function [equs]=baseline_steadystate_find_AL_delta_varphi(xxx,pibar,mupsi,tauk,muzplus,R,alphaa,Rf,epsilon,lambdad,... etag,Rx,etax,omegax,etaf,omegai,etai,Upsilon,zetac,betaa,b,tauc,zetah,sigmaL,omegac,... etac,Rnustar,tauw,tauy,etaa,taud,s,phalo,pitildew,lambdamc,mc,piw,phalomi,phalomc,... phalomx,Rstar,lambdami,lambdamx,phalox,lambdax,taumx,taumc,taumi,mcmi,mcmx,mcmc,taux,mcx,... intensity_target,iy_target,xy_target,Rk,xiw,lambdaw) %back out parameter values AL=xxx(1)*10; delta=xxx(2); varphi=xxx(3); %what follows is part of the code in baseline_steadystate %Relative import prices pmx=taumx*Rnustar*varphi/mcmx; pmc=taumc*Rnustar*varphi/mcmc; pmi=taumi*Rnustar*varphi/mcmi; %Relative consumption price pc=(1-omegac+omegac*pmc^(1-etac))^(1/(1-etac)); %Relative investment price pinvest=(1-omegai+omegai*pmi^(1-etai))^(1/(1-etai)); %Relative export price px=(taux*Rx/(mcx*varphi))*(omegax*pmx^(1-etax)+1-omegax)^(1/(1-etax)); %Relative price of capital pkprime=pinvest/Upsilon; %Rental rate on capital rkbar=(Rk*mupsi*pkprime/pibar-(1-delta)*pkprime-tauk*delta*mupsi*pkprime/pibar)/(1-tauk); %Real Wage wbar=(mc/(taud*(1/(1-alphaa))^(1-alphaa)*(1/alphaa)^alphaa*rkbar^alphaa*Rf^(1-alphaa)/epsilon))^(1/(1-alphaa)); % Capital labor ratio kh=muzplus*((taud*mupsi^alphaa*wbar*Rf)/((1-alphaa)*mc))^(1/alphaa); %Abbreviation ThetacH ThetacH=1/(zetah*AL)*((1-xiw*(pitildew/piw)^(1/(1-lambdaw)))/(1-xiw))^(1-lambdaw*(1+sigmaL))... *(wbar*(1-tauy)/(lambdaw*(1+tauw)))*(1-betaa*xiw*(pitildew/piw)^(lambdaw*(1+sigmaL)/(1-lambdaw)))... *(zetac/(muzplus-b)*(muzplus-betaa*b)/(pc*(1+tauc)))/(1-betaa*xiw*(pitildew/piw)^(1/(1-lambdaw))); %Abbreviation Thetay Thetay=phalo^(lambdad/(lambdad-1))*epsilon*(kh/(mupsi*muzplus))^alphaa... /(1+phalo^(lambdad/(lambdad-1))*(1/mc-phalo^(lambdad/(1-lambdad)))); %alphaa abbreviations alpha1=omegac*(pc/pmc)^etac*ThetacH*phalomc^(lambdamc/(1-lambdamc)); alpha2=(1-Rstar*s/(pibar*muzplus))*etaa*Thetay/varphi... +omegai*(pinvest/pmi)^etai*kh*(1-(1-delta)/(muzplus*mupsi))/Upsilon*phalomi^(lambdami/(1-lambdami)); alpha3=px^(1-etaf)/Rnustar-omegax*((omegax*pmx^(1-etax)+1-omegax)^(1/(1-etax))/pmx)^etax... *phalox^(lambdax/(1-lambdax))*px^(-etaf)*phalomx^(lambdamx/(1-lambdamx)); alpha4=(1-etag)*Thetay-pinvest^etai*kh*(1-(1-delta)/(muzplus*mupsi))/Upsilon*(1-omegai); alpha5=(1-omegac)*pc^etac*ThetacH; alpha6=(omegax*pmx^(1-etax)+1-omegax)^(etax/(1-etax))*(1-omegax)... *phalox^(lambdax/(1-lambdax))*px^(-etaf); %Hours H=((alpha5+alpha6*alpha1/alpha3)/(alpha4-alpha6*alpha2/alpha3))^(1/(1+sigmaL)); %Further steady states kbar=kh*H; ybar=Thetay*H; i=kbar*(1-(1-delta)/(muzplus*mupsi))/Upsilon; ystar=1/alpha3*(alpha1*H^(-sigmaL)+alpha2*H); x=px^(-etaf)*ystar; whalo=((1-xiw*(pitildew/piw)^(1/(1-lambdaw)))/(1-xiw))^(1-lambdaw)... /((1-xiw*(pitildew/piw)^(lambdaw/(1-lambdaw)))/(1-xiw))^((1-lambdaw)/lambdaw); smallh=whalo^(lambdaw/(1-lambdaw))*H; %construct equations to hold with approximate equality %smallh target equ1=smallh-intensity_target; %iy target equ2=i*pinvest/ybar-iy_target; %xy target % old incorrect version: equ3=x*px/ybar-xy_target; equ3=px^(-etaf)*ystar*px*varphi/ybar-xy_target; %create equation vector for fsolve equs=[equ1 equ2 equ3];