122 lines
4.0 KiB
Matlab
122 lines
4.0 KiB
Matlab
function [x,f,abscissa,dens,binf,bsup] = draw_prior_density(indx);
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% function [x,f,abscissa,dens,binf,bsup] = draw_prior_density(indx)
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% plots prior density
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%
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% INPUTS
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% indx: parameter number
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%
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% OUTPUTS
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% x: subset of 'abscissa' such as the density is less than 10
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% f: subset of 'dens' such as the density is less than 10
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% abscissa: abscissa
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% dens: density
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% binf: lower bound of the truncated prior
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% bsup: upper bound of the truncated prior
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%
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% SPECIAL REQUIREMENTS
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% none
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% Copyright (C) 2004-2008 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 bayestopt_
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pmean = bayestopt_.pmean;
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pshape = bayestopt_.pshape;
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p1 = bayestopt_.p1;
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p2 = bayestopt_.p2;
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p3 = bayestopt_.p3;
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p4 = bayestopt_.p4;
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truncprior = 10^(-3);
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if pshape(indx) == 1 %/* BETA Prior */
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density = inline('((bb-x).^(b-1)).*(x-aa).^(a-1)./(beta(a,b)*(bb-aa)^(a+b-1))','x','a','b','aa','bb');
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mu = (p1(indx)-p3(indx))/(p4(indx)-p3(indx));
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stdd = p2(indx)/(p4(indx)-p3(indx));
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a = (1-mu)*mu^2/stdd^2 - mu;
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b = a*(1/mu-1);
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aa = p3(indx);
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bb = p4(indx);
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infbound = qbeta(truncprior,a,b)*(bb-aa)+aa;
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supbound = qbeta(1-truncprior,a,b)*(bb-aa)+aa;
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stepsize = (supbound-infbound)/200;
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abscissa = infbound:stepsize:supbound;
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dens = density(abscissa,a,b,aa,bb);
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elseif pshape(indx) == 2 %/* GAMMA PRIOR */
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mu = p1(indx)-p3(indx);
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b = p2(indx)^2/mu;
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a = mu/b;
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infbound = mj_qgamma(truncprior,a)*b;
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supbound = mj_qgamma(1-truncprior,a)*b;
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stepsize = (supbound-infbound)/200;
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abscissa = infbound:stepsize:supbound;
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dens = exp(lpdfgam(abscissa,a,b));
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abscissa = abscissa + p3(indx);
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elseif pshape(indx) == 3 %/* GAUSSIAN PRIOR */
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density = inline('inv(sqrt(2*pi)*b)*exp(-0.5*((x-a)/b).^2)','x','a','b');
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a = p1(indx);
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b = p2(indx);
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infbound = norminv(truncprior,a,b);
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supbound = norminv(1-truncprior,a,b);
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stepsize = (supbound-infbound)/200;
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abscissa = infbound:stepsize:supbound;
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dens = density(abscissa,a,b);
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elseif pshape(indx) == 4 %/* INVGAMMA PRIOR type 1 */
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density = inline('2*inv(gamma(nu/2))*(x.^(-nu-1))*((s/2)^(nu/2)).*exp(-s./(2*x.^2))','x','s','nu');
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nu = p2(indx);
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s = p1(indx);
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a = nu/2;
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b = 2/s;
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infbound = 1/sqrt(mj_qgamma(1-10*truncprior,a)*b);
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supbound = 1/sqrt(mj_qgamma(10*truncprior,a)*b);
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stepsize = (supbound-infbound)/200;
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abscissa = infbound:stepsize:supbound;
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dens = density(abscissa,s,nu);
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elseif pshape(indx) == 5 %/* UNIFORM PRIOR */
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density = inline('(x.^0)/(b-a)','x','a','b');
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a = p1(indx);
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b = p2(indx);
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infbound = a;
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supbound = b;
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stepsize = (supbound-infbound)/200;
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abscissa = infbound:stepsize:supbound;
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dens = density(abscissa,a,b);
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elseif pshape(indx) == 6 %/* INVGAMMA PRIOR type 2 */
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density = inline('inv(gamma(nu/2))*(x.^(-.5*(nu+2)))*((s/2)^(nu/2)).*exp(-s./(2*x))','x','s','nu');
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nu = p2(indx);
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s = p1(indx);
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a = nu/2;
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b = 2/s;
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infbound = 1/(qgamma(1-truncprior,a)*b);
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supbound = 1/(qgamma(truncprior,a)*b);
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stepsize = (supbound-infbound)/200;
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abscissa = infbound:stepsize:supbound;
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dens = density(abscissa,s,nu);
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end
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k = [1:length(dens)];
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if pshape(indx) ~= 5
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[junk,k1] = max(dens);
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if k1 == 1 | k1 == length(dens)
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k = find(dens < 10);
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end
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end
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binf = abscissa(k(1));
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bsup = abscissa(k(length(k)));
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x = abscissa(k);
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f = dens(k); |