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radialintensity.py
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177 lines (138 loc) · 4.43 KB
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from aart_func import *
from params import *
import argparse
parser = argparse.ArgumentParser(description='Intensity as function of radial distance from black hole')
parser.add_argument('--nu', default=ilp.kw_nu0.value, type=float)
parser.add_argument('--mass', default=ilp.kw_mass.value, type=float)
parser.add_argument('--scaleh', default=ilp.kw_scale_height, type=float)
parser.add_argument('--thetab', default=ilp.kw_theta_b.value, type=float)
parser.add_argument('--beta', default=ilp.kw_beta, type=float)
parser.add_argument('--rie', default=ilp.kw_beta, type=float)
parser.add_argument('--rb0', default=ilp.kw_rb_0, type=float)
parser.add_argument('--nth0', default=ilp.kw_n_th0.value, type=float)
parser.add_argument('--te0', default=ilp.kw_t_e0.value, type=float)
parser.add_argument('--b0', default=ilp.kw_bv_0.value, type=float)
parser.add_argument('--pdens', default=ilp.kw_p_dens, type=float)
parser.add_argument('--ptemp', default=ilp.kw_p_temp, type=float)
parser.add_argument('--pmag', default=ilp.kw_p_bv, type=float)
parser.add_argument('--nscale', default=ilp.kw_nscale, type=float)
parser.add_argument('--emodelkey', default=0, type=int)
parser.add_argument('--bkey', default=0, type=int)
parser.add_argument('--nnoisykey', default=0, type=int)
parser.add_argument('--tnoisykey', default=0, type=int)
parser.add_argument('--bnoisykey', default=0, type=int)
parser.add_argument('--thetabkey', default=0, type=int)
parser.add_argument('--lband', default="0", type=str) # PATH_DIR
parser.add_argument('--rtray', default="0", type=str) # PATH_DIR
parser.add_argument('--magang', default="0", type=str) # PATH_DIR
args = parser.parse_args()
brightparams = {
"nu0": args.nu*ilp.Hz, # 0
"mass": args.mass*ilp.grams, # 1
"scale_height": args.scaleh, # 2
"theta_b": args.thetab*ilp.rads, # 3
"beta": args.beta, # 4
"r_ie": args.rie, # 5
"rb_0": args.rb0, # 6
"n_th0": args.nth0*ilp.cmcubed, # 7
"t_e0": args.te0*ilp.kelv, # 8
"b_0": args.b0*ilp.gauss, # 9
"p_dens": args.pdens, # 10
"p_temp": args.ptemp, # 11
"p_mag": args.pmag, # 12
"nscale": args.nscale, # 13
}
funckeys = {
"emodelkey": args.emodelkey, # 0
"bkey": args.bkey, # 1
"nnoisykey": args.nnoisykey, # 2
"tnoisykey": args.tnoisykey, # 3
"bnoisykey": args.bnoisykey, # 4
"theta_bkey": args.thetabkey # 0 for variable theta b, 1 for fixed
}
# Getting angles
# fnrays="./Results/Rays_a_%s_i_%s.h5"%(spin_case,i_case)
rtray = args.rtray
lband = args.lband
magAng = args.magang
if rtray == "0":
print("using default rtray")
fnrays = path + "Rays_a_%s_i_%s.h5"%(spin_case,i_case)
else:
print("using altered rtray")
fnrays = rtray
print("Reading file: ",fnrays)
h5f = h5py.File(fnrays,'r')
phi012 = [
h5f['phi0'][:],
h5f['phi1'][:],
h5f['phi2'][:]
]
fact=-(D_obs+2*np.log(D_obs))
t0rt=h5f['t0'][:]
t1rt=h5f['t1'][:]
t2rt=h5f['t2'][:]
t0rt-=fact
t1rt-=fact
t2rt-=fact
fact2=5000/2-np.nanmax(t0rt) #GENERALIZE!
t012 = [
t0rt+fact2,
t1rt+fact2,
t2rt+fact2
]
h5f.close()
#-------------------------
if magAng == "0":
print("using default magAng")
fn = path + "MagneticAngle_a_%s_i_%s.h5"%(spin_case,i_case)
else:
print("using altered rtray")
fn = magAng
h5f = h5py.File(fn,'r')
#Points for the boundary of the BH shadow
anglen0=h5f['cos2angB_n0'][:]
anglen1=h5f['cos2angB_n1'][:]
anglen2=h5f['cos2angB_n2'][:]
h5f.close()
#-------------------------
print("Intensity")
if lband == "0":
fnbands = path + "LensingBands_a_%s_i_%s.h5" % (spin_case, i_case)
print("using default lband")
else:
print("using altered lband")
fnbands = lband
print("Reading file: ",fnbands)
h5f = h5py.File(fnbands,'r')
supergrid0=h5f['grid0'][:]
mask0=h5f['mask0'][:]
N0=int(h5f["N0"][0])
if bvapp!=1:
supergrid1=h5f['grid1'][:]
mask1=h5f['mask1'][:]
N1=int(h5f["N1"][0])
supergrid2=h5f['grid2'][:]
mask2=h5f['mask2'][:]
N2=int(h5f["N2"][0])
fnbands=fnrays
print("Reading file: ",fnbands)
h5f = h5py.File(fnbands,'r')
rs0=h5f['rs0'][:]
sign0=h5f['sign0'][:]
rs1=h5f['rs1'][:]
sign1=h5f['sign1'][:]
rs2=h5f['rs2'][:]
sign2=h5f['sign2'][:]
h5f.close()
obsint.br(supergrid0,mask0,N0,rs0,sign0,anglen0,supergrid1,mask1,N1,rs1,sign1,anglen1,
supergrid2,mask2,N2,rs2,sign2,anglen2,brightparams,funckeys,phi012,t012)
else:
h5f.close()
fnrays=rtray
print("Reading file: ",fnrays)
h5f = h5py.File(fnrays,'r')
rs0_bv=h5f['rs0_bv'][:]
sign0_bv=h5f['sign0_bv'][:]
h5f.close()
obsint.br_bv(supergrid0,mask0,N0,rs0_bv,sign0_bv)