figure
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% tit_tex [cell array] TeX-Names for Variables
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% names1 [cell array] Names of all variables in the moment matrix from
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% which names2 is selected
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% names2 [cell array] Names of variables subset selected for moments
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% names3 [string] Name of the field in oo_ structure to be set
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% DirectoryName [string] Name of the directory in which to save and from
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% where to read
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% var_type [string] suffix of the filename from which to load moment
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% matrix
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% PARALLEL CONTEXT
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% See also the comment in posterior_sampler.m funtion.
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% Copyright (C) 2007-2016 Dynare Team
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%
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% This file is part of Dynare.
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%
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% Dynare is free software: you can redistribute it and/or modify
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% it under the terms of the GNU General Public License as published by
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% the Free Software Foundation, either version 3 of the License, or
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% (at your option) any later version.
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%
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% Dynare is distributed in the hope that it will be useful,
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% but WITHOUT ANY WARRANTY; without even the implied warranty of
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% MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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% GNU General Public License for more details.
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%
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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 options_ M_ oo_
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nn = 3;
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MaxNumberOfPlotsPerFigure = nn^2; % must be square
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varlist = names2;
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if isempty(varlist)
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varlist = names1;
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SelecVariables = (1:M_.endo_nbr)';
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nvar = M_.endo_nbr;
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else
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nvar = size(varlist,1);
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SelecVariables = [];
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for i=1:nvar
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if ~isempty(strmatch(varlist(i,:),names1,'exact'))
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SelecVariables = [SelecVariables;strmatch(varlist(i,:),names1,'exact')];
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end
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end
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end
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if options_.TeX
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if isempty(tit_tex),
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tit_tex=names1;
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end
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varlist_TeX = [];
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for i=1:nvar
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if i==1
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varlist_TeX = tit_tex(SelecVariables(i),:);
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else
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varlist_TeX = char(varlist_TeX,tit_tex(SelecVariables(i),:));
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end
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end
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end
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Mean = zeros(n2,nvar);
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Median = zeros(n2,nvar);
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Var = zeros(n2,nvar);
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Distrib = zeros(9,n2,nvar);
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HPD = zeros(2,n2,nvar);
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if options_.estimation.moments_posterior_density.indicator
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Density = zeros(options_.estimation.moments_posterior_density.gridpoints,2,n2,nvar);
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end
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fprintf(['Estimation::mcmc: ' tit1 '\n']);
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k = 0;
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filter_step_ahead_indicator=0;
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filter_covar_indicator=0;
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for file = 1:ifil
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load([DirectoryName '/' M_.fname var_type int2str(file)]);
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if strcmp(var_type,'_filter_step_ahead')
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if file==1 %on first run, initialize variable for storing filter_step_ahead
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stock1_filter_step_ahead=NaN(n1,n2,B,length(options_.filter_step_ahead));
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stock1 = zeros(n1,n2,B);
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end
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filter_step_ahead_indicator=1;
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stock_filter_step_ahead=zeros(n1,n2,size(stock,4),length(options_.filter_step_ahead));
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for ii=1:length(options_.filter_step_ahead)
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K_step_ahead=options_.filter_step_ahead(ii);
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stock_filter_step_ahead(:,:,:,ii)=stock(ii,:,1+K_step_ahead:n2+K_step_ahead,:);
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end
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stock = squeeze(stock(1,:,1+1:1+n2,:)); %1 step ahead starts at entry 2
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k = k(end)+(1:size(stock,3));
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stock1(:,:,k) = stock;
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stock1_filter_step_ahead(:,:,k,:) = stock_filter_step_ahead;
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elseif strcmp(var_type,'_filter_covar')
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if file==1 %on first run, initialize variable for storing filter_step_ahead
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stock1_filter_covar=NaN(n1,n2,size(stock,3),B);
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end
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filter_covar_indicator=1;
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k = k(end)+(1:size(stock,4));
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stock1_filter_covar(:,:,:,k) = stock;
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elseif strcmp(var_type,'_trend_coeff')
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if file==1 %on first run, initialize variable for storing filter_step_ahead
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stock1_filter_step_ahead=NaN(n1,n2,B,length(options_.filter_step_ahead));
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stock1 = zeros(n1,B);
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end
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k = k(end)+(1:size(stock,2));
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stock1(:,k) = stock;
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else
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if file==1 %on first run, initialize variable for storing filter_step_ahead
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stock1 = zeros(n1,n2,B);
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end
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k = k(end)+(1:size(stock,3));
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stock1(:,:,k) = stock;
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end
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end
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clear stock
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if filter_step_ahead_indicator
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clear stock_filter_step_ahead
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filter_steps=length(options_.filter_step_ahead);
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Mean_filter_step_ahead = zeros(filter_steps,nvar,n2);
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Median_filter_step_ahead = zeros(filter_steps,nvar,n2);
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Var_filter_step_ahead = zeros(filter_steps,nvar,n2);
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Distrib_filter_step_ahead = zeros(9,filter_steps,nvar,n2);
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HPD_filter_step_ahead = zeros(2,filter_steps,nvar,n2);
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if options_.estimation.moments_posterior_density.indicator
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Density_filter_step_ahead = zeros(options_.estimation.moments_posterior_density.gridpoints,2,filter_steps,nvar,n2);
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end
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end
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if filter_covar_indicator
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draw_dimension=4;
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oo_.FilterCovariance.Mean = squeeze(mean(stock1_filter_covar,draw_dimension));
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oo_.FilterCovariance.Median = squeeze(median(stock1_filter_covar,draw_dimension));
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oo_.FilterCovariance.var = squeeze(var(stock1_filter_covar,0,draw_dimension));
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if size(stock1_filter_covar,draw_dimension)>2
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hpd_interval = quantile(stock1_filter_covar,[(1-options_.mh_conf_sig)/2 (1-options_.mh_conf_sig)/2+options_.mh_conf_sig],draw_dimension);
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else
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size_matrix=size(stock1_filter_covar);
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hpd_interval=NaN([size_matrix(1:3),2]);
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end
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if size(stock1_filter_covar,draw_dimension)>9
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post_deciles =quantile(stock1_filter_covar,[0.1:0.1:0.9],draw_dimension);
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else
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size_matrix=size(stock1_filter_covar);
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post_deciles=NaN([size_matrix(1:3),9]);
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end
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oo_.FilterCovariance.post_deciles=post_deciles;
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oo_.FilterCovariance.HPDinf=squeeze(hpd_interval(:,:,:,1));
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oo_.FilterCovariance.HPDsup=squeeze(hpd_interval(:,:,:,2));
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fprintf(['Estimation::mcmc: ' tit1 ', done!\n']);
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return
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end
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if strcmp(var_type,'_trend_coeff') %two dimensional arrays
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for i = 1:nvar
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if options_.estimation.moments_posterior_density.indicator
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[Mean(1,i),Median(1,i),Var(1,i),HPD(:,1,i),Distrib(:,1,i),Density(:,:,1,i)] = ...
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posterior_moments(squeeze(stock1(SelecVariables(i),:)),1,options_.mh_conf_sig,options_.estimation.moments_posterior_density);
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else
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[Mean(1,i),Median(1,i),Var(1,i),HPD(:,1,i),Distrib(:,1,i)] = ...
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posterior_moments(squeeze(stock1(SelecVariables(i),:)),0,options_.mh_conf_sig);
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end
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end
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else %three dimensional arrays
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for i = 1:nvar
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for j = 1:n2
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if options_.estimation.moments_posterior_density.indicator
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[Mean(j,i),Median(j,i),Var(j,i),HPD(:,j,i),Distrib(:,j,i),Density(:,:,j,i)] = ...
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posterior_moments(squeeze(stock1(SelecVariables(i),j,:)),1,options_.mh_conf_sig,options_.estimation.moments_posterior_density);
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else
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[Mean(j,i),Median(j,i),Var(j,i),HPD(:,j,i),Distrib(:,j,i)] = ...
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posterior_moments(squeeze(stock1(SelecVariables(i),j,:)),0,options_.mh_conf_sig);
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end
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if filter_step_ahead_indicator
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if options_.estimation.moments_posterior_density.indicator
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for K_step = 1:length(options_.filter_step_ahead)
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[Mean_filter_step_ahead(K_step,i,j),Median_filter_step_ahead(K_step,i,j),Var_filter_step_ahead(K_step,i,j),HPD_filter_step_ahead(:,K_step,i,j),Distrib_filter_step_ahead(:,K_step,i,j),Density_filter_step_ahead(:,:,K_step,i,j) ] = ...
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posterior_moments(squeeze(stock1_filter_step_ahead(SelecVariables(i),j,:,K_step)),1,options_.mh_conf_sig,options_.estimation.moments_posterior_density);
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end
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else
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for K_step = 1:length(options_.filter_step_ahead)
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[Mean_filter_step_ahead(K_step,i,j),Median_filter_step_ahead(K_step,i,j),Var_filter_step_ahead(K_step,i,j),HPD_filter_step_ahead(:,K_step,i,j),Distrib_filter_step_ahead(:,K_step,i,j)] = ...
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posterior_moments(squeeze(stock1_filter_step_ahead(SelecVariables(i),j,:,K_step)),0,options_.mh_conf_sig);
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end
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end
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end
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end
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end
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end
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clear stock1
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if filter_step_ahead_indicator %write matrices corresponding to ML
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clear stock1_filter_step_ahead
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FilteredVariablesKStepAhead=zeros(length(options_.filter_step_ahead),nvar,n2+max(options_.filter_step_ahead));
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FilteredVariablesKStepAheadVariances=zeros(length(options_.filter_step_ahead),nvar,n2+max(options_.filter_step_ahead));
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for K_step = 1:length(options_.filter_step_ahead)
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FilteredVariablesKStepAhead(K_step,:,1+options_.filter_step_ahead(K_step):n2+options_.filter_step_ahead(K_step))=Mean_filter_step_ahead(K_step,:,:);
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FilteredVariablesKStepAheadVariances(K_step,:,1+options_.filter_step_ahead(K_step):n2+options_.filter_step_ahead(K_step))=Mean_filter_step_ahead(K_step,:,:);
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end
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oo_.FilteredVariablesKStepAhead=FilteredVariablesKStepAhead;
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oo_.FilteredVariablesKStepAheadVariances=FilteredVariablesKStepAheadVariances;
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end
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if strcmp(var_type,'_trend_coeff') || strcmp(var_type,'_smoothed_trend') || strcmp(var_type,'_smoothed_trend')
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for i = 1:nvar
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name = deblank(names1(SelecVariables(i),:));
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oo_.Smoother.(name3).Mean.(name) = Mean(:,i);
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oo_.Smoother.(name3).Median.(name) = Median(:,i);
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oo_.Smoother.(name3).Var.(name) = Var(:,i);
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oo_.Smoother.(name3).deciles.(name) = Distrib(:,:,i);
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oo_.Smoother.(name3).HPDinf.(name) = HPD(1,:,i)';
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oo_.Smoother.(name3).HPDsup.(name) = HPD(2,:,i)';
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if options_.estimation.moments_posterior_density.indicator
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oo_.Smoother.(name3).density.(name) = Density(:,:,:,i);
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end
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end
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else
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for i = 1:nvar
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name = deblank(names1(SelecVariables(i),:));
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oo_.(name3).Mean.(name) = Mean(:,i);
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oo_.(name3).Median.(name) = Median(:,i);
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oo_.(name3).Var.(name) = Var(:,i);
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oo_.(name3).deciles.(name) = Distrib(:,:,i);
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oo_.(name3).HPDinf.(name) = HPD(1,:,i)';
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oo_.(name3).HPDsup.(name) = HPD(2,:,i)';
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if options_.estimation.moments_posterior_density.indicator
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oo_.(name3).density.(name) = Density(:,:,:,i);
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end
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if filter_step_ahead_indicator
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for K_step = 1:length(options_.filter_step_ahead)
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name4=['Filtered_Variables_',num2str(K_step),'_step_ahead'];
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oo_.(name4).Mean.(name) = squeeze(Mean_filter_step_ahead(K_step,i,:));
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oo_.(name4).Median.(name) = squeeze(Median_filter_step_ahead(K_step,i,:));
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oo_.(name4).Var.(name) = squeeze(Var_filter_step_ahead(K_step,i,:));
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oo_.(name4).deciles.(name) = squeeze(Distrib_filter_step_ahead(:,K_step,i,:));
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oo_.(name4).HPDinf.(name) = squeeze(HPD_filter_step_ahead(1,K_step,i,:));
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oo_.(name4).HPDsup.(name) = squeeze(HPD_filter_step_ahead(2,K_step,i,:));
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if options_.estimation.moments_posterior_density.indicator
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oo_.(name4).density.(name) = squeeze(Density_filter_step_ahead(:,:,K_step,i,:));
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end
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end
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end
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end
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end
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if strcmp(var_type,'_trend_coeff') || max(max(abs(Mean(:,:))))<=10^(-6) || all(all(isnan(Mean)))
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fprintf(['Estimation::mcmc: ' tit1 ', done!\n']);
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return %not do plots
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end
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%%
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%% Finally I build the plots.
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%%
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% Block of code executed in parallel, with the exception of file
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% .tex generation always run sequentially. This portion of code is execute in parallel by
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% pm3_core1.m function.
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% %%%%%%%%% PARALLEL BLOCK % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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%
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% %%% The file .TeX! are not saved in parallel.
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% Store the variable mandatory for local/remote parallel computing.
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localVars=[];
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localVars.tit1=tit1;
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localVars.nn=nn;
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localVars.n2=n2;
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localVars.Distrib=Distrib;
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localVars.varlist=varlist;
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localVars.MaxNumberOfPlotsPerFigure=MaxNumberOfPlotsPerFigure;
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localVars.name3=name3;
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localVars.tit3=tit3;
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localVars.Mean=Mean;
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% Like sequential execution!
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nvar0=nvar;
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if ~isoctave
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% Commenting for testing!
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if isnumeric(options_.parallel) || ceil(size(varlist,1)/MaxNumberOfPlotsPerFigure)<4,
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fout = pm3_core(localVars,1,nvar,0);
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% Parallel execution!
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else
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isRemoteOctave = 0;
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for indPC=1:length(options_.parallel),
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isRemoteOctave = isRemoteOctave + (findstr(options_.parallel(indPC).MatlabOctavePath, 'octave'));
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end
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if isRemoteOctave
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fout = pm3_core(localVars,1,nvar,0);
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else
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globalVars = struct('M_',M_, ...
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'options_', options_, ...
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'oo_', oo_);
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[fout, nvar0, totCPU] = masterParallel(options_.parallel, 1, nvar, [],'pm3_core', localVars,globalVars, options_.parallel_info);
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end
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end
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else
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% For the time being in Octave enviroment the pm3.m is executed only in
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% serial modality, to avoid problem with the plots.
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fout = pm3_core(localVars,1,nvar,0);
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end
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subplotnum = 0;
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if options_.TeX && any(strcmp('eps',cellstr(options_.graph_format)))
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fidTeX = fopen([M_.dname '/Output/' M_.fname '_' name3 '.tex'],'w');
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fprintf(fidTeX,'%% TeX eps-loader file generated by Dynare.\n');
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fprintf(fidTeX,['%% ' datestr(now,0) '\n']);
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fprintf(fidTeX,' \n');
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nvar0=cumsum(nvar0);
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i=0;
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for j=1:length(nvar0),
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NAMES = [];
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TEXNAMES = [];
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nvar=nvar0(j);
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while i<nvar,
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i=i+1;
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if max(abs(Mean(:,i))) > 10^(-6)
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subplotnum = subplotnum+1;
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name = deblank(varlist(i,:));
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texname = deblank(varlist_TeX(i,:));
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if subplotnum==1
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NAMES = name;
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TEXNAMES = ['$' texname '$'];
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else
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NAMES = char(NAMES,name);
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TEXNAMES = char(TEXNAMES,['$' texname '$']);
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end
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end
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if subplotnum == MaxNumberOfPlotsPerFigure || i == nvar
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fprintf(fidTeX,'\\begin{figure}[H]\n');
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for jj = 1:size(TEXNAMES,1)
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fprintf(fidTeX,['\\psfrag{%s}[1][][0.5][0]{%s}\n'],deblank(NAMES(jj,:)),deblank(TEXNAMES(jj,:)));
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end
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fprintf(fidTeX,'\\centering \n');
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fprintf(fidTeX,['\\includegraphics[width=%2.2f\\textwidth]{%s/Output/%s_' name3 '_%s}\n'],options_.figures.textwidth*min(subplotnum/nn,1),M_.dname,M_.fname,deblank(tit3(i,:)));
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fprintf(fidTeX,'\\label{Fig:%s:%s}\n',name3,deblank(tit3(i,:)));
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fprintf(fidTeX,'\\caption{%s}\n',tit1);
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fprintf(fidTeX,'\\end{figure}\n');
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fprintf(fidTeX,' \n');
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subplotnum = 0;
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NAMES = [];
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TEXNAMES = [];
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end
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end
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end
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fprintf(fidTeX,'%% End of TeX file.\n');
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fclose(fidTeX);
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end
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fprintf(['Estimation::mcmc: ' tit1 ', done!\n']); |