def _generate_request_passband(pbr, content_request, gzipped=False, save=True):
if app._verbose:
print("_generate_request_passband {} {} gzipped={} save={}".format(
pbr, content_request, gzipped, save))
# we have to force reloading from the file here or else changing the content
# will persist in memory
pb = phoebe.get_passband(pbr, reload=True)
prefix = '{}_{}'.format(pb.pbset.lower(), pb.pbname.lower())
filename = '{}.fits.gz'.format(prefix) if gzipped else '{}.fits'.format(
prefix)
if isinstance(content_request, str):
if content_request.lower() == 'all':
pass
else:
raise ValueError(
"pass content_request through _unpack_content_request first")
else:
content_return = []
for c in content_request:
c_expanded = _expand_content_item(pb, c)
# if not len(c_expanded):
# raise ValueError("could not find content match for content_request={}".format(c))
content_return += c_expanded
content_return = list(set(content_return))
print("serving {} passband with content={}".format(
pbr, content_return))
pb.content = content_return
if save:
pbf = tempfile.NamedTemporaryFile(
mode='w+b',
dir=tmpdir,
prefix=prefix,
suffix=".fits.gz" if gzipped else ".fits")
if gzipped:
gzf = gzip.GzipFile(mode='wb', fileobj=pbf)
pb.save(gzf, update_timestamp=False)
return gzf, filename
else:
pb.save(pbf, update_timestamp=False)
return pbf, filename
else:
return pb
# In[8]:
print pb.content
# We can now test-drive the blackbody lookup table we just created. For this we will use a low-level `Passband` class method that computes normal emergent passband intensity, `Inorm()`. For the sake of simplicity, we will turn off limb darkening by setting `ld_func` to `'linear'` and `ld_coeffs` to `'[0.0]'`:
# In[9]:
print pb.Inorm(Teff=5772, atm='blackbody', ld_func='linear', ld_coeffs=[0.0])
# Let us now plot a range of temperatures, to make sure that normal emergent passband intensities do what they are supposed to do. While at it, let us compare what we get for the Johnson:V passband.
# In[10]:
jV = phoebe.get_passband('Johnson:V')
teffs = np.linspace(5000, 8000, 100)
plt.xlabel('Temperature [K]')
plt.ylabel('Inorm [W/m^2/A]')
plt.plot(teffs,
pb.Inorm(teffs, atm='blackbody', ld_func='linear', ld_coeffs=[0.0]),
label='mypb')
plt.plot(teffs,
jV.Inorm(teffs, atm='blackbody', ld_func='linear', ld_coeffs=[0.0]),
label='jV')
plt.legend(loc='lower right')
plt.show()
# This makes perfect sense: Johnson V transmission function is wider than our boxed transmission function, so intensity in the V band is larger the lower temperatures. However, for the hotter temperatures the contribution to the UV flux increases and our box passband with a perfect transmission of 1 takes over.
# Computing Castelli & Kurucz (2004) response
#!/usr/bin/env python3
# -*- coding: utf-8 -*-
"""
Created on Sat Nov 9 16:18:03 2019
@author: dyz
"""
import phoebe
from phoebe import u
import numpy as np
import matplotlib.pyplot as plt
logger = phoebe.logger(clevel='WARNING')
kepler = phoebe.get_passband('Kepler:mean')
tess = phoebe.get_passband('TESS:default')
#calculate the two passband flux
teffs = np.linspace(3500, 8000, 100)
fig=plt.figure()
plt.xlabel('Temperature [K]')
plt.ylabel('Inorm [W/m^2/A]')
plt.plot(teffs, kepler.Inorm(teffs, atm='blackbody', ld_func='linear', ld_coeffs=[0.0]), label='Kepler')
plt.plot(teffs, tess.Inorm(teffs, atm='blackbody', ld_func='linear', ld_coeffs=[0.0]), label='TESS')
plt.legend(loc='lower right')
plt.savefig("two_passband_flux.eps")
#plt.show()
"""
