Replace initval blocks by steady_state_model blocks in fs2000 unit tests

Speeds up estimation
2015-06-07 12:18:24 +02:00 · 2015-06-07 12:18:24 +02:00 · 0104f91f4b
parent e07607011c
commit 0104f91f4b
61 changed files with 1215 additions and 1385 deletions
--- a/tests/AIM/fs2000_b1L1L.mod
+++ b/tests/AIM/fs2000_b1L1L.mod
@ -52,21 +52,34 @@ P2 = P(+1);
 c2 = c(+1);
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam); 
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
+  Y_obs = 1;
+  P_obs = 1;
+  P2 = P;
+  c2 = c;
 end;

 shocks;
--- a/tests/AIM/fs2000_b1L1L_AIM.mod
+++ b/tests/AIM/fs2000_b1L1L_AIM.mod
@ -52,23 +52,37 @@ P2 = P(+1);
 c2 = c(+1);
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam); 
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
+  Y_obs = 1;
+  P_obs = 1;
+  P2 = P;
+  c2 = c;
 end;

+
 shocks;
 var e_a; stderr 0.014;
 var e_m; stderr 0.005;
--- a/tests/AIM/fs2000_b1L1L_AIM_steadystate.m
+++ b/tests/AIM/fs2000_b1L1L_AIM_steadystate.m
@ -1,65 +0,0 @@
-% computes the steady state of fs2000 analyticaly
-% largely inspired by the program of F. Schorfheide
-function [ys,check] = fs2000k_steadystate(ys,exe)
-  global M_
-  
-  alp = M_.params(1); 
-  bet = M_.params(2); 
-  gam = M_.params(3); 
-  mst = M_.params(4); 
-  rho = M_.params(5); 
-  psi = M_.params(6); 
-  del = M_.params(7); 
-
-  check = 0;
-  
-  dA = exp(gam);
-  gst = 1/dA;
-  m = mst;
-  
-  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
-  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
-  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
-  n  = xist/(nust+xist);
-  P  = xist + nust;
-  k  = khst*n;
-
-  l  = psi*mst*n/( (1-psi)*(1-n) );
-  c  = mst/P;
-  d  = l - mst + 1;
-  y  = k^alp*n^(1-alp)*gst^alp;
-  R  = mst/bet;
-  W  = l/n;
-  ist  = y-c;
-  q  = 1 - d;
-
-  e = 1;
-  
-  gp_obs = m/dA;
-  gy_obs = dA;
-  
-  P_obs = 1;
-  Y_obs = 1;
-  
-  P2=P;
-  c2=c;
-  
-  ys =[
-    m     
-    P     
-    c     
-    e     
-    W     
-    R     
-    k     
-    d     
-    n     
-    l     
-    gy_obs
-    gp_obs
-    Y_obs 
-    P_obs 
-    y     
-    dA
-    P2
-    c2  ];
--- a/tests/AIM/fs2000_b1L1L_steadystate.m
+++ b/tests/AIM/fs2000_b1L1L_steadystate.m
@ -1,65 +0,0 @@
-% computes the steady state of fs2000 analyticaly
-% largely inspired by the program of F. Schorfheide
-function [ys,check] = fs2000_b1L1L_steadystate(ys,exe)
-  global M_
-  
-  alp = M_.params(1); 
-  bet = M_.params(2); 
-  gam = M_.params(3); 
-  mst = M_.params(4); 
-  rho = M_.params(5); 
-  psi = M_.params(6); 
-  del = M_.params(7); 
-
-  check = 0;
-  
-  dA = exp(gam);
-  gst = 1/dA;
-  m = mst;
-  
-  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
-  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
-  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
-  n  = xist/(nust+xist);
-  P  = xist + nust;
-  k  = khst*n;
-
-  l  = psi*mst*n/( (1-psi)*(1-n) );
-  c  = mst/P;
-  d  = l - mst + 1;
-  y  = k^alp*n^(1-alp)*gst^alp;
-  R  = mst/bet;
-  W  = l/n;
-  ist  = y-c;
-  q  = 1 - d;
-
-  e = 1;
-  
-  gp_obs = m/dA;
-  gy_obs = dA;
-  
-  P_obs = 1;
-  Y_obs = 1;
-  
-  P2=P;
-  c2=c;
-  
-  ys =[
-    m     
-    P     
-    c     
-    e     
-    W     
-    R     
-    k     
-    d     
-    n     
-    l     
-    gy_obs
-    gp_obs
-    Y_obs 
-    P_obs 
-    y     
-    dA
-    P2
-    c2  ];
--- a/tests/Makefile.am
+++ b/tests/Makefile.am
@ -353,8 +353,6 @@ EXTRA_DIST = \
 	printMakeCheckOctaveErrMsg.m \
 	fataltest.m \
 	AIM/data_ca1.m \
-	AIM/fs2000_b1L1L_AIM_steadystate.m \
-	AIM/fs2000_b1L1L_steadystate.m \
 	AIM/fsdat.m \
 	block_bytecode/run_ls2003.m \
 	bvar_a_la_sims/bvar_sample.m \
@ -365,12 +363,10 @@ EXTRA_DIST = \
 	steady_state/walsh1_old_ss_steadystate.m \
 	data/test.xls \
 	analytic_derivatives/fsdat_simul.m \
-	fs2000/fs2000a_steadystate.m \
 	fs2000/fsdat_simul.m \
 	k_order_perturbation/run_fs2000kplusplus.m \
 	ls2003/data_ca1.m \
 	measurement_errors/data_ca1.m \
-	measurement_errors/fs2000_corr_me_ml_mcmc/fs2000_corr_ME_steadystate.m \
 	measurement_errors/fs2000_corr_me_ml_mcmc/fsdat_simul.m \
 	missing/simulate_data_with_missing_observations.m \
 	objectives/sgu_ex1.mat \
@ -393,18 +389,14 @@ EXTRA_DIST = \
 	ms-sbvar/archive-files/specification_2v2c.dat \
 	recursive/data_ca1.m \
 	kalman_filter_smoother/fsdat_simul.m \
-	kalman_filter_smoother/fs2000a_steadystate.m \
 	identification/kim/kim2_steadystate.m \
+	identification/as2007/as2007_steadystate.m \
 	estimation/fsdat_simul.m \
 	ep/mean_preserving_spread.m \
 	third_order/comparison_policy_functions_dynare_mathematica.m \
 	third_order/policyfunctions.mat \
 	shock_decomposition/example1_calib_shock_decomp_data.mat \
 	shock_decomposition/fsdat_simul.m \
-	estimation/fs2000_MCMC_jumping_covariance_steadystate.m \
-	estimation/fs2000_initialize_from_calib_steadystate.m \
-	filter_step_ahead/fs2000_filter_step_ahead_bayesian_steadystate.m \
-	filter_step_ahead/fs2000_filter_step_ahead_ML_steadystate.m \
 	loglinear/results_exp.mat \
 	smoother2histval/fsdat_simul.m \
 	optimal_policy/Ramsey/find_c.m \
--- a/tests/analytic_derivatives/fs2000_analytic_derivation.mod
+++ b/tests/analytic_derivatives/fs2000_analytic_derivation.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/conditional_forecasts/fs2000_cal.mod
+++ b/tests/conditional_forecasts/fs2000_cal.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/conditional_forecasts/fs2000_est.mod
+++ b/tests/conditional_forecasts/fs2000_est.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/dates/fs2000.mod
+++ b/tests/dates/fs2000.mod
@ -32,21 +32,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/estimation/fs2000.mod
+++ b/tests/estimation/fs2000.mod
@ -30,23 +30,33 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

+
 shocks;
 var e_a; stderr 0.014;
 var e_m; stderr 0.005;
@ -72,4 +82,4 @@ varobs gp_obs gy_obs;

 options_.solve_tolf = 1e-12;

-estimation(order=1,datafile=fsdat_simul,nobs=192,loglinear,mh_replic=2000,mh_nblocks=2,mh_jscale=0.8);
+estimation(order=1,datafile=fsdat_simul,nobs=192,loglinear,mh_replic=3000,mh_nblocks=2,mh_jscale=0.8,moments_varendo,selected_variables_only) y m;
--- a/tests/estimation/fs2000_MCMC_jumping_covariance.mod
+++ b/tests/estimation/fs2000_MCMC_jumping_covariance.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/estimation/fs2000_MCMC_jumping_covariance_steadystate.m
+++ b/tests/estimation/fs2000_MCMC_jumping_covariance_steadystate.m
@ -1,73 +0,0 @@
-% computes the steady state of fs2000 analyticaly
-% largely inspired by the program of F. Schorfheide
-
-% Copyright (C) 2004-2010 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 <http://www.gnu.org/licenses/>.
-
-function [ys,check] = fs2000_MCMC_jumping_covariance_steadystate(ys,exe)
-  global M_
-  
-  alp = M_.params(1); 
-  bet = M_.params(2); 
-  gam = M_.params(3); 
-  mst = M_.params(4); 
-  rho = M_.params(5); 
-  psi = M_.params(6); 
-  del = M_.params(7); 
-
-  check = 0;
-  
-  dA = exp(gam);
-  gst = 1/dA;
-  m = mst;
-  
-  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
-  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
-  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
-  n  = xist/(nust+xist);
-  P  = xist + nust;
-  k  = khst*n;
-
-  l  = psi*mst*n/( (1-psi)*(1-n) );
-  c  = mst/P;
-  d  = l - mst + 1;
-  y  = k^alp*n^(1-alp)*gst^alp;
-  R  = mst/bet;
-  W  = l/n;
-  ist  = y-c;
-  q  = 1 - d;
-
-  e = 1;
-  
-  gp_obs = m/dA;
-  gy_obs = dA;
-  
-  ys =[
-m     
-P     
-c     
-e     
-W     
-R     
-k     
-d     
-n     
-l     
-gy_obs
-gp_obs
-y     
-dA          ];
--- a/tests/estimation/fs2000_calibrated_covariance.mod
+++ b/tests/estimation/fs2000_calibrated_covariance.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 varobs gp_obs gy_obs;
--- a/tests/estimation/fs2000_initialize_from_calib.mod
+++ b/tests/estimation/fs2000_initialize_from_calib.mod
@ -29,23 +29,33 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

+
 shocks;
 var e_a; stderr 0.014;
 var e_m; stderr 0.005;
--- a/tests/estimation/fs2000_initialize_from_calib_steadystate.m
+++ b/tests/estimation/fs2000_initialize_from_calib_steadystate.m
@ -1,73 +0,0 @@
-% computes the steady state of fs2000 analyticaly
-% largely inspired by the program of F. Schorfheide
-
-% Copyright (C) 2004-2010 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 <http://www.gnu.org/licenses/>.
-
-function [ys,check] = fs2000_steadystate(ys,exe)
-  global M_
-  
-  alp = M_.params(1); 
-  bet = M_.params(2); 
-  gam = M_.params(3); 
-  mst = M_.params(4); 
-  rho = M_.params(5); 
-  psi = M_.params(6); 
-  del = M_.params(7); 
-
-  check = 0;
-  
-  dA = exp(gam);
-  gst = 1/dA;
-  m = mst;
-  
-  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
-  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
-  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
-  n  = xist/(nust+xist);
-  P  = xist + nust;
-  k  = khst*n;
-
-  l  = psi*mst*n/( (1-psi)*(1-n) );
-  c  = mst/P;
-  d  = l - mst + 1;
-  y  = k^alp*n^(1-alp)*gst^alp;
-  R  = mst/bet;
-  W  = l/n;
-  ist  = y-c;
-  q  = 1 - d;
-
-  e = 1;
-  
-  gp_obs = m/dA;
-  gy_obs = dA;
-  
-  ys =[
-m     
-P     
-c     
-e     
-W     
-R     
-k     
-d     
-n     
-l     
-gy_obs
-gp_obs
-y     
-dA          ];
--- a/tests/estimation/fs2000_mf.mod
+++ b/tests/estimation/fs2000_mf.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/filter_step_ahead/fs2000_filter_step_ahead_ML.mod
+++ b/tests/filter_step_ahead/fs2000_filter_step_ahead_ML.mod
@ -65,21 +65,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/filter_step_ahead/fs2000_filter_step_ahead_ML_steadystate.m
+++ b/tests/filter_step_ahead/fs2000_filter_step_ahead_ML_steadystate.m
@ -1,73 +0,0 @@
-% computes the steady state of fs2000 analyticaly
-% largely inspired by the program of F. Schorfheide
-
-% Copyright (C) 2004-2010 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 <http://www.gnu.org/licenses/>.
-
-function [ys,check] = fs2000_steadystate(ys,exe)
-  global M_
-  
-  alp = M_.params(1); 
-  bet = M_.params(2); 
-  gam = M_.params(3); 
-  mst = M_.params(4); 
-  rho = M_.params(5); 
-  psi = M_.params(6); 
-  del = M_.params(7); 
-
-  check = 0;
-  
-  dA = exp(gam);
-  gst = 1/dA;
-  m = mst;
-  
-  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
-  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
-  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
-  n  = xist/(nust+xist);
-  P  = xist + nust;
-  k  = khst*n;
-
-  l  = psi*mst*n/( (1-psi)*(1-n) );
-  c  = mst/P;
-  d  = l - mst + 1;
-  y  = k^alp*n^(1-alp)*gst^alp;
-  R  = mst/bet;
-  W  = l/n;
-  ist  = y-c;
-  q  = 1 - d;
-
-  e = 1;
-  
-  gp_obs = m/dA;
-  gy_obs = dA;
-  
-  ys =[
-m     
-P     
-c     
-e     
-W     
-R     
-k     
-d     
-n     
-l     
-gy_obs
-gp_obs
-y     
-dA          ];
--- a/tests/filter_step_ahead/fs2000_filter_step_ahead_bayesian.mod
+++ b/tests/filter_step_ahead/fs2000_filter_step_ahead_bayesian.mod
@ -65,21 +65,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/filter_step_ahead/fs2000_filter_step_ahead_bayesian_steadystate.m
+++ b/tests/filter_step_ahead/fs2000_filter_step_ahead_bayesian_steadystate.m
@ -1,73 +0,0 @@
-% computes the steady state of fs2000 analyticaly
-% largely inspired by the program of F. Schorfheide
-
-% Copyright (C) 2004-2010 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 <http://www.gnu.org/licenses/>.
-
-function [ys,check] = fs2000_steadystate(ys,exe)
-  global M_
-  
-  alp = M_.params(1); 
-  bet = M_.params(2); 
-  gam = M_.params(3); 
-  mst = M_.params(4); 
-  rho = M_.params(5); 
-  psi = M_.params(6); 
-  del = M_.params(7); 
-
-  check = 0;
-  
-  dA = exp(gam);
-  gst = 1/dA;
-  m = mst;
-  
-  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
-  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
-  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
-  n  = xist/(nust+xist);
-  P  = xist + nust;
-  k  = khst*n;
-
-  l  = psi*mst*n/( (1-psi)*(1-n) );
-  c  = mst/P;
-  d  = l - mst + 1;
-  y  = k^alp*n^(1-alp)*gst^alp;
-  R  = mst/bet;
-  W  = l/n;
-  ist  = y-c;
-  q  = 1 - d;
-
-  e = 1;
-  
-  gp_obs = m/dA;
-  gy_obs = dA;
-  
-  ys =[
-m     
-P     
-c     
-e     
-W     
-R     
-k     
-d     
-n     
-l     
-gy_obs
-gp_obs
-y     
-dA          ];
--- a/tests/fs2000/fs2000_analytic_derivation.mod
+++ b/tests/fs2000/fs2000_analytic_derivation.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/fs2000/fs2000_calib.mod
+++ b/tests/fs2000/fs2000_calib.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/fs2000/fs2000_calib_dseries.mod
+++ b/tests/fs2000/fs2000_calib_dseries.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/fs2000/fs2000_data.mod
+++ b/tests/fs2000/fs2000_data.mod
@ -30,23 +30,33 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

+
 shocks;
 var e_a; stderr 0.014;
 var e_m; stderr 0.005;
--- a/tests/fs2000/fs2000_dseries_a.mod
+++ b/tests/fs2000/fs2000_dseries_a.mod
@ -30,23 +30,33 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

+
 shocks;
 var e_a; stderr 0.014;
 var e_m; stderr 0.005;
--- a/tests/fs2000/fs2000_dseries_b.mod
+++ b/tests/fs2000/fs2000_dseries_b.mod
@ -30,23 +30,33 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

+
 shocks;
 var e_a; stderr 0.014;
 var e_m; stderr 0.005;
--- a/tests/fs2000/fs2000_missing_data.mod
+++ b/tests/fs2000/fs2000_missing_data.mod
@ -30,23 +30,33 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

+
 shocks;
 var e_a; stderr 0.014;
 var e_m; stderr 0.005;
--- a/tests/fs2000/fs2000_particle.mod
+++ b/tests/fs2000/fs2000_particle.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/fs2000/fs2000_sd.mod
+++ b/tests/fs2000/fs2000_sd.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/fs2000/fs2000a.mod
+++ b/tests/fs2000/fs2000a.mod
@ -33,21 +33,32 @@ Y_obs/Y_obs(-1) = gy_obs;
 P_obs/P_obs(-1) = gp_obs;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gy_obs = exp(gam);
+  gp_obs = exp(-gam);
+  Y_obs=gy_obs;
+  P_obs=gp_obs;
 end;

 shocks;
--- a/tests/fs2000/fs2000a_steadystate.m
+++ b/tests/fs2000/fs2000a_steadystate.m
@ -1,60 +0,0 @@
-% computes the steady state of fs2000 analyticaly
-% largely inspired by the program of F. Schorfheide
-function [ys,check] = fs2000a_steadystate(ys,exe)
-  global M_
-  
-  alp = M_.params(1); 
-  bet = M_.params(2); 
-  gam = M_.params(3); 
-  mst = M_.params(4); 
-  rho = M_.params(5); 
-  psi = M_.params(6); 
-  del = M_.params(7); 
-
-  check = 0;
-  
-  dA = exp(gam);
-  gst = 1/dA;
-  m = mst;
-  
-  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
-  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
-  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
-  n  = xist/(nust+xist);
-  P  = xist + nust;
-  k  = khst*n;
-
-  l  = psi*mst*n/( (1-psi)*(1-n) );
-  c  = mst/P;
-  d  = l - mst + 1;
-  y  = k^alp*n^(1-alp)*gst^alp;
-  R  = mst/bet;
-  W  = l/n;
-  ist  = y-c;
-  q  = 1 - d;
-
-  e = 1;
-  
-  gp_obs = m/dA;
-  gy_obs = dA;
-  
-  P_obs = 1;
-  Y_obs = 1;
-  
-  ys =[
-m     
-P     
-c     
-e     
-W     
-R     
-k     
-d     
-n     
-l     
-gy_obs
-gp_obs
-Y_obs 
-P_obs 
-y     
-dA          ];
--- a/tests/fs2000/fs2000c.mod
+++ b/tests/fs2000/fs2000c.mod
@ -35,18 +35,27 @@ M-M(-1)+d = l;
 y = k(-1)^alp*(A*n)^(1-alp);
 end;

-initval;
-k = 6;
-gM = mst;
-P = 2.25;
-c = 0.45;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gA = exp(gam);
+steady_state_model;
+  gA = exp(gam);
+  gst = 1/gA;
+  gM = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
 end;

 shocks;
--- a/tests/fs2000_nonstationary.mod
+++ b/tests/fs2000_nonstationary.mod
@ -59,18 +59,27 @@ M-M(-1)+d = l;
 y = k(-1)^alp*(A*n)^(1-alp);
 end;

-initval;
-k = 6;
-gM = mst;
-P = 2.25;
-c = 0.45;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gA = exp(gam);
+steady_state_model;
+  gA = exp(gam);
+  gst = 1/gA;
+  gM = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
 end;

 shocks;
--- a/tests/gradient/fs2000_numgrad_13.mod
+++ b/tests/gradient/fs2000_numgrad_13.mod
@ -28,21 +28,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/gradient/fs2000_numgrad_15.mod
+++ b/tests/gradient/fs2000_numgrad_15.mod
@ -28,21 +28,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/gradient/fs2000_numgrad_2.mod
+++ b/tests/gradient/fs2000_numgrad_2.mod
@ -28,21 +28,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/gradient/fs2000_numgrad_3.mod
+++ b/tests/gradient/fs2000_numgrad_3.mod
@ -28,21 +28,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/gradient/fs2000_numgrad_5.mod
+++ b/tests/gradient/fs2000_numgrad_5.mod
@ -28,21 +28,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/identification/as2007/as2007_steadystate.m
+++ b/tests/identification/as2007/as2007_steadystate.m
@ -1,6 +1,6 @@
-function [ys,check1]=as2007_steadystate(junk, ys)
+function [ys,check1]=as2007_steadystate(ys,exo)

-global M_ options_
+global M_

 for j=1:size(M_.param_names,1)
  eval([deblank(M_.param_names(j,:)),' = M_.params(j);'])
@ -21,12 +21,14 @@ YGR=gam_steady;
 INFL = pi_steady;
 INT = pi_steady+rr_steady+4*gam_steady;

-ys=[
-pie 
-y 
-R 
-g 
-z 
-YGR 
-INFL
-INT];
+%% end own model equations
+
+for iter = 1:length(M_.params) %update parameters set in the file
+  eval([ 'M_.params(' num2str(iter) ') = ' M_.param_names(iter,:) ';' ])
+end
+
+NumberOfEndogenousVariables = M_.orig_endo_nbr; %auxiliary variables are set automatically
+for ii = 1:NumberOfEndogenousVariables
+  varname = deblank(M_.endo_names(ii,:));
+  eval(['ys(' int2str(ii) ') = ' varname ';']);
+end
--- a/tests/identification/kim/kim2_steadystate.m
+++ b/tests/identification/kim/kim2_steadystate.m
@ -1,6 +1,6 @@
-function [ys,check1]=kim2_steadystate(junk, ys)
+function [ys,check1]=kim2_steadystate(ys,exo)

-global M_ options_
+global M_ 

 for j=1:size(M_.param_names,1)
  eval([deblank(M_.param_names(j,:)),' = M_.params(j);'])
@ -19,10 +19,14 @@ i=delta*k;
 c=(((a*k^alph)^(1+theta)-s*(i/s)^(1+theta))/(1-s))^(1/(1+theta))*(1-s);
 lam = (1-s)^theta/c^(1+theta)/(1+theta);

-ys=[
-  c
-  k
-  i
-  a
-  lam
-  ];
+%% end own model equations
+
+for iter = 1:length(M_.params) %update parameters set in the file
+  eval([ 'M_.params(' num2str(iter) ') = ' M_.param_names(iter,:) ';' ])
+end
+
+NumberOfEndogenousVariables = M_.orig_endo_nbr; %auxiliary variables are set automatically
+for ii = 1:NumberOfEndogenousVariables
+  varname = deblank(M_.endo_names(ii,:));
+  eval(['ys(' int2str(ii) ') = ' varname ';']);
+end
--- a/tests/k_order_perturbation/fs2000k2_m.mod
+++ b/tests/k_order_perturbation/fs2000k2_m.mod
@ -31,21 +31,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-k = 6;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam); 
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/k_order_perturbation/fs2000k2_use_dll.mod
+++ b/tests/k_order_perturbation/fs2000k2_use_dll.mod
@ -31,21 +31,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-k = 6;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam); 
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/k_order_perturbation/fs2000k2a.mod
+++ b/tests/k_order_perturbation/fs2000k2a.mod
@ -31,21 +31,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-k = 6;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam); 
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/k_order_perturbation/fs2000k3_m.mod
+++ b/tests/k_order_perturbation/fs2000k3_m.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-k = 6;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam); 
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/k_order_perturbation/fs2000k3_p.mod
+++ b/tests/k_order_perturbation/fs2000k3_p.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-k = 6;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam); 
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/k_order_perturbation/fs2000k3_use_dll.mod
+++ b/tests/k_order_perturbation/fs2000k3_use_dll.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-k = 6;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam); 
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/k_order_perturbation/fs2000k_1_m.mod
+++ b/tests/k_order_perturbation/fs2000k_1_m.mod
@ -34,26 +34,36 @@ P_1 = P;
 AUXv = bet*P*(alp*exp(-alp*(gam+log(e)))*k(-1)^(alp-1)*n^(1-alp)+(1-del)*exp(-(gam+log(e))))/(c(+1)*P(+1)*m);
 end;

-initval;
-m = mst;
-m_1=mst;
-P = 2.25;
-P_1 = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-k = 6;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam); 
-dA = exp(gam);
-AUXv = 1;
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  m_1=mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  P_1 = P;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
+  AUXv = 1/(c*m);
 end;

+
 shocks;
 var e_a; stderr 0.014;
 var e_m; stderr 0.005;
--- a/tests/k_order_perturbation/fs2000k_1_use_dll.mod
+++ b/tests/k_order_perturbation/fs2000k_1_use_dll.mod
@ -34,24 +34,33 @@ P_1 = P;
 AUXv = bet*P*(alp*exp(-alp*(gam+log(e)))*k(-1)^(alp-1)*n^(1-alp)+(1-del)*exp(-(gam+log(e))))/(c(+1)*P(+1)*m);
 end;

-initval;
-m = mst;
-m_1=mst;
-P = 2.25;
-P_1 = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-k = 6;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam); 
-dA = exp(gam);
-AUXv = 1;
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  m_1=mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  P_1 = P;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
+  AUXv = 1/(c*m);
 end;

 shocks;
--- a/tests/kalman_filter_smoother/fs2000.mod
+++ b/tests/kalman_filter_smoother/fs2000.mod
@ -30,21 +30,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/kalman_filter_smoother/fs2000_1.mod
+++ b/tests/kalman_filter_smoother/fs2000_1.mod
@ -31,21 +31,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/kalman_filter_smoother/fs2000_2.mod
+++ b/tests/kalman_filter_smoother/fs2000_2.mod
@ -31,21 +31,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/kalman_filter_smoother/fs2000_smoother_only.mod
+++ b/tests/kalman_filter_smoother/fs2000_smoother_only.mod
@ -65,21 +65,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/kalman_filter_smoother/fs2000a.mod
+++ b/tests/kalman_filter_smoother/fs2000a.mod
@ -33,21 +33,32 @@ Y_obs/Y_obs(-1) = gy_obs;
 P_obs/P_obs(-1) = gp_obs;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
+  Y_obs = gy_obs;
+  P_obs = gp_obs;
 end;

 shocks;
--- a/tests/kalman_filter_smoother/fs2000a_steadystate.m
+++ b/tests/kalman_filter_smoother/fs2000a_steadystate.m
@ -1,60 +0,0 @@
-% computes the steady state of fs2000 analyticaly
-% largely inspired by the program of F. Schorfheide
-function [ys,check] = fs2000a_steadystate(ys,exe)
-  global M_
-  
-  alp = M_.params(1); 
-  bet = M_.params(2); 
-  gam = M_.params(3); 
-  mst = M_.params(4); 
-  rho = M_.params(5); 
-  psi = M_.params(6); 
-  del = M_.params(7); 
-
-  check = 0;
-  
-  dA = exp(gam);
-  gst = 1/dA;
-  m = mst;
-  
-  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
-  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
-  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
-  n  = xist/(nust+xist);
-  P  = xist + nust;
-  k  = khst*n;
-
-  l  = psi*mst*n/( (1-psi)*(1-n) );
-  c  = mst/P;
-  d  = l - mst + 1;
-  y  = k^alp*n^(1-alp)*gst^alp;
-  R  = mst/bet;
-  W  = l/n;
-  ist  = y-c;
-  q  = 1 - d;
-
-  e = 1;
-  
-  gp_obs = m/dA;
-  gy_obs = dA;
-  
-  P_obs = 1;
-  Y_obs = 1;
-  
-  ys =[
-m     
-P     
-c     
-e     
-W     
-R     
-k     
-d     
-n     
-l     
-gy_obs
-gp_obs
-Y_obs 
-P_obs 
-y     
-dA          ];
--- a/tests/measurement_errors/fs2000_corr_me_ml_mcmc/fs2000_corr_ME.mod
+++ b/tests/measurement_errors/fs2000_corr_me_ml_mcmc/fs2000_corr_ME.mod
@ -63,21 +63,30 @@ gy_obs = dA*y/y(-1);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 varobs gp_obs gy_obs;
--- a/tests/measurement_errors/fs2000_corr_me_ml_mcmc/fs2000_corr_ME_steadystate.m
+++ b/tests/measurement_errors/fs2000_corr_me_ml_mcmc/fs2000_corr_ME_steadystate.m
@ -1,73 +0,0 @@
-% computes the steady state of fs2000 analyticaly
-% largely inspired by the program of F. Schorfheide
-
-% Copyright (C) 2004-2013 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 <http://www.gnu.org/licenses/>.
-
-function [ys,check] = fs2000_corr_ME_steadystate(ys,exe)
-  global M_
-  
-  alp = M_.params(1); 
-  bet = M_.params(2); 
-  gam = M_.params(3); 
-  mst = M_.params(4); 
-  rho = M_.params(5); 
-  psi = M_.params(6); 
-  del = M_.params(7); 
-
-  check = 0;
-  
-  dA = exp(gam);
-  gst = 1/dA;
-  m = mst;
-  
-  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
-  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
-  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
-  n  = xist/(nust+xist);
-  P  = xist + nust;
-  k  = khst*n;
-
-  l  = psi*mst*n/( (1-psi)*(1-n) );
-  c  = mst/P;
-  d  = l - mst + 1;
-  y  = k^alp*n^(1-alp)*gst^alp;
-  R  = mst/bet;
-  W  = l/n;
-  ist  = y-c;
-  q  = 1 - d;
-
-  e = 1;
-  
-  gp_obs = m/dA;
-  gy_obs = dA;
-  
-  ys =[
-m     
-P     
-c     
-e     
-W     
-R     
-k     
-d     
-n     
-l     
-gy_obs
-gp_obs
-y     
-dA          ];
--- a/tests/smoother2histval/fs2000_simul.mod
+++ b/tests/smoother2histval/fs2000_simul.mod
@ -31,21 +31,30 @@ gy_obs = dA*y/y(-2);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/smoother2histval/fs2000_smooth.mod
+++ b/tests/smoother2histval/fs2000_smooth.mod
@ -31,21 +31,30 @@ gy_obs = dA*y/y(-2);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/smoother2histval/fs2000_smooth_stoch_simul.mod
+++ b/tests/smoother2histval/fs2000_smooth_stoch_simul.mod
@ -31,21 +31,30 @@ gy_obs = dA*y/y(-2);
 gp_obs = (P/P(-1))*m(-1)/dA;
 end;

-initval;
-k = 6;
-m = mst;
-P = 2.25;
-c = 0.45;
-e = 1;
-W = 4;
-R = 1.02;
-d = 0.85;
-n = 0.19;
-l = 0.86;
-y = 0.6;
-gy_obs = exp(gam);
-gp_obs = exp(-gam);
-dA = exp(gam);
+steady_state_model;
+  dA = exp(gam);
+  gst = 1/dA;
+  m = mst;
+  khst = ( (1-gst*bet*(1-del)) / (alp*gst^alp*bet) )^(1/(alp-1));
+  xist = ( ((khst*gst)^alp - (1-gst*(1-del))*khst)/mst )^(-1);
+  nust = psi*mst^2/( (1-alp)*(1-psi)*bet*gst^alp*khst^alp );
+  n  = xist/(nust+xist);
+  P  = xist + nust;
+  k  = khst*n;
+
+  l  = psi*mst*n/( (1-psi)*(1-n) );
+  c  = mst/P;
+  d  = l - mst + 1;
+  y  = k^alp*n^(1-alp)*gst^alp;
+  R  = mst/bet;
+  W  = l/n;
+  ist  = y-c;
+  q  = 1 - d;
+
+  e = 1;
+  
+  gp_obs = m/dA;
+  gy_obs = dA;
 end;

 shocks;
--- a/tests/steady_state/walsh1_old_ss.mod
+++ b/tests/steady_state/walsh1_old_ss.mod
@ -2,12 +2,12 @@ var y c k m n R pi z u;
 varexo	e sigma;	 
 // sigma stands for phi in the eq 2.37 p.69

-parameters alpha beta delta gamm phi1 eta a b rho  phi2 Psi thetass;  
+parameters alphha betta delta gamm phi1 eta a b rho  phi2 Psi thetass;  
 //phi1 stands for capital phi in eq.2.68 and 2.69
 //phi2 stands for lowercase phi in eq. 2.66

-alpha = 0.36;
-beta = 0.989; 
+alphha = 0.36;
+betta = 0.989; 
 gamm = 0.5;
 delta = 0.019;
 phi1 = 2;
@ -21,17 +21,17 @@ thetass = 1.0125;

 model;

-(a*exp(c)^(1-b)+(1-a)*exp(m)^(1-b))^((b-phi1)/(1-b))*a*exp(c)^(-b) = (a*exp(c)^(1-b)+(1-a)*exp(m)^(1-b))^((b-phi1)/(1-b))*(1-a)*exp(m)^(-b)+beta*(a*exp(c(+1))^(1-b)+(1-a)*exp(m(+1))^(1-b))^((b-phi1)/(1-b))*a*exp(c(+1))^(-b)/(1+pi(+1));
+(a*exp(c)^(1-b)+(1-a)*exp(m)^(1-b))^((b-phi1)/(1-b))*a*exp(c)^(-b) = (a*exp(c)^(1-b)+(1-a)*exp(m)^(1-b))^((b-phi1)/(1-b))*(1-a)*exp(m)^(-b)+betta*(a*exp(c(+1))^(1-b)+(1-a)*exp(m(+1))^(1-b))^((b-phi1)/(1-b))*a*exp(c(+1))^(-b)/(1+pi(+1));

-Psi*(1-exp(n))^(-eta)/(a*exp(c)^(-b)*(a*exp(c)^(1-b) + (1-a)*exp(m)^(1-b))^((b-phi1)/(1-b))) = (1-alpha)*exp(y)/exp(n);
+Psi*(1-exp(n))^(-eta)/(a*exp(c)^(-b)*(a*exp(c)^(1-b) + (1-a)*exp(m)^(1-b))^((b-phi1)/(1-b))) = (1-alphha)*exp(y)/exp(n);

-(a*exp(c)^(1-b)+(1-a)*exp(m)^(1-b))^((b-phi1)/(1-b))*a*exp(c)^(-b) = beta*exp(R(+1))*(a*exp(c(+1))^(1-b)+(1-a)*exp(m(+1))^(1-b))^((b-phi1)/(1-b))*a*exp(c(+1))^(-b);
+(a*exp(c)^(1-b)+(1-a)*exp(m)^(1-b))^((b-phi1)/(1-b))*a*exp(c)^(-b) = betta*exp(R(+1))*(a*exp(c(+1))^(1-b)+(1-a)*exp(m(+1))^(1-b))^((b-phi1)/(1-b))*a*exp(c(+1))^(-b);

-exp(R) = alpha*exp(y)/exp(k(-1)) + 1-delta;
+exp(R) = alphha*exp(y)/exp(k(-1)) + 1-delta;

 exp(k) = (1-delta)*exp(k(-1))+exp(y)-exp(c);

-exp(y) = exp(z)*exp(k(-1))^alpha*exp(n)^(1-alpha);
+exp(y) = exp(z)*exp(k(-1))^alphha*exp(n)^(1-alphha);

 exp(m) = exp(m(-1))*(u+thetass)/(1+pi);

--- a/tests/steady_state/walsh1_old_ss_steadystate.m
+++ b/tests/steady_state/walsh1_old_ss_steadystate.m
@ -1,32 +1,28 @@
-function [ys,check] = walsh1_old_ss_steadystate(ys0,exo)
-    global M_
-    
-    check = 0;
-    
-    params = M_.params;
-    alpha = params(1);
-    beta = params(2);
-    delta = params(3);
-    gamm = params(4);
-    phi1 = params(5);
-    eta = params(6);
-    a = params(7);
-    b = params(8);
-    rho = params(9);
-    phi2 = params(10);
-    Psi = params(11);
-    thetass = params(12);
+function [ys,check] = walsh1_old_ss_steadystate(ys,exo)
+global M_ 
+
+% read out parameters to access them with their name
+NumberOfParameters = M_.param_nbr;
+for ii = 1:NumberOfParameters
+  paramname = deblank(M_.param_names(ii,:));
+  eval([ paramname ' = M_.params(' int2str(ii) ');']);
+end
+% initialize indicator
+check = 0;
+
+
+%% Enter model equations here
 
    pi = thetass-1;
    en = 1/3;
-    eR = 1/beta;
-    y_k = (1/alpha)*(1/beta-1+delta);
-    ek = en*y_k^(-1/(1-alpha));
+    eR = 1/betta;
+    y_k = (1/alphha)*(1/betta-1+delta);
+    ek = en*y_k^(-1/(1-alphha));
    ec = ek*(y_k-delta);
-    em = ec*(a/(1-a))^(-1/b)*((thetass-beta)/thetass)^(-1/b);
+    em = ec*(a/(1-a))^(-1/b)*((thetass-betta)/thetass)^(-1/b);
    ey = ek*y_k;
-    Xss = a*ec^(1-b)*(1+(a/(1-a))^(-1/b)*((thetass-beta)/thetass)^((b-1)/b));
-    Psi = (1-alpha)*(ey/en)*Xss^((b-phi1)/(1-b))*a*ec^(-b)*(1-en)^eta;
+    Xss = a*ec^(1-b)*(1+(a/(1-a))^(-1/b)*((thetass-betta)/thetass)^((b-1)/b));
+    Psi = (1-alphha)*(ey/en)*Xss^((b-phi1)/(1-b))*a*ec^(-b)*(1-en)^eta;
    n = log(en);
    k = log(ek);
    m = log(em);
@ -36,6 +32,14 @@ function [ys,check] = walsh1_old_ss_steadystate(ys0,exo)
    z = 0;
    u = 0;
    
-    ys = [y c k m n R pi z u]';
-    M_.params(11) = Psi;
-    
+%% end own model equations
+
+for iter = 1:length(M_.params) %update parameters set in the file
+  eval([ 'M_.params(' num2str(iter) ') = ' M_.param_names(iter,:) ';' ])
+end
+
+NumberOfEndogenousVariables = M_.orig_endo_nbr; %auxiliary variables are set automatically
+for ii = 1:NumberOfEndogenousVariables
+  varname = deblank(M_.endo_names(ii,:));
+  eval(['ys(' int2str(ii) ') = ' varname ';']);
+end