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authorAaron LI <aly@aaronly.me>2017-08-11 23:19:30 +0800
committerAaron LI <aly@aaronly.me>2017-08-11 23:19:30 +0800
commitb364604b5ad0e76c1cb4dd0a33ac4ffd77a77b6f (patch)
tree1bd7ac4f3950695675bf5eb740c12a157e3d4ae3 /fg21sim/extragalactic/clusters/helper.py
parent3cd0b04107a6b42040f9431b0a2f6728273b57a9 (diff)
downloadfg21sim-b364604b5ad0e76c1cb4dd0a33ac4ffd77a77b6f.tar.bz2
clusters: Implement calc_{power,flux,brightness_mean} in helper
Help development & debug ... Signed-off-by: Aaron LI <aly@aaronly.me>
Diffstat (limited to 'fg21sim/extragalactic/clusters/helper.py')
-rw-r--r--fg21sim/extragalactic/clusters/helper.py106
1 files changed, 106 insertions, 0 deletions
diff --git a/fg21sim/extragalactic/clusters/helper.py b/fg21sim/extragalactic/clusters/helper.py
index 0d66dee..4b7185f 100644
--- a/fg21sim/extragalactic/clusters/helper.py
+++ b/fg21sim/extragalactic/clusters/helper.py
@@ -27,6 +27,7 @@ References
http://adsabs.harvard.edu/abs/2014MNRAS.438..124Z
"""
+import logging
import numpy as np
from scipy import integrate
@@ -35,6 +36,10 @@ from ...share import CONFIGS, COSMO
from ...utils.units import (Units as AU,
Constants as AC,
UnitConversions as AUC)
+from ...utils.convert import Fnu_to_Tb_fast
+
+
+logger = logging.getLogger(__name__)
def radius_virial(mass, z=0.0):
@@ -293,3 +298,104 @@ def magnetic_field(mass):
M_mean = 1.6e15 # [Msun]
B = b_mean * (mass/M_mean) ** b_index
return B
+
+
+def calc_power(emissivity, volume):
+ """
+ Calculate the synchrotron power (i.e., power *emitted* per unit
+ frequency) from emissivity, which assumed to be uniform within
+ the volume.
+
+ NOTE
+ ----
+ The calculated power (a.k.a. spectral luminosity) is in units of
+ [W/Hz] which is common in radio astronomy, instead of [erg/s/Hz].
+ 1 [W] = 1e7 [erg/s]
+
+ Parameters
+ ----------
+ emissivity : float, or 1D `~numpy.ndarray`
+ The synchrotron emissivity at multiple frequencies.
+ Unit: [erg/s/cm^3/Hz]
+ volume : float
+ The volume of the radio halo
+ Unit: [kpc^3]
+
+ Returns
+ -------
+ power : float, or 1D `~numpy.ndarray`
+ The calculated synchrotron power w.r.t. each input emissivity.
+ Unit: [W/Hz]
+ """
+ emissivity = np.asarray(emissivity)
+ power = emissivity * (volume * AUC.kpc2cm**3) # [erg/s/Hz]
+ power *= 1e-7 # [erg/s/Hz] -> [W/Hz]
+ return power
+
+
+def calc_flux(power, z):
+ """
+ Calculate the synchrotron flux density (i.e., power *observed*
+ per unit frequency) from radio power at a certain redshift (i.e.,
+ distance).
+
+ Parameters
+ ----------
+ power : float, or 1D `~numpy.ndarray`
+ The synchrotron power at multiple frequencies.
+ Unit: [W/Hz]
+
+ Returns
+ -------
+ flux : float, or 1D `~numpy.ndarray`
+ The calculated synchrotron flux w.r.t. each input power.
+ Unit: [Jy] = 1e-23 [erg/s/cm^2/Hz] = 1e-26 [W/m^2/Hz]
+ """
+ DL = COSMO.DL(z) * AUC.Mpc2m # [m]
+ flux = 1e26 * power / (4*np.pi * DL*DL) # [Jy]
+ return flux
+
+
+def calc_brightness_mean(flux, frequency, omega, pixelsize=None):
+ """
+ Calculate the mean surface brightness (power observed per unit
+ frequency and per unit solid angle) expressed in *brightness
+ temperature* at the specified frequencies from flux.
+
+ NOTE
+ ----
+ If the solid angle that the object extends is smaller than the
+ specified pixel area, then is is assumed to have size of 1 pixel.
+
+ Parameters
+ ----------
+ flux : float, or 1D `~numpy.ndarray`
+ The synchrotron flux densities at multiple frequencies.
+ Unit: [Jy]
+ frequency : float, or 1D `~numpy.ndarray`
+ The frequencies where the above flux calculated.
+ Unit: [MHz]
+ omega : float
+ The sky coverage (angular size) of the object.
+ Unit: [arcsec^2]
+ pixelsize : float, optional
+ The pixel size of the output simulated sky image.
+ Unit: [arcsec]
+
+ Returns
+ -------
+ Tb : float, or 1D `~numpy.ndarray`
+ The mean surface brightness at each frequency.
+ Unit: [K] <-> [Jy/pixel]
+ """
+ if pixelsize and (omega < pixelsize**2):
+ omega = pixelsize ** 2 # [arcsec^2]
+ logger.warning("Object sky coverage < 1 pixel; force to be 1 pixel")
+
+ Tb = [Fnu_to_Tb_fast(Fnu, omega, freq)
+ for Fnu, freq in zip(np.array(flux, ndmin=1),
+ np.array(frequency, ndmin=1))]
+ if len(Tb) == 1:
+ return Tb[0]
+ else:
+ return np.array(Tb)