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author | Aaron LI <aly@aaronly.me> | 2018-12-22 21:15:07 +0800 |
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committer | Aaron LI <aly@aaronly.me> | 2018-12-22 21:15:07 +0800 |
commit | 1703eb5e04f9e35a56e5a764a8b08be1350d5326 (patch) | |
tree | eaa8dda5e0d95e37628b08029ad64f12e5398cde | |
parent | c74ec6af0df0520779b9d1743b1211031c118eaa (diff) | |
download | fg21sim-1703eb5e04f9e35a56e5a764a8b08be1350d5326.tar.bz2 |
clusters/main: Split out _simulate_halo1()
-rw-r--r-- | fg21sim/extragalactic/clusters/main.py | 98 |
1 files changed, 56 insertions, 42 deletions
diff --git a/fg21sim/extragalactic/clusters/main.py b/fg21sim/extragalactic/clusters/main.py index f471d90..ba3ecf1 100644 --- a/fg21sim/extragalactic/clusters/main.py +++ b/fg21sim/extragalactic/clusters/main.py @@ -228,9 +228,62 @@ class GalaxyClusters: nmax = max([cdict["merger_num"] for cdict in self.catalog]) logger.info("Maximum number of merger events: %d" % nmax) + def _simulate_halo1(self, clinfo): + """ + Calculate the radio halo information for the given cluster. + + Parameters + ---------- + clinfo : dict + The cluster information from ``self._simulate_mergers()``. + + Returns + ------- + haloinfo : dict + The calculated radio halo information. + """ + merger_num = clinfo["merger_num"] + M_obs = clinfo["mass"] + z_obs = clinfo["z"] + M1 = clinfo["merger_mass1"][merger_num-1] + z1 = clinfo["merger_z"][merger_num-1] + logger.info("M(%.2e)@z(%.3f) -> M(%.2e)@z(%.3f) with %d merger(s)" % + (M1, z1, M_obs, z_obs, merger_num)) + halo = RadioHaloAM(M_obs=M_obs, z_obs=z_obs, + M_main=clinfo["merger_mass1"], + M_sub=clinfo["merger_mass2"], + z_merger=clinfo["merger_z"], + merger_num=merger_num, + configs=self.configs) + n_e = halo.calc_electron_spectrum() + + return OrderedDict([ + ("z0", z_obs), + ("M0", M_obs), # [Msun] + ("age0", halo.age_obs), # [Gyr] + ("merger_num", merger_num), + ("lon", clinfo["lon"]), # [deg] longitude + ("lat", clinfo["lat"]), # [deg] longitude + ("felong", clinfo["felong"]), # fraction of elongation + ("rotation", clinfo["rotation"]), # [deg] rotation angle + ("Rvir0", halo.radius_virial_obs), # [kpc] + ("kT0", halo.kT_obs), # [keV] + ("B0", halo.B_obs), # [uG] magnetic field @ z_obs + ("Rhalo", halo.radius), # [kpc] + ("Rhalo_angular", halo.angular_radius), # [arcsec] + ("volume", halo.volume), # [kpc^3] + ("Ke", halo.injection_rate), # [cm^-3 Gyr^-1] + ("time_turbulence", halo.time_turbulence_avg), # [Gyr] + ("Mach_turb", halo.mach_turbulence_avg), # Mach number + ("tau_acc", halo.tau_acceleration_avg), # [Gyr] + ("tfrac_acc", halo.time_acceleration_fraction), + ("gamma", halo.gamma), # Lorentz factors + ("n_e", n_e), # [cm^-3] + ]) + def _simulate_halos(self): """ - Simulate the radio halo properties for each cluster that has mergers. + Calculate the radio halo information for each cluster that has mergers. Attributes ---------- @@ -246,47 +299,8 @@ class GalaxyClusters: ii = i + 1 if ii % 50 == 0: logger.info("[%d/%d] %.1f%% ..." % (ii, num, 100*ii/num)) - cdict = self.catalog[idx] - merger_num = cdict["merger_num"] - M_obs = cdict["mass"] - z_obs = cdict["z"] - M1 = cdict["merger_mass1"][merger_num-1] - z1 = cdict["merger_z"][merger_num-1] - info = ("[%d/%d] " % (ii, num) + - "M(%.2e)@z(%.3f) -> M(%.2e)@z(%.3f) with %d merger(s)" % - (M1, z1, M_obs, z_obs, merger_num)) - logger.info(info) - halo = RadioHaloAM(M_obs=M_obs, z_obs=z_obs, - M_main=cdict["merger_mass1"], - M_sub=cdict["merger_mass2"], - z_merger=cdict["merger_z"], - merger_num=merger_num, - configs=self.configs) - n_e = halo.calc_electron_spectrum() - data = OrderedDict([ - ("z0", z_obs), - ("M0", M_obs), # [Msun] - ("age0", halo.age_obs), # [Gyr] - ("merger_num", merger_num), - ("lon", cdict["lon"]), # [deg] longitude - ("lat", cdict["lat"]), # [deg] longitude - ("felong", cdict["felong"]), # fraction of elongation - ("rotation", cdict["rotation"]), # [deg] rotation angle - ("Rvir0", halo.radius_virial_obs), # [kpc] - ("kT0", halo.kT_obs), # [keV] - ("B0", halo.B_obs), # [uG] magnetic field @ z_obs - ("Rhalo", halo.radius), # [kpc] - ("Rhalo_angular", halo.angular_radius), # [arcsec] - ("volume", halo.volume), # [kpc^3] - ("Ke", halo.injection_rate), # [cm^-3 Gyr^-1] - ("time_turbulence", halo.time_turbulence_avg), # [Gyr] - ("Mach_turb", halo.mach_turbulence_avg), # Mach number - ("tau_acc", halo.tau_acceleration_avg), # [Gyr] - ("tfrac_acc", halo.time_acceleration_fraction), - ("gamma", halo.gamma), # Lorentz factors - ("n_e", n_e), # [cm^-3] - ]) - self.halos.append(data) + haloinfo = self._simulate_halo1(self.catalog[idx]) + self.halos.append(haloinfo) logger.info("Simulated radio halos.") def _calc_halos_emission(self): |