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author | Aaron LI <aaronly.me@outlook.com> | 2016-10-24 22:21:31 +0800 |
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committer | Aaron LI <aaronly.me@outlook.com> | 2016-10-24 22:21:31 +0800 |
commit | 200ac8cdc3661af0306b85d7589a13759a66ee41 (patch) | |
tree | 4fb517aea9812bb891774510daf41207692530ec /fg21sim/utils | |
parent | 5fa8d50cbf9aacbc846cf650d1cbd2ec9fd0b5a3 (diff) | |
download | fg21sim-200ac8cdc3661af0306b85d7589a13759a66ee41.tar.bz2 |
convert.py: Optimize "Fnu_to_Tb()" and "Sb_to_Tb()"
* Optimize the "Fnu_to_Tb()" and "Sb_to_Tb()" functions by explicitly
calculating the conversions, avoiding the slow `astropy.unit`
conversions (which is rather slow). The new fast functions are named
as "Fnu_to_Tb_fast()" and "Sb_to_Tb_fast()".
* Optimize the new functions using `numba.jit` further.
* Add `numba` to the dependencies.
Diffstat (limited to 'fg21sim/utils')
-rw-r--r-- | fg21sim/utils/convert.py | 65 |
1 files changed, 65 insertions, 0 deletions
diff --git a/fg21sim/utils/convert.py b/fg21sim/utils/convert.py index 1212780..fc9a228 100644 --- a/fg21sim/utils/convert.py +++ b/fg21sim/utils/convert.py @@ -5,7 +5,9 @@ Utilities for conversion among common astronomical quantities. """ +import numpy as np import astropy.units as au +import numba def Fnu_to_Tb(Fnu, omega, freq): @@ -61,3 +63,66 @@ def Sb_to_Tb(Sb, freq): omega = 1.0 * au.sr Fnu = Sb * omega return Fnu_to_Tb(Fnu, omega, freq) + + +@numba.jit(nopython=True) +def Sb_to_Tb_fast(Sb, freq): + """Convert surface brightness to brightness temperature, using the + Rayleigh-Jeans law, in the Rayleigh-Jeans limit. + + This function does the calculations explicitly, and does NOT rely + on the `astropy.units`, therefore it is faster. However, the input + parameters must be in right units. + + Tb = Sb * c^2 / (2 * k_B * nu^2) + + where `SB` is the surface brightness density measured at a certain + frequency (unit: [ Jy/rad^2 ] = [ erg/s/cm^2/Hz/rad^2 ]). + + Parameters + ---------- + Sb : float + Input surface brightness, unit [ Jy/deg^2 ] + freq : float + Frequency where the flux density measured, unit [ MHz ] + + Returns + ------- + Tb : float + Calculated brightness temperature, unit [ K ] + """ + # NOTE: `radian` is dimensionless + rad2_to_deg2 = np.rad2deg(1.0) * np.rad2deg(1.0) + Sb_rad2 = Sb * rad2_to_deg2 # unit: [ Jy/rad^2 ] -> [ Jy ] + c = 29979245800.0 # speed of light, [ cm/s ] + k_B = 1.3806488e-16 # Boltzmann constant, [ erg/K ] + coef = 1e-35 # take care the unit conversions + Tb = coef * (Sb_rad2 * c*c) / (2 * k_B * freq*freq) # unit: [ K ] + return Tb + + +@numba.jit(nopython=True) +def Fnu_to_Tb_fast(Fnu, omega, freq): + """Convert flux density to brightness temperature, using the + Rayleigh-Jeans law, in the Rayleigh-Jeans limit. + + This function does the calculations explicitly, and does NOT rely + on the `astropy.units`, therefore it is faster. However, the input + parameters must be in right units. + + Parameters + ---------- + Fnu : float + Input flux density, unit [ Jy ] + omega : float + Source angular size/area, unit [ deg^2 ] + freq : float + Frequency where the flux density measured, unit [ MHz ] + + Returns + ------- + Tb : float + Calculated brightness temperature, unit [ K ] + """ + Sb = Fnu / omega + return Sb_to_Tb_fast(Sb, freq) |