171 lines
5.1 KiB
Modula-2
171 lines
5.1 KiB
Modula-2
// --+ options: json=compute, stochastic +--
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var x1 x2 x1bar x2bar z y x u;
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varexo ex1 ex2 ex1bar ex2bar ez ey ex eu;
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parameters
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rho_1 rho_2 rho_3 rho_4
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a_x1_0 a_x1_1 a_x1_2 a_x1_x2_1 a_x1_x2_2
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a_x2_0 a_x2_1 a_x2_2 a_x2_x1_1 a_x2_x1_2
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e_c_m c_z_1 c_z_2 c_z_dx2 c_z_u beta
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lambda;
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rho_1 = .9;
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rho_2 = -.2;
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rho_3 = .4;
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rho_4 = -.3;
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a_x1_0 = -.9;
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a_x1_1 = .4;
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a_x1_2 = .3;
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a_x1_x2_1 = .1;
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a_x1_x2_2 = .2;
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a_x2_0 = -.9;
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a_x2_1 = .2;
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a_x2_2 = -.1;
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a_x2_x1_1 = -.1;
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a_x2_x1_2 = .2;
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beta = .2;
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e_c_m = .5;
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c_z_1 = .2;
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c_z_2 = -.1;
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c_z_dx2 = .3;
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c_z_u = .3;
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lambda = 0.5; // Share of optimizing agents.
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trend_component_model(model_name=toto, eqtags=['eq:x1', 'eq:x2', 'eq:x1bar', 'eq:x2bar'], targets=['eq:x1bar', 'eq:x2bar']);
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pac_model(auxiliary_model_name=toto, discount=beta, model_name=pacman);
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model;
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[name='eq:u']
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u = .5*u(-1) - .2*u(-2) + eu;
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[name='eq:y']
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y = rho_1*y(-1) + rho_2*y(-2) + ey;
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[name='eq:x']
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x = rho_3*x(-1) + rho_4*x(-2) + ex;
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[name='eq:x1']
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diff(x1) = a_x1_0*(x1(-1)-x1bar(-1)) + a_x1_1*diff(x1(-1)) + a_x1_2*diff(x1(-2)) + a_x1_x2_1*diff(x2(-1)) + a_x1_x2_2*diff(x2(-2)) + ex1;
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[name='eq:x2']
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diff(x2) = a_x2_0*(x2(-1)-x2bar(-1)) + a_x2_1*diff(x1(-1)) + a_x2_2*diff(x1(-2)) + a_x2_x1_1*diff(x2(-1)) + a_x2_x1_2*diff(x2(-2)) + ex2;
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[name='eq:x1bar']
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x1bar = x1bar(-1) + ex1bar;
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[name='eq:x2bar']
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x2bar = x2bar(-1) + ex2bar;
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[name='zpac']
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diff(z) = lambda*(e_c_m*(x1(-1)-z(-1)) + c_z_1*diff(z(-1)) + c_z_2*diff(z(-2)) + pac_expectation(pacman)) + (1-lambda)*( y + x) + c_z_dx2*diff(x2) + c_z_u*u + ez;
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end;
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shocks;
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var ex1 = 1.0;
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var ex2 = 1.0;
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var ex1bar = 1.0;
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var ex2bar = 1.0;
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var ez = 1.0;
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var ey = 0.1;
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var ex = 0.1;
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var eu = 0.05;
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end;
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// Initialize the PAC model (build the Companion VAR representation for the auxiliary model).
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pac.initialize('pacman');
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// Update the parameters of the PAC expectation model (h0 and h1 vectors).
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pac.update.expectation('pacman');
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// Set initial conditions to zero. Please use more sensible values if any...
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initialconditions = dseries(zeros(10, M_.endo_nbr+M_.exo_nbr), 2000Q1, vertcat(M_.endo_names,M_.exo_names));
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// Simulate the model for 500 periods
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if isoctave
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// Use a different seed under Octave, the OLS estimation fails with the default one
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options_.bnlms.set_dynare_seed_to_default = false;
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set_dynare_seed(5);
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end
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TrueData = simul_backward_model(initialconditions, 5000);
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// Define a structure describing the parameters to be estimated (with initial conditions).
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clear eparams
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eparams.e_c_m = .9;
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eparams.c_z_1 = .5;
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eparams.c_z_2 = .2;
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eparams.c_z_dx2 = .5;
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eparams.lambda = .7;
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// Define the dataset used for estimation
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edata = TrueData;
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edata.ez = dseries(NaN(TrueData.nobs, 1), 2000Q1, 'ez');
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pac.estimate.iterative_ols('zpac', eparams, edata, 2005Q1:2005Q1+4000);
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e_c_m_iterative_ols = M_.params(strmatch('e_c_m', M_.param_names, 'exact'));
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c_z_1_iterative_ols = M_.params(strmatch('c_z_1', M_.param_names, 'exact'));
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c_z_2_iterative_ols = M_.params(strmatch('c_z_2', M_.param_names, 'exact'));
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c_z_dx2_iterative_ols = M_.params(strmatch('c_z_dx2', M_.param_names, 'exact'));
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lambda_iterative_ols = M_.params(strmatch('lambda', M_.param_names, 'exact'));
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disp(sprintf('Estimate of e_c_m: %f', e_c_m_iterative_ols))
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disp(sprintf('Estimate of c_z_1: %f', c_z_1_iterative_ols))
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disp(sprintf('Estimate of c_z_2: %f', c_z_2_iterative_ols))
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disp(sprintf('Estimate of c_z_dx2: %f', c_z_dx2_iterative_ols))
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disp(sprintf('Estimate of lambda: %f', lambda_iterative_ols))
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skipline(2)
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// Define a structure describing the parameters to be estimated (with initial conditions).
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clear eparams
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eparams.e_c_m = .9;
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eparams.c_z_1 = .5;
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eparams.c_z_2 = .2;
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eparams.c_z_dx2 = .5;
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eparams.lambda = .7;
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edata = TrueData;
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edata.ez = dseries(NaN(TrueData.nobs, 1), 2000Q1, 'ez');
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pac.estimate.nls('zpac', eparams, edata, 2005Q1:2005Q1+4000, 'fmincon');
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e_c_m_nls = M_.params(strmatch('e_c_m', M_.param_names, 'exact'));
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c_z_1_nls = M_.params(strmatch('c_z_1', M_.param_names, 'exact'));
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c_z_2_nls = M_.params(strmatch('c_z_2', M_.param_names, 'exact'));
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c_z_dx2_nls = M_.params(strmatch('c_z_dx2', M_.param_names, 'exact'));
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lambda_nls = M_.params(strmatch('lambda', M_.param_names, 'exact'));
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disp(sprintf('Estimate of e_c_m: %f', e_c_m_nls))
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disp(sprintf('Estimate of c_z_1: %f', c_z_1_nls))
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disp(sprintf('Estimate of c_z_2: %f', c_z_2_nls))
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disp(sprintf('Estimate of c_z_dx2: %f', c_z_dx2_nls))
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disp(sprintf('Estimate of lambda: %f', lambda_nls))
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if abs(e_c_m_nls-e_c_m_iterative_ols)>.01
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error('Iterative OLS and NLS do not provide consistent estimates (e_c_m)')
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end
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if abs(c_z_1_nls-c_z_1_iterative_ols)>.01
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error('Iterative OLS and NLS do not provide consistent estimates (c_z_1)')
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end
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if abs(c_z_2_nls-c_z_2_iterative_ols)>.01
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error('Iterative OLS and NLS do not provide consistent estimates (c_z_2)')
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end
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if abs(c_z_dx2_nls-c_z_dx2_iterative_ols)>.01
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error('Iterative OLS and NLS do not provide consistent estimates (c_z_dx2)')
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end
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if abs(lambda_nls-lambda_iterative_ols)>.01
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error('Iterative OLS and NLS do not provide consistent estimates (lambda)')
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end
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