2011-12-09 21:13:16 +01:00
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function redform_screen(dirname)
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%function redform_map(dirname)
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% inputs (from opt_gsa structure
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% anamendo = options_gsa_.namendo;
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% anamlagendo = options_gsa_.namlagendo;
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% anamexo = options_gsa_.namexo;
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% iload = options_gsa_.load_redform;
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%
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2012-01-09 13:12:31 +01:00
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% Written by Marco Ratto
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2011-12-09 21:13:16 +01:00
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% Joint Research Centre, The European Commission,
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% (http://eemc.jrc.ec.europa.eu/),
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% marco.ratto@jrc.it
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%
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% Reference:
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% M. Ratto, Global Sensitivity Analysis for Macroeconomic models, MIMEO, 2006.
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2012-01-09 13:12:31 +01:00
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% Copyright (C) 2012 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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2011-12-09 21:13:16 +01:00
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%
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2012-01-09 13:12:31 +01:00
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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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2011-12-09 21:13:16 +01:00
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global M_ oo_ estim_params_ options_ bayestopt_
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options_gsa_ = options_.opt_gsa;
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anamendo = options_gsa_.namendo;
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anamlagendo = options_gsa_.namlagendo;
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anamexo = options_gsa_.namexo;
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iload = options_gsa_.load_redform;
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nliv = options_gsa_.morris_nliv;
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pnames = M_.param_names(estim_params_.param_vals(:,1),:);
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if nargin==0,
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dirname='';
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end
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load([dirname,'/',M_.fname,'_prior'],'lpmat','lpmat0','istable','T');
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nspred=oo_.dr.nspred;
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[kn, np]=size(lpmat);
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nshock = length(bayestopt_.pshape)-np;
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nsok = length(find(M_.lead_lag_incidence(M_.maximum_lag,:)));
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js=0;
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for j=1:size(anamendo,1),
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namendo=deblank(anamendo(j,:));
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iendo=strmatch(namendo,M_.endo_names(oo_.dr.order_var,:),'exact');
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iplo=0;
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ifig=0;
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for jx=1:size(anamexo,1)
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namexo=deblank(anamexo(jx,:));
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iexo=strmatch(namexo,M_.exo_names,'exact');
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if ~isempty(iexo),
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y0=teff(T(iendo,iexo+nspred,:),kn,istable);
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if ~isempty(y0),
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if mod(iplo,9)==0,
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ifig=ifig+1;
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figure('name',[namendo,' vs. shocks ',int2str(ifig)]),
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iplo=0;
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end
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iplo=iplo+1;
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js=js+1;
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subplot(3,3,iplo),
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[SAmeas, SAMorris] = Morris_Measure_Groups(np+nshock, [lpmat0 lpmat], y0,nliv);
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SAM = squeeze(SAMorris(nshock+1:end,1));
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SA(:,js)=SAM./(max(SAM)+eps);
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[saso, iso] = sort(-SA(:,js));
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bar(SA(iso(1:min(np,10)),js))
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%set(gca,'xticklabel',pnames(iso(1:min(np,10)),:),'fontsize',8)
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set(gca,'xticklabel',' ','fontsize',10)
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set(gca,'xlim',[0.5 10.5])
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for ip=1:min(np,10),
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text(ip,-0.02,deblank(pnames(iso(ip),:)),'rotation',90,'HorizontalAlignment','right','interpreter','none')
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end
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title([namendo,' vs. ',namexo],'interpreter','none')
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if iplo==9,
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saveas(gcf,[dirname,'/',M_.fname,'_', namendo,'_vs_shock_',num2str(ifig)])
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eval(['print -depsc2 ' dirname,'/',M_.fname,'_', namendo,'_vs_shock_',num2str(ifig)]);
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eval(['print -dpdf ' dirname,'/',M_.fname,'_', namendo,'_vs_shock_',num2str(ifig)]);
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close(gcf)
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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 iplo<9 & iplo>0 & ifig,
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saveas(gcf,[dirname,'/',M_.fname,'_', namendo,'_vs_shocks_',num2str(ifig)])
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eval(['print -depsc2 ' dirname,'/',M_.fname,'_', namendo,'_vs_shocks_',num2str(ifig)]);
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eval(['print -dpdf ' dirname,'/',M_.fname,'_', namendo,'_vs_shocks_',num2str(ifig)]);
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close(gcf)
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end
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iplo=0;
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ifig=0;
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for je=1:size(anamlagendo,1)
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namlagendo=deblank(anamlagendo(je,:));
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ilagendo=strmatch(namlagendo,M_.endo_names(oo_.dr.order_var(oo_.dr.nstatic+1:oo_.dr.nstatic+nsok),:),'exact');
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if ~isempty(ilagendo),
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y0=teff(T(iendo,ilagendo,:),kn,istable);
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if ~isempty(y0),
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if mod(iplo,9)==0,
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ifig=ifig+1;
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figure('name',[namendo,' vs. lagged endogenous ',int2str(ifig)]),
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iplo=0;
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end
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iplo=iplo+1;
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js=js+1;
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subplot(3,3,iplo),
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[SAmeas, SAMorris] = Morris_Measure_Groups(np+nshock, [lpmat0 lpmat], y0,nliv);
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SAM = squeeze(SAMorris(nshock+1:end,1));
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SA(:,js)=SAM./(max(SAM)+eps);
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[saso, iso] = sort(-SA(:,js));
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bar(SA(iso(1:min(np,10)),js))
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%set(gca,'xticklabel',pnames(iso(1:min(np,10)),:),'fontsize',8)
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set(gca,'xticklabel',' ','fontsize',10)
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set(gca,'xlim',[0.5 10.5])
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for ip=1:min(np,10),
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text(ip,-0.02,deblank(pnames(iso(ip),:)),'rotation',90,'HorizontalAlignment','right','interpreter','none')
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end
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title([namendo,' vs. ',namlagendo,'(-1)'],'interpreter','none')
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if iplo==9,
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saveas(gcf,[dirname,'/',M_.fname,'_', namendo,'_vs_lags_',num2str(ifig)])
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eval(['print -depsc2 ' dirname,'/',M_.fname,'_', namendo,'_vs_lags_',num2str(ifig)]);
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eval(['print -dpdf ' dirname,'/',M_.fname,'_', namendo,'_vs_lags_',num2str(ifig)]);
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close(gcf)
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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 iplo<9 & iplo>0 & ifig,
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saveas(gcf,[dirname,'/',M_.fname,'_', namendo,'_vs_lags_',num2str(ifig)])
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eval(['print -depsc2 ' dirname,'/',M_.fname,'_', namendo,'_vs_lags_',num2str(ifig)]);
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eval(['print -dpdf ' dirname,'/',M_.fname,'_', namendo,'_vs_lags_',num2str(ifig)]);
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close(gcf)
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end
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end
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figure,
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%bar(SA)
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% boxplot(SA','whis',10,'symbol','r.')
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myboxplot(SA',[],'.',[],10)
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set(gca,'xticklabel',' ','fontsize',10,'xtick',[1:np])
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set(gca,'xlim',[0.5 np+0.5])
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set(gca,'ylim',[0 1])
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set(gca,'position',[0.13 0.2 0.775 0.7])
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for ip=1:np,
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text(ip,-0.02,deblank(pnames(ip,:)),'rotation',90,'HorizontalAlignment','right','interpreter','none')
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end
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xlabel(' ')
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ylabel('Elementary Effects')
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title('Reduced form screening')
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saveas(gcf,[dirname,'/',M_.fname,'_redform_screen'])
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eval(['print -depsc2 ' dirname,'/',M_.fname,'_redform_screen']);
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eval(['print -dpdf ' dirname,'/',M_.fname,'_redform_screen']);
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