@#define extended_path_version = 1 var Capital, Output, Labour, Consumption, Investment, Efficiency, efficiency, residual, marginal_utility; varexo EfficiencyInnovation; parameters beta, theta, tau, alpha, psi, delta, rho, effstar, sigma; /* ** Calibration */ beta = 0.990; theta = 0.357; tau = 2.000; alpha = 0.450; psi = -0.200; delta = 0.020; rho = 0.800; effstar = 1.000; sigma = 0.100; model; efficiency = rho*efficiency(-1) + sigma*EfficiencyInnovation; Efficiency = effstar*exp(efficiency); (((Consumption^theta)*((1-Labour)^(1-theta)))^(1-tau))/Consumption - beta*((((Consumption(+1)^theta)*((1-Labour(+1))^(1-theta)))^(1-tau))/Consumption(+1))*(alpha*((Output(+1)/Capital)^(1-psi))+1-delta); residual = (((Consumption^theta)*((1-Labour)^(1-theta)))^(1-tau))/Consumption - beta*((((Consumption(+1)^theta)*((1-Labour(+1))^(1-theta)))^(1-tau))/Consumption(+1))*(alpha*((Output(+1)/Capital)^(1-psi))+1-delta); ((1-theta)/theta)*(Consumption/(1-Labour)) - (1-alpha)*(Output/Labour)^(1-psi); Output = Efficiency*(alpha*(Capital(-1)^psi)+(1-alpha)*(Labour^psi))^(1/psi); Output = Consumption + Investment; Investment = Capital - (1-delta)*Capital(-1); marginal_utility = (((Consumption^theta)*((1-Labour)^(1-theta)))^(1-tau))/Consumption; end; steady_state_model; Efficiency = effstar; y_k = (Efficiency^(-psi)*(1/beta-1+delta)/alpha)^(1/(1-psi)); c_k = y_k - delta; n_k = (((y_k/Efficiency)^psi-alpha)/(1-alpha))^(1/psi); y_n = y_k/n_k; c_n = c_k/n_k; Labour = y_k*(1-alpha)/(((1-theta)/theta)*c_k*(alpha*n_k^(-psi)+1-alpha)+y_k*(1-alpha)); Capital = Labour/n_k; Consumption = c_n*Labour; Output = Efficiency*(alpha*Capital^psi+(1-alpha)*Labour^psi)^(1/psi); Investment = delta*Capital; residual = 0; marginal_utility = (((Consumption^theta)*((1-Labour)^(1-theta)))^(1-tau))/Consumption; end; steady; shocks; var EfficiencyInnovation; periods 1; values -4; end; perfect_foresight_setup(periods=100); perfect_foresight_solver(lmmcp); rplot Investment; rplot residual;