143 lines
3.3 KiB
Matlab
143 lines
3.3 KiB
Matlab
function return_resample = residual_resampling(particles,weights,noise)
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% Resamples particles.
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%@info:
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%! @deftypefn {Function File} {@var{indx} =} residual_resampling (@var{weights})
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%! @anchor{particle/residual_resampling}
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%! @sp 1
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%! Resamples particles.
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%! @sp 2
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%! @strong{Inputs}
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%! @sp 1
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%! @table @ @var
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%! @item weights
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%! n*1 vector of doubles, particles' weights.
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%! @end table
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%! @sp 2
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%! @strong{Outputs}
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%! @sp 1
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%! @table @ @var
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%! @item indx
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%! n*1 vector of intergers, indices.
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%! @end table
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%! @sp 2
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%! @strong{This function is called by:}
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%! @sp 1
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%! @ref{particle/resample}
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%! @sp 2
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%! @strong{This function calls:}
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%! @sp 2
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%! @end deftypefn
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%@eod:
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% Copyright (C) 2011-2013 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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% AUTHOR(S) frederic DOT karame AT univ DASH evry DOT fr
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% stephane DOT adjemian AT univ DASH lemans DOT fr
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% What is the number of particles?
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number_of_particles = length(weights);
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switch length(noise)
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case 1
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kitagawa_resampling = 1;
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case number_of_particles
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kitagawa_resampling = 0;
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otherwise
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error(['particle::resampling: Unknown method! The size of the second argument (' inputname(noise) ') is wrong.'])
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end
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% Set vectors of indices.
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jndx = 1:number_of_particles;
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indx = zeros(1,number_of_particles);
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% Multiply the weights by the number of particles.
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WEIGHTS = number_of_particles*weights;
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% Compute the integer part of the normalized weights.
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iWEIGHTS = fix(WEIGHTS);
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% Compute the number of resample
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number_of_trials = number_of_particles-sum(iWEIGHTS);
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if number_of_trials
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WEIGHTS = (WEIGHTS-iWEIGHTS)/number_of_trials;
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EmpiricalCDF = cumsum(WEIGHTS);
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if kitagawa_resampling
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u = (transpose(1:number_of_trials)-1+noise(:))/number_of_trials;
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else
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u = fliplr(cumprod(noise(1:number_of_trials).^(1./(number_of_trials:-1:1))));
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end
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j=1;
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for i=1:number_of_trials
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while (u(i)>EmpiricalCDF(j))
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j=j+1;
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end
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iWEIGHTS(j)=iWEIGHTS(j)+1;
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if kitagawa_resampling==0
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j=1;
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end
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end
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end
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k=1;
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for i=1:number_of_particles
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if (iWEIGHTS(i)>0)
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for j=k:k+iWEIGHTS(i)-1
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indx(j) = jndx(i);
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end
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end
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k = k + iWEIGHTS(i);
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end
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if particles==0
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return_resample = indx ;
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else
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return_resample = particles(indx,:) ;
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end
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%@test:1
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%$ % Define the weights
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%$ weights = randn(2000,1).^2;
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%$ weights = weights/sum(weights);
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%$ % Initialize t.
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%$ t = ones(1,1);
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%$
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%$ try
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%$ indx1 = residual_resampling(weights);
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%$ catch
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%$ t(1) = 0;
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%$ end
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%$
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%$ T = all(t);
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%@eof:1
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%@test:2
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%$ % Define the weights
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%$ weights = exp(randn(2000,1));
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%$ weights = weights/sum(weights);
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%$ % Initialize t.
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%$ t = ones(1,1);
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%$
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%$ try
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%$ indx1 = residual_resampling(weights);
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%$ catch
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%$ t(1) = 0;
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%$ end
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%$
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%$ T = all(t);
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%@eof:2 |