def decr(endogvarm1, innov, paramplus, acoeff, poly): #decision rule with variables in levels and deviation from steady state. endogvar = {} kk = endogvarm1['kp_d'] invm1 = endogvarm1['inv_d'] shocks = np.zeros(poly['ne']) if poly['shockswitch'] == 0: shocks[0] = paramplus['rhobeta'] * endogvarm1['beta_d'] + paramplus[ 'stdbeta'] * innov[0] if poly['ne'] == 2: shocks[1] = paramplus['rhomu'] * endogvarm1['mu_d'] + paramplus[ 'stdmu'] * innov[1] else: shocks[0] = paramplus['rhomu'] * endogvarm1['mu_d'] + paramplus[ 'stdmu'] * innov[0] if poly['ne'] == 2: shocks[1] = paramplus['rhobeta'] * endogvarm1[ 'beta_d'] + paramplus['stdbeta'] * innov[1] if (poly['ne'] == 0): msvm1 = np.array([kk, invm1, shocks[0]]) xx1 = po.msv2xx(msvm1, poly['nmsv'], poly['scmsv2xx']) poly_xx = chebpolytensor(xx1, poly['nmsv'], poly['npoly'], poly['ncheb']) for ifunc in np.arange(nfunc): polycur[ifunc] = np.dot( acoeff[0, ifunc * poly['npoly']:(ifunc + 1) * poly['npoly']], poly_xx) else: msvm1 = np.array([kk, invm1]) ind_shocks = po.get_index(shocks, poly['ne'], poly['ngrid'], poly['steps'], poly['bounds']) xx1 = po.msv2xx(msvm1, poly['nmsv'], poly['scmsv2xx']) polycur = po.get_linspline(xx1,shocks,ind_shocks,acoeff,poly['exoggrid'],poly['steps'],poly['nfunc'],\ poly['ngrid'],poly['npoly'],poly['nmsv'],poly['ncheb'],poly['ne']) (dvar, lvar) = modelvariables(polycur, msvm1, shocks, paramplus, poly['eqswitch'], poly['shockswitch'], poly['ne']) for x in lvar: endogvar[x] = lvar[x] endogvar[x + '_d'] = dvar[x] return (endogvar)
def decr(endogvarm1, innov, regime, acoeff, poly, params): endogvar = np.zeros(poly['nvars']) ne = poly['nexog_fe'] npoly = poly['npoly'] nmsv = poly['nmsv'] nmsve = poly['nexog_nmsv'] nsreg = poly['nsreg'] nx = nmsv - nmsve - (nsreg - 1) ss = np.zeros(ne + nmsve) msvm1 = np.zeros(nmsv) shocks = np.zeros(ne + 1) #update non-monetary shocks and compute place on grid endogvar[ -6] = params['rhoeta'] * endogvarm1[-4] + params['stdeta'] * innov[0] ss[0] = endogvar[-6] ind_ss = po.get_index(ss, ne, poly['ngrid'], poly['steps'], poly['bounds']) ss[1] = poly['gamma0'][regime] + params['stdm'] * innov[1] endogvar[-3] = ss[1] endogvar[-4] = params['stdm'] * innov[1] endogvar[-5] = poly['gamma0'][regime] msvm1[:nx + nsreg - 1] = endogvarm1[:nx + nsreg - 1] msvm1[nx + nsreg - 1] = ss[1] xxm1 = po.msv2xx(msvm1, nmsv, poly['scmsv2xx']) polycur = po.get_linspline(xxm1, ss[:ne], ind_ss, acoeff, poly['exoggrid'], poly['steps'], poly['nfunc'], poly['ngrid'], npoly, nmsv, ne) (yy, dp, nr, lptp, post) = modelvariables(polycur, msvm1[:nmsv - nmsve], ss, params, nmsv, nmsve, nsreg, poly['gamma0'], poly['P']) endogvar[-2] = polycur[0] endogvar[-1] = polycur[1] endogvar[0] = nr endogvar[1] = yy endogvar[2] = dp if nsreg == 2: endogvar[nx] = lptp else: endogvar[nx:nx + nsreg - 1] = lptp endogvar[nx + nsreg - 1:nx + 2 * nsreg - 1] = post return (endogvar)
def calc_euler(ind_state, gridindex, acoeff, poly, paramplus): npoly = poly['npoly'] nmsv = poly['nmsv'] ne = poly['ne'] polycur = np.zeros([poly['nfunc']]) polyvarm1 = poly['bbt'][gridindex, :] for ifunc in np.arange(poly['nfunc']): polycur[ifunc] = np.dot( acoeff[ind_state, ifunc * npoly:(ifunc + 1) * npoly], polyvarm1) msvm1 = po.msv2xx(poly['pgrid'][gridindex, :], nmsv, poly['scxx2msv']) kk = msvm1[0] invm1 = msvm1[1] if ne == 0: shocks = np.zeros(poly['ninnov']) shocks[0] = msvm1[2] else: shocks = poly['exoggrid'][ind_state, :] (dvar, lvar) = modelvariables(polycur, msvm1, shocks, paramplus, poly['eqswitch'], poly['shockswitch'], poly['ne']) ind = npoly * ind_state + gridindex ss_futmat = poly['sfutquad'][ind_state, :, :] if ne > 0: ind_futmat = poly['ind_sfutquad'][ind_state, :, :] msv = np.array([dvar['kp'], dvar['inv']]) else: msv = np.zeros(nmsv) msv[0] = dvar['kp'] msv[1] = dvar['inv'] exp_qeq = 0. exp_ieq = 0. qweight = (1.0 - paramplus['delta']) / paramplus['gamma'] for j in np.arange(poly['nqs']): if ne == 0: msv[2] = ss_futmat[j, :] xx1 = po.msv2xx(msv, nmsv, poly['scmsv2xx']) if ne == 0: poly_xx = po.chebpolytensor(xx1, nmsv, npoly, poly['ncheb']) polyfut = np.zeros(poly['nfunc']) for ifunc in np.arange(poly['nfunc']): polyfut[ifunc] = np.dot( acoeff[0, ifunc * npoly:(ifunc + 1) * npoly], poly_xx) else: polyfut = po.get_linspline(xx1,ss_futmat[j,:],ind_futmat[j,:],acoeff,poly['exoggrid'],poly['steps'],poly['nfunc'],\ poly['ngrid'],npoly,nmsv,poly['ncheb'],ne) (dvarp, lvarp) = modelvariables(polyfut, msv, ss_futmat[j, :], paramplus, poly['eqswitch'], poly['shockswitch'], poly['ne']) if (poly['eqswitch'] == 0): exp_qeq = exp_qeq + poly['quadweight'][j] * qweight * dvarp['qq'] exp_ieq = exp_ieq + poly['quadweight'][j] * paramplus['beta'] * ( dvarp['inv'] - dvar['inv']) else: exp_qeq = exp_qeq + poly['quadweight'][j] * qweight * lvarp['qq'] Sprimep = paramplus['b'] * paramplus['a'] * ( np.exp(paramplus['a'] * (lvarp['inv'] / lvar['inv'] - 1)) - 1) exp_ieq = exp_ieq + poly['quadweight'][j] * lvar['beta'] * lvarp[ 'qq'] * lvarp['mu'] * Sprimep * (lvarp['inv'] / lvar['inv'])**2 polynew = np.zeros(poly['nfunc']) if poly['eqswitch'] == 0: polynew[0] = invm1 + (1.0 / (paramplus['a']**2 * paramplus['b'])) * ( dvar['qq'] + dvar['mu']) + exp_ieq polynew[1] = -(1 - paramplus['beta'] * qweight) * ( 1.0 - paramplus['alpha'] ) * dvar['kp'] + paramplus['beta'] * exp_qeq + dvar['beta'] else: linvm1 = np.exp(invm1 + np.log(paramplus['inv'])) dinv_l = lvar['inv'] / linvm1 adjcost = paramplus['b'] * (np.exp(paramplus['a'] * (dinv_l - 1)) - paramplus['a'] * (dinv_l - 1) - 1) stemp = (1 - adjcost - (1.0 - exp_ieq) / (lvar['qq'] * lvar['mu'])) * (1 / dinv_l) sarg = 1.0 + ( 1.0 / paramplus['a']) * np.log(1.0 + stemp / (paramplus['b'] * paramplus['a'])) polynew[0] = invm1 + np.log(sarg) rkp = (paramplus['alpha'] / paramplus['gamma']) * ( lvar['kp'] / paramplus['gamma'])**(paramplus['alpha'] - 1) polynew[1] = np.log(lvar['beta'] * (rkp + exp_qeq)) res = np.sum(np.abs(polynew - polycur)) / poly['nfunc'] # if (gridindex == 1): # print('---------------------') # print('kk = ', kk) # print('invm1 = ', invm1) # print('dvar =', dvar) # print(np.abs(polynew-polycur)) # print('polycur = ', polycur) # print('exp_qeq = ', exp_qeq) # print('exp_ieq = ', exp_ieq) # print('-----------------') # print('ind_state = ', ind_state) # print('gridindex = ', gridindex) # print('msvm1 = ', msvm1) # print('shocks = ', shocks) # print('---------------------') # print('polynew = ', polynew) # print('res = ', res) # sys.exit('in calc') return (polynew, res)
def calc_euler(ind_state, gridindex, acoeff, polyapp, params): #returns predicted decision rules and prediction errors from sys import exit npoly = polyapp['npoly'] nmsv = polyapp['nmsv'] nmsve = polyapp['nexog_nmsv'] ne = polyapp['nexog_fe'] nsreg = polyapp['nsreg'] nx = nmsv - nmsve - (nsreg - 1) polycur = np.zeros([polyapp['nfunc']]) polyvarm1 = polyapp['bbt'][gridindex, :] for ifunc in np.arange(polyapp['nfunc']): polycur[ifunc] = np.dot( acoeff[ind_state, ifunc * npoly:(ifunc + 1) * npoly], polyvarm1) msvm1 = po.msv2xx(polyapp['pgrid'][gridindex, :], nmsv, polyapp['scxx2msv']) ss = np.append(polyapp['exoggrid'][ind_state, :], msvm1[nmsv - nmsve:]) (yy, dp, nr, lptp, posterior) = modelvariables(polycur, msvm1[:nmsv - nmsve], ss, params, nmsv, nmsve, nsreg, polyapp['gamma0'], polyapp['P']) ind_futmat = polyapp['ind_sfutquad'][ind_state, :, :] ss_futmat = polyapp['sfutquad'][ind_state, :, :] exp_yyp = 0. exp_dpp = 0. msv = np.zeros(nmsv) if (nx >= 1): msv[0] = nr if (nx >= 2): msv[1] = yy if (nx == 3): msv[2] = dp ptp_c_t = np.zeros(nsreg) if (nsreg == 2): msv[nx] = lptp[0] ptp_c_t[0] = np.exp(msv[nx]) ptp_c_t[1] = 1.0 - ptp_c_t[0] else: mid = np.int((nsreg + 1) / 2) msv[nx:nx + mid - 1] = lptp[:mid - 1] msv[nx + mid - 1:nx + nsreg] = lptp[mid - 1:] ptp_c_t[0:mid - 1] = np.exp(msv[nx:nx + mid - 1]) ptp_c_t[mid:] = np.exp(msv[nx + mid:nx + nsreg]) temp_arr = np.append(ptp_c_t[:mid - 1], ptp_c_t[mid:]) ptp_c_t[mid - 1] = 1.0 - np.sum(temp_arr) for ireg in np.arange(nsreg): for j in np.arange(polyapp['nqs']): shockall = ss_futmat[j, :] shockall[ne] = polyapp['gamma0'][ireg] + ss_futmat[j, ne] msv[nmsv - nmsve] = shockall[ne] xx1 = po.msv2xx(msv, nmsv, polyapp['scmsv2xx']) polyfut = po.get_linspline(xx1, ss_futmat[j, :ne], ind_futmat[j, :], acoeff, polyapp['exoggrid'], polyapp['steps'], polyapp['nfunc'], polyapp['ngrid'], npoly, nmsv, ne) (yyp, dpp, nrp, lptpp, postp) = modelvariables(polyfut, msv[:nmsv - nmsve], shockall, params, nmsv, nmsve, nsreg, polyapp['gamma0'], polyapp['P']) exp_yyp = exp_yyp + ptp_c_t[ireg] * polyapp['quadweight'][j] * yyp exp_dpp = exp_dpp + ptp_c_t[ireg] * polyapp['quadweight'][j] * dpp polynew = np.zeros(polyapp['nfunc']) polynew[0] = exp_yyp polynew[1] = exp_dpp # print('difference in coeffs') # print(np.abs(polynew-polycur)) # print('polycur = ', polycur) # print('-----------------') # print('ind_state = ', ind_state) # print('gridindex = ', gridindex) # print('msv = ', msv) # print('ptp_c_t = ', ptp_c_t) # print('polynew = ', polynew) # print('data = ', yy,dp,nr,posterior.round(3)) # exit() res = np.sum(np.abs(polynew - polycur)) / (polyapp['nfunc']) return (polynew, res)