function oo_recursive_=dynare_estimation(var_list,dname) % function dynare_estimation(var_list) % runs the estimation of the model % % INPUTS % var_list: selected endogenous variables vector % % OUTPUTS % oo_recursive_: cell array containing the results structures from recursive estimation % % SPECIAL REQUIREMENTS % none % Copyright (C) 2003-2014 Dynare Team % % This file is part of Dynare. % % Dynare is free software: you can redistribute it and/or modify % it under the terms of the GNU General Public License as published by % the Free Software Foundation, either version 3 of the License, or % (at your option) any later version. % % Dynare 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 General Public License for more details. % % You should have received a copy of the GNU General Public License % along with Dynare. If not, see . global options_ oo_ M_ dataset_ oo_recursive_={}; % Test if the order of approximation is nonzero (the preprocessor tests if order is non negative). if isequal(options_.order,0) error('Estimation:: The order of the Taylor approximation cannot be 0!') end % Decide if a DSGE or DSGE-VAR has to be estimated. if ~isempty(strmatch('dsge_prior_weight',M_.param_names)) options_.dsge_var = 1; end var_list = check_list_of_variables(options_, M_, var_list); options_.varlist = var_list; if isfield(options_,'nobs') nobs = sort(options_.nobs); else nobs = []; end nnobs = length(nobs); horizon = options_.forecast; if nargin<2 || ~exist(dname) || isempty(dname) dname = M_.fname; end M_.dname = dname; if (isnumeric(options_.mode_compute) && options_.mode_compute && options_.analytic_derivation) ... %no user supplied function || (~isnumeric(options_.mode_compute) && options_.analytic_derivation) % user supplied function analytic_derivation0=options_.analytic_derivation; options_.analytic_derivation=1; end if options_.logged_steady_state oo_.dr.ys=exp(oo_.dr.ys); oo_.steady_state=exp(oo_.steady_state); end if nnobs > 1 for i=1:nnobs options_.nobs = nobs(i); M_.dname = [dname '_' int2str(nobs(i))]; dynare_estimation_1(var_list,M_.dname); if isequal(i,1) options_.mode_file = [M_.fname '_mode']; end if options_.recursive_estimation_restart for j=1:options_.recursive_estimation_restart dynare_estimation_1(var_list,M_.dname); end end oo_recursive_{nobs(i)} = oo_; end else dynare_estimation_1(var_list,dname); end if options_.mode_compute && options_.analytic_derivation, options_.analytic_derivation=analytic_derivation0; end if nnobs > 1 && horizon > 0 mh_replic = options_.mh_replic; endo_names = M_.endo_names; n_varobs = length(options_.varobs); if isempty(var_list) var_list = endo_names; nvar = size(endo_names,1); SelecVariables = transpose(1:nvar); else nvar = size(var_list,1); SelecVariables = []; for i=1:nvar if ~isempty(strmatch(var_list(i,:),endo_names,'exact')) SelecVariables = [SelecVariables;strmatch(var_list(i,:),endo_names, 'exact')]; else error(['Estimation:: ' var_list(i,:) ' isn''t an endogenous variable']) end end end IdObs = zeros(n_varobs,1); for j=1:n_varobs iobs = strmatch(options_.varobs{j},var_list,'exact'); if ~isempty(iobs) IdObs(j,1) = iobs; end end gend = dataset_.nobs; time_offset=min(3,gend-1); %for observables, plot 3 previous periods unless data is shorter k = time_offset+min(nobs(end)-nobs(1)+horizon, ... size(dataset_.data,1)-nobs(1)); data2 = dataset_.data(end-k+1:end,:); [nbplt,nr,nc,lr,lc,nstar] = pltorg(nvar); m = 1; plot_index=0; OutputDirectoryName = CheckPath('graphs',M_.fname); for i = 1:size(var_list,1) if mod(i,nstar) == 1 plot_index=plot_index+1; hfig = dyn_figure(options_,'Name',['Out of sample forecasts (',num2str(plot_index),')']); m = 1; end subplot(nr,nc,m) hold on if any(i==IdObs) k2 = find(i==IdObs); offsetx = 3; plot(nobs(1)-offsetx+1:nobs(1)-offsetx+k,data2(end-k+1:end,k2)','-k','linewidth',2); else offsetx = 0; end vname = deblank(var_list(i,:)); for j=1:nnobs if mh_replic > 0 oo_.RecursiveForecast.Mean.(vname)(j,:) = ... oo_recursive_{nobs(j)}.MeanForecast.Mean.(vname); oo_.RecursiveForecast.HPDinf.(vname)(j,:) = ... oo_recursive_{nobs(j)}.MeanForecast.HPDinf.(vname); oo_.RecursiveForecast.HPDsup.(vname)(j,:) = ... oo_recursive_{nobs(j)}.MeanForecast.HPDsup.(vname); oo_.RecursiveForecast.HPDTotalinf.(vname)(j,:) = ... oo_recursive_{nobs(j)}.PointForecast.HPDinf.(vname); oo_.RecursiveForecast.HPDTotalsup.(vname)(j,:) = ... oo_recursive_{nobs(j)}.PointForecast.HPDsup.(vname); else oo_.RecursiveForecast.Mean.(vname)(j,:) =... oo_recursive_{nobs(j)}.forecast.Mean.(vname); oo_.RecursiveForecast.HPDinf.(vname)(j,:) =... oo_recursive_{nobs(j)}.forecast.HPDinf.(vname); oo_.RecursiveForecast.HPDsup.(vname)(j,:) =... oo_recursive_{nobs(j)}.forecast.HPDsup.(vname); end x = nobs(1)+nobs(j)-nobs(1)+(1:horizon); y = oo_.RecursiveForecast.Mean.(vname)(j,:); y1 = oo_.RecursiveForecast.HPDinf.(vname)(j,:); y2 = oo_.RecursiveForecast.HPDsup.(vname)(j,:); plot(x,y,'-b','linewidth',2) plot(x,y1,'--g', ... 'linewidth',1.5) plot(x,y2,'--g', ... 'linewidth',1.5) if mh_replic y3 = oo_.RecursiveForecast.HPDTotalinf.(vname)(j,:); y4 = oo_.RecursiveForecast.HPDTotalsup.(vname)(j,:); plot(x,y3,'--r', ... 'linewidth',1.5) plot(x,y4,'--r','linewidth',1.5) end end box on title(vname,'Interpreter','none') hold off xlim([nobs(1)-offsetx nobs(end)+horizon]) m = m + 1; if mod(i+1,nstar) == 1 || i ==size(var_list,1) dyn_saveas(hfig,[M_.fname,filesep,'graphs',filesep M_.fname '_RecursiveForecasts_' int2str(plot_index)],options_); end end end