%------------------------------------------------------------------------- % The model: Safe Assets - the case of general IES (THETA not equal 1) % % This file defines the model (see Appendix for the full derivation). % Bonds are perfectly safe short-term assets. % % Variables are denoted by small letters and % parameters by capital letters. Future values are denoted by suffix p. %------------------------------------------------------------------------- clear,clc %% Symbolic variables syms RHO GAMMA1 GAMMA2 NU MU THETA real syms f1 f2 f1p f2p x1 x2 x1p x2p real syms logq logqp tilp tilpp real syms state1 state1p state2 state2p hatyp k1 tilb1 real syms tila1 tila2 invtila1 invtila2 invtilp rbp rep c1 c2 c1p c2p q qp real syms invc1 invc1p invc2 invc2p invf1 invf2 r1p r2p u1p_power u2p_power u1p u2p logf1 logf1p logf2 logf2p real syms term1p term2p invr1p invr2p real %% Parameters symparams = [RHO,GAMMA1,GAMMA2,NU,MU,THETA]; %% State variables state = [state1,state2]; % current period statep = [state1p,state2p]; % future period %% Control variables control = [f1,f2,x1,x2,logq,tilp]; % current period controlp = [f1p,f2p,x1p,x2p,logqp,tilpp]; % future period %% shocks shocks = hatyp; %% auxiliary variables logc1p = log(c1p); logc2p = log(c2p); invf1_ = 1/f1; invf2_ = 1/f2; logf1p_ = log(f1p); logf2p_ = log(f2p); invr1p_ = 1/r1p; invr2p_ = 1/r2p; q_ = exp(logq); qp_ = exp(logqp); invtila1_ = 1/tila1; invtila2_ = 1/tila2; rep_ = (1 + tilpp)/tilp*hatyp; % return on equity rbp_ = 1/q; % return on bond %% MODEL CONDITIONS invc1_ = 1 + 1/RHO*f1^(1 - THETA); c1_ = 1/invc1; invc1p_ = 1 + 1/RHO*f1p^(1 - THETA); c1p_ = 1/invc1p; invc2_ = 1 + 1/RHO*f2^(1-THETA); c2_ = 1/invc2; invc2p_ = 1 + 1/RHO*f2p^(1 - THETA); c2p_ = 1/invc2p; tila1_ = (1 + tilp)*state1 + state2; tila2_ = tilp + 1 - tila1; k1_ = x1*(1 - c1)*tila1/tilp; eq0 = -(1 - k1) + x2*(1 - c2)*tila2/tilp; tilb1_ = (1 - x1)*(1 - c1)*tila1; eq1 = tilb1*invtila2 + (1 - x2)*(1 - c2); r1p_ = x1*rep + (1 - x1)*rbp; r2p_ = x2*rep + (1 - x2)*rbp; term1p_ = ((invc1 - 1)*r1p*invf1)^(1 - GAMMA1)*((1 - NU*(1 - MU))*u1p^(1 - GAMMA1)... + NU*(1 - MU)*u2p^(1 - GAMMA1)); term2p_ = ((invc2 - 1)*r2p*invf2)^(1 - GAMMA2)*((1 - NU*MU)*u2p^(1 - GAMMA2)... + NU*MU*u1p^(1 - GAMMA2)); eq2 = -1 + term1p; eq3 = -1 + term2p; u1p_power_ = RHO/(1 + RHO)*c1p^(1 - THETA) + 1/(1 + RHO)*c1p^(1 - THETA)*f1p^(1 - THETA); u2p_power_ = RHO/(1 + RHO)*c2p^(1 - THETA) + 1/(1 + RHO)*c2p^(1 - THETA)*f2p^(1 - THETA); u1p_ = u1p_power^(1/(1 - THETA)); u2p_ = u2p_power^(1/(1 - THETA)); eq4 = (rep - rbp)*term1p*invr1p; eq5 = (rep - rbp)*term2p*invr2p; %% Function f (Ef = 0 imposes model conditions) f_fun = [eq0;eq1;eq2;eq3;eq4;eq5]; %% law of motion of state variables Phi_fun = [k1 - NU*(k1 - MU); % law of motion of state1p (1 - NU)*tilb1/(hatyp*q)]; % law of motion of state2p %% collect auxiliary variables and functions allvars=who; auxfuns=[]; auxvars=[]; for i=1:length(allvars) if strcmp(allvars{i}(end),'_') eval(['tempfun=' allvars{i} ';']) eval(['tempvar=' allvars{i}(1:end-1) ';']) auxfuns=[auxfuns;tempfun]; auxvars=[auxvars;tempvar]; end end %% Approximation order (<=4) order = 4; %% Preprocess model and save model = prepare_tp(f_fun,Phi_fun,controlp,control,statep,state,shocks,symparams,order,auxfuns,auxvars); save('model')