Exemplo n.º 1
0
def get_quadstates(poly, paramplus):
    #returns exogenous states at each quadrature point and each exogenous grid point

    ninnov = poly['ninnov']
    nqs = poly['nqs']
    ns = poly['ns']
    npoly = poly['npoly']
    ne = ninnov
    quadgrid, quadweight = po.get_quadgrid(poly['nquad'], ninnov, nqs)

    if poly['ne'] == 0:
        nchebexog = np.prod(poly['ncheb'][2:])
        pgridexog = poly['pgrid'][:nchebexog, 2:poly['nmsv']]
        ns = nchebexog
        exoggrid = np.zeros([nchebexog, poly['nmsv'] - 2])
        exogscxx2msv = poly['scxx2msv'][2:poly['nmsv'] * 2:poly['nmsv']]
        for i in np.arange(ns):
            exoggrid[i, :] = po.msv2xx(pgridexog[i, :], poly['nmsv'] - 2,
                                       exogscxx2msv)
    else:
        exoggrid = poly['exoggrid']

    sfut = np.zeros([ns, nqs, ninnov])
    ind_sfut = np.zeros([ns, nqs, ne], dtype=int)
    for j in np.arange(nqs):
        for i in np.arange(ns):
            if poly['shockswitch'] == 0:
                sfut[i, j, 0] = paramplus['rhobeta'] * exoggrid[
                    i, 0] + paramplus['stdbeta'] * quadgrid[j, 0]
                if ninnov == 2:
                    sfut[i, j, 1] = paramplus['rhomu'] * exoggrid[
                        i, 1] + paramplus['stdmu'] * quadgrid[j, 1]
            else:
                sfut[i, j, 0] = paramplus['rhomu'] * exoggrid[
                    i, 0] + paramplus['stdmu'] * quadgrid[j, 0]
                if ninnov == 2:
                    sfut[i, j, 1] = paramplus['rhobeta'] * exoggrid[
                        i, 1] + paramplus['stdbeta'] * quadgrid[j, 1]
            if poly['ne'] > 0:
                ind_sfut[i, j, :] = po.get_index(sfut[i, j, :], ninnov,
                                                 poly['ngrid'], poly['steps'],
                                                 poly['bounds'])
    return (sfut, ind_sfut, quadweight)
Exemplo n.º 2
0
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 get_quadstates(poly, params):
    #returns exogenous states at each quadrature point and each exogenous grid point

    ninnov = poly['ninnov']
    nqs = poly['nqs']
    ns = poly['ns']
    npoly = poly['npoly']
    ne = poly['nexog_fe']
    quadgrid, quadweight = po.get_quadgrid(poly['nquad'], ninnov, nqs)
    sfut = np.zeros([ns, nqs, ninnov])
    ind_sfut = np.zeros([ns, nqs, ne], dtype=int)

    for i in np.arange(ns):
        for j in np.arange(nqs):
            sfut[i, j, :ne] = poly['rhos'][:ne] * poly['exoggrid'][
                i, :] + poly['stds'][:ne] * quadgrid[j, :ne]
            sfut[i, j, ne] = params['stdm'] * quadgrid[j, ne]
            ss = sfut[i, j, :ne]
            ind_sfut[i, j, :] = po.get_index(ss, ne, poly['ngrid'],
                                             poly['steps'], poly['bounds'])
    return (sfut, ind_sfut, quadweight)
Exemplo n.º 5
0
def get_quadstates(poly, paramplus):
    #returns exogenous states at each quadrature point and each exogenous grid point

    ninnov = poly['ninnov']
    nqs = poly['nqs']
    ns = poly['ns']
    npoly = poly['npoly']
    ne = ninnov
    quadgrid, quadweight = po.get_quadgrid(poly['nquad'], ninnov, nqs)
    sfut = np.zeros([ns, nqs, ninnov])
    ind_sfut = np.zeros([ns, nqs, ne], dtype=int)

    #meanpreserve = -paramplus['stdbeta']**2/(2*(1.0+paramplus['rhobeta']))
    #print(meanpreserve)
    for j in np.arange(nqs):
        for i in np.arange(ns):
            sfut[i, j, 0] = paramplus['rhobeta'] * poly['exoggrid'][
                i, 0] + paramplus['stdbeta'] * quadgrid[j, 0]  #+ meanpreserve
            if ne == 2:
                sfut[i, j, 1] = paramplus['rhomu'] * poly['exoggrid'][
                    i, 1] + paramplus['stdmu'] * quadgrid[j, 0]
            ind_sfut[i, j, :] = po.get_index(sfut[i, j, :], ne, poly['ngrid'],
                                             poly['steps'], poly['bounds'])
    return (sfut, ind_sfut, quadweight)