function oo_ = sim1_lbj(options_, M_, oo_) % function sim1_lbj % performs deterministic simulations with lead or lag on one period % using the historical LBJ algorithm % % INPUTS % ... % OUTPUTS % ... % ALGORITHM % Laffargue, Boucekkine, Juillard (LBJ) % see Juillard (1996) Dynare: A program for the resolution and % simulation of dynamic models with forward variables through the use % of a relaxation algorithm. CEPREMAP. Couverture Orange. 9602. % % SPECIAL REQUIREMENTS % None. % Copyright (C) 1996-2015 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 . lead_lag_incidence = M_.lead_lag_incidence; ny = size(oo_.endo_simul,1) ; nyp = nnz(lead_lag_incidence(1,:)) ; nyf = nnz(lead_lag_incidence(3,:)) ; nrs = ny+nyp+nyf+1 ; nrc = nyf+1 ; iyf = find(lead_lag_incidence(3,:)>0) ; iyp = find(lead_lag_incidence(1,:)>0) ; isp = [1:nyp] ; is = [nyp+1:ny+nyp] ; isf = iyf+nyp ; isf1 = [nyp+ny+1:nyf+nyp+ny+1] ; stop = 0 ; iz = [1:ny+nyp+nyf]; verbose = options_.verbosity; if verbose printline(56) disp(['MODEL SIMULATION :']) skipline() end it_init = M_.maximum_lag+1 ; h1 = clock ; for iter = 1:options_.simul.maxit h2 = clock ; if options_.terminal_condition == 0 c = zeros(ny*options_.periods,nrc) ; else c = zeros(ny*(options_.periods+1),nrc) ; end it_ = it_init ; z = [oo_.endo_simul(iyp,it_-1) ; oo_.endo_simul(:,it_) ; oo_.endo_simul(iyf,it_+1)] ; [d1,jacobian] = feval([M_.fname '_dynamic'],z,oo_.exo_simul, M_.params, oo_.steady_state,it_); jacobian = [jacobian(:,iz) -d1] ; ic = [1:ny] ; icp = iyp ; c (ic,:) = jacobian(:,is)\jacobian(:,isf1) ; for it_ = it_init+(1:options_.periods-1) z = [oo_.endo_simul(iyp,it_-1) ; oo_.endo_simul(:,it_) ; oo_.endo_simul(iyf,it_+1)] ; [d1,jacobian] = feval([M_.fname '_dynamic'],z,oo_.exo_simul, ... M_.params, oo_.steady_state, it_); jacobian = [jacobian(:,iz) -d1] ; jacobian(:,[isf nrs]) = jacobian(:,[isf nrs])-jacobian(:,isp)*c(icp,:) ; ic = ic + ny ; icp = icp + ny ; c (ic,:) = jacobian(:,is)\jacobian(:,isf1) ; end if options_.terminal_condition == 1 s = eye(ny) ; s(:,isf) = s(:,isf)+c(ic,1:nyf) ; ic = ic + ny ; c(ic,nrc) = s\c(ic,nrc) ; c = bksup1(c,ny,nrc,iyf,options_.periods) ; c = reshape(c,ny,options_.periods+1) ; oo_.endo_simul(:,it_init+(0:options_.periods)) = oo_.endo_simul(:,it_init+(0:options_.periods))+options_.slowc*c ; else c = bksup1(c,ny,nrc,iyf,options_.periods) ; c = reshape(c,ny,options_.periods) ; oo_.endo_simul(:,it_init+(0:options_.periods-1)) = oo_.endo_simul(:,it_init+(0:options_.periods-1))+options_.slowc*c ; end err = max(max(abs(c./options_.scalv'))); if verbose str = sprintf('Iter: %s,\t err. = %s, \t time = %s',num2str(iter),num2str(err), num2str(etime(clock,h2))); disp(str); end if err < options_.dynatol.f stop = 1 ; if verbose skipline() disp(sprintf('Total time of simulation: %s', num2str(etime(clock,h1)))) end oo_.deterministic_simulation.status = 1;% Convergency obtained. oo_.deterministic_simulation.error = err; oo_.deterministic_simulation.iterations = iter; break end end if ~stop if verbose disp(sprintf('Total time of simulation: %s.', num2str(etime(clock,h1)))) disp('Maximum number of iterations is reached (modify option maxit).') end oo_.deterministic_simulation.status = 0;% more iterations are needed. oo_.deterministic_simulation.error = err; oo_.deterministic_simulation.errors = c/abs(err); oo_.deterministic_simulation.iterations = options_.simul.maxit; end if verbose if stop printline(56) else printline(62) end skipline() end