In [1]:

    

# Makes print and division act like Python 3
from __future__ import print_function, division

# Import the usual libraries
import numpy as np
import matplotlib
import matplotlib.pyplot as plt
import matplotlib.patches as mpatches

# Enable inline plotting
%matplotlib inline

from IPython.display import display, Latex, clear_output
from matplotlib.backends.backend_pdf import PdfPages


    

In [2]:

    

import pynrc
from pynrc import nrc_utils
from pynrc.nrc_utils import S, source_spectrum

pynrc.setup_logging('WARNING', verbose=False)


    

    




[     pynrc:INFO]   jwst_backgrounds is not installed and will not be used for bg estimates.

In [3]:

    

# Observation Definitions
from pynrc.nb_funcs import make_key, obs_wfe, obs_optimize
from pynrc.nb_funcs import model_info, disk_rim_model

# Functions to run a series of operations
from pynrc.nb_funcs import do_opt, do_contrast, do_gen_hdus, do_sat_levels

# Plotting routines
from pynrc.nb_funcs import plot_contrasts, plot_contrasts_mjup, planet_mags, plot_planet_patches
from pynrc.nb_funcs import update_yscale, do_plot_contrasts, do_plot_contrasts2
from pynrc.nb_funcs import plot_hdulist, plot_images, plot_images_swlw


    

In [4]:

    

# Various Bandpasses
bp_v = S.ObsBandpass('v')
bp_k = pynrc.bp_2mass('k')
bp_w1 = pynrc.bp_wise('w1')
bp_w2 = pynrc.bp_wise('w2')


    

In [5]:

    

#                source,      dist, age, sptype,  vmag kmag  W1   W2
args_sources = [('MWC 758',    160,   5, 'A5V',    8.3, 5.7, 4.6, 3.5)]

ref_sources = args_sources


    

In [6]:

    

# Directory housing VOTables 
# http://vizier.u-strasbg.fr/vizier/sed/
votdir = 'votables/'

# Directory to save plots and figures
outdir  = 'YSOs/'


    

In [7]:

    

# List of filters
args_filter = [('F187N',       None,       None),
               ('F200W',       None,       None),
               ('F405N',       None,       None),
               ('F410M',       None,       None),]

filt_keys = []
for filt,mask,pupil in args_filter:
    filt_keys.append(make_key(filt, mask=mask, pupil=pupil))


    

In [8]:

    

# Fit spectrum to SED photometry
i=0
name_sci, dist_sci, age_sci, spt_sci, vmag_sci, kmag_sci, w1_sci, w2_sci = args_sources[i]
vot = votdir + name_sci.replace(' ' ,'') + '.vot'

mag_sci, bp_sci = vmag_sci, bp_v
args = (name_sci, spt_sci, mag_sci, bp_sci, vot)
src = source_spectrum(*args)

src.fit_SED(use_err=False, robust=False, wlim=[1,10], IR_excess=True)

# Final source spectrum
sp_sci = src.sp_model


    

    




[6.89562121e-02 3.83155695e+03 2.00704053e+00]

In [9]:

    

# Do the same for the reference source
name_ref, spt_ref, sp_ref = name_sci, spt_sci, sp_sci


    

In [10]:

    

cols = plt.rcParams['axes.prop_cycle'].by_key()['color']

# Plot spectra 
fig, axes = plt.subplots(1,2, figsize=(14,4.5))

ax = axes[0]
src.plot_SED(ax=axes[0], xr=[0.5,30])
ax.set_title('Science SED -- {} ({})'.format(name_sci, spt_sci))
# ax.set_xscale('linear')
# ax.xaxis.set_minor_locator(AutoMinorLocator())


ax = axes[1]
xr = [1,6]

bp = pynrc.read_filter(*args_filter[-1])
sp = sp_sci
w = sp.wave / 1e4
o = S.Observation(sp, bp, binset=bp.wave)
sp.convert('photlam')
f = sp.flux / sp.flux[(w>xr[0]) & (w<xr[1])].max()

ind = (w>=xr[0]) & (w<=xr[1])
ax.plot(w[ind], f[ind], lw=1, label=sp.name)
ax.set_ylabel('Normalized Flux (photons/s/wave)')
sp.convert('flam')

ax.set_xlim(xr)
ax.set_xlabel(r'Wavelength ($\mu m$)')
ax.set_title('{} Spectrum and Bandpasses'.format(sp_sci.name))

# Overplot Filter Bandpass
ax2 = ax.twinx()
for i, af in enumerate(args_filter):
    bp = pynrc.read_filter(*af)
    ax2.plot(bp.wave/1e4, bp.throughput, color=cols[i+1], label=bp.name+' Bandpass')
ax2.set_ylim([0,ax2.get_ylim()[1]])
ax2.set_xlim(xr)
ax2.set_ylabel('Bandpass Throughput')

ax.legend(loc='upper left')
ax2.legend(loc='upper right')

fig.tight_layout()
fig.savefig(outdir+'{}_SED.pdf'.format(name_sci.replace(' ','')))


    

In [11]:

    

fig, ax = plt.subplots(1,1, figsize=(14,6))

xr = [2.5,5.5]
for mass in [1,5,10,15]:
    pl = nrc_utils.planets_sb12(atmo='cf1s', mass=mass, age=5, distance=140)
    sp = pl.export_pysynphot(fluxout='photlam')
    
    ind = (sp.wave>xr[0]*1e4) & (sp.wave<xr[1]*1e4)
    ax.plot(sp.wave[ind]/1e4, sp.flux[ind]/sp.flux[ind].max())



filters = ['F182M', 'F210M', 'F200W', 'F360M', 'F356W', 'F410M', 'F430M', 'F444W']
filters = ['F444W', 'F360M', 'F410M', 'F430M']
ax2 = ax.twinx()
for i, f in enumerate(filters):
    bp = pynrc.read_filter(f, module='A')
    ax2.plot(bp.wave/1e4, bp.throughput,label=bp.name+' Bandpass', lw=3)
    
    flux_vals = []
    for mass in [1,5,10,15]:
        pl = nrc_utils.planets_sb12(mass=mass, age=5, distance=140)
        sp = pl.export_pysynphot(fluxout='photlam')
        o = S.Observation(sp, bp, binset=bp.wave, force='taper')
        flux_vals.append(o.effstim('counts'))
    print(f, flux_vals)
    
# filters = ['J', 'H', 'K']
# for i, f in enumerate(filters):
#     bp = pynrc.bp_2mass(f)
#     ax2.plot(bp.wave/1e4, bp.throughput,label=bp.name+' Bandpass', lw=3, ls='--')
    
#     flux_vals = []
#     for mass in [1,5,10,15]:
#         pl = nrc_utils.planets_sb12(mass=mass, age=5, distance=140)
#         sp = pl.export_pysynphot(fluxout='photlam')
#         o = S.Observation(sp, bp, binset=bp.wave)
#         flux_vals.append(o.effstim('counts'))
#     print(f, flux_vals)
    
ax2.set_ylim([0,ax2.get_ylim()[1]])
ax2.set_xlim(xr)
ax2.set_ylabel('Bandpass Throughput')


fig.tight_layout()


    

    




F444W [266.5101591594304, 2015.1648587927707, 3750.487483684146, 7059.4016158984905]
F360M [12.292336501362836, 571.4020147616723, 1727.0110292273944, 4479.147132959256]
F410M [97.98584633024866, 1116.8829358649198, 2189.0956020580425, 4176.6198444352285]
F430M [71.9252009318661, 527.2885403264481, 954.8850076266357, 1723.1682844691823]






    

In [12]:

    

from astropy.io import fits
hdul = fits.open(outdir + 'model_MWC758.fits')

# Data is in million Jy per Steradian
data = hdul[0].data
data_wave = 1.6 # micons
pa_offset = 215

# Arcsec/pixel
pix_asec = 0.0034

# Steradians to square arcsec
sr_to_asec2 = (3600*180/np.pi)**2

# Data in Jy/arcsec^2
data *= (1e9 * pix_asec**2 / sr_to_asec2) # mJy / pixel

# Mask inner disk region
rho = nrc_utils.dist_image(data, pixscale=pix_asec)
data[rho<=0.1] = 0
 
hdul[0].data = nrc_utils.rotate_offset(data, pa_offset, reshape=False)
hdul[0].data = hdul[0].data[:,::-1]

args_disk = (hdul, pix_asec, dist_sci, data_wave, 'mJy/pixel')
#hdul_out = pynrc.obs_nircam.model_to_hdulist(args_disk, sp_sci, bp)

extent = np.array([-1,1,-1,1]) * hdul[0].data.shape[0] * pix_asec / 2
plt.imshow(hdul[0].data*rho**2, extent=extent)
plt.xlim([-1,1])
plt.ylim([-1,1])


    

    
Out[12]:





(-1, 1)






    

In [13]:

    

subsize = 160

# Create a dictionary that holds the obs_hci class for each filter
wfe_drift = 0
obs_dict = obs_wfe(wfe_drift, args_filter, sp_sci, dist_sci, sp_ref=sp_ref, args_disk=args_disk, 
                   wind_mode='WINDOW', subsize=subsize, verbose=False)


    

    




F187N_none_none
F200W_none_none
F405N_none_none
F410M_none_none

In [14]:

    

# if there's a disk input, then we want to remove disk 
# contributions from stellar flux and recompute to make 
# sure total flux counts matches what we computed for 
# sp_sci in previous section to match real photometry
if args_disk is not None:
    for key in filt_keys:
        obs = obs_dict[key]
        
        star_flux = obs.star_flux(sp=sp_sci) # Pass original input spectrum
        disk_flux = obs.disk_hdulist[0].data.sum()
        obs.sp_sci = sp_sci * (1 - disk_flux / star_flux)
        obs.sp_sci.name = sp_sci.name

        print(disk_flux, star_flux, obs.star_flux())

        obs.sp_ref = obs.sp_sci


    

    




52818.11148593956 6107406.608926663 6054588.497440724
1098597.0176610039 127679461.29165992 126580864.27399892
67354.00275425828 7830692.908136831 7763338.905382572
814157.788804585 94744961.76096755 93930803.97216296

In [15]:

    

# Update detector readout
for i, key in enumerate(filt_keys):
    obs = obs_dict[key]

    if 'none' in key:
        pattern, ng, nint_sci, nint_ref = ('RAPID',10,480,480)
    elif ('MASK210R' in key) or ('MASKSWB' in key):
        pattern, ng, nint_sci, nint_ref = ('BRIGHT2',10,20,20)
    else:
        pattern, ng, nint_sci, nint_ref = ('MEDIUM8',10,15,15)

    obs.update_detectors(read_mode=pattern, ngroup=ng, nint=nint_sci)
    obs.nrc_ref.update_detectors(read_mode=pattern, ngroup=ng, nint=nint_ref)
    
#     print(key)
#     print(obs.multiaccum_times)
#     _ = obs.sensitivity(nsig=5, units='vegamag', verbose=True)
#     print('')


    

In [16]:

    

sat_dict = {}

for k in filt_keys:
    print('\n{}'.format(k))
    obs = obs_dict[k]
    
    dsat_asec = do_sat_levels(obs, satval=0.9, plot=False)
    sat_dict[k] = dsat_asec


    

    




F187N_none_none
Sci: MWC 758
  9 saturated pixel at NGROUP=2; Max Well: 4.17
  25 saturated pixel at NGROUP=10; Max Well: 20.83
  Sat Dist NG=2: 0.07 arcsec
Ref: MWC 758
  9 saturated pixel at NGROUP=2; Max Well: 4.16
  24 saturated pixel at NGROUP=10; Max Well: 20.82

F200W_none_none
Sci: MWC 758
  68 saturated pixel at NGROUP=2; Max Well: 80.30
  210 saturated pixel at NGROUP=10; Max Well: 401.50
  Sat Dist NG=2: 0.18 arcsec
Ref: MWC 758
  66 saturated pixel at NGROUP=2; Max Well: 80.29
  201 saturated pixel at NGROUP=10; Max Well: 401.46

F405N_none_none
Sci: MWC 758
  9 saturated pixel at NGROUP=2; Max Well: 7.02
  44 saturated pixel at NGROUP=10; Max Well: 35.10
  Sat Dist NG=2: 0.13 arcsec
Ref: MWC 758
  9 saturated pixel at NGROUP=2; Max Well: 7.02
  44 saturated pixel at NGROUP=10; Max Well: 35.08

F410M_none_none
Sci: MWC 758
  66 saturated pixel at NGROUP=2; Max Well: 84.35
  175 saturated pixel at NGROUP=10; Max Well: 421.75
  Sat Dist NG=2: 0.32 arcsec
Ref: MWC 758
  66 saturated pixel at NGROUP=2; Max Well: 84.30
  169 saturated pixel at NGROUP=10; Max Well: 421.52

In [17]:

    

# Determine contrast curves for various WFE drift values
wfe_list = [0, 1, 2, 5]

nsig = 5
roll = 10

# fk_contrast = ['F444W_none_none', 'F410M_none_none']
curves_dict = do_contrast(obs_dict, wfe_list, filt_keys,
                          nsig=nsig, roll_angle=roll, opt_diff=False, no_ref=True)


    

    




F187N_none_none
F200W_none_none
F405N_none_none
F410M_none_none

In [19]:

    

lin_vals = np.linspace(0.2,0.8,len(wfe_list))
c1 = plt.cm.Reds_r(lin_vals)
c2 = plt.cm.Blues_r(lin_vals)

key1, key2 = ('F410M_none_none', 'F200W_none_none') #filt_keys[-2:][::-1]
lab1 = '{}'.format(obs_dict[key1].filter)
lab2 = '' if key2 is None else '{}'.format(obs_dict[key2].filter)
fig, axes_all = do_plot_contrasts2(key1, key2, curves_dict, nsig, obs_dict, wfe_list, age_sci,
                                   sat_dict=sat_dict, label1=lab1, label2=lab2, c1=c1, c2=c2, 
                                   xr=[0,5], yr=[25,10], yscale2='log', yr2=[3e-2, 100])

fig.subplots_adjust(top=0.8, bottom=0.1 , left=0.05, right=0.95)
fname = "{}_contrast.pdf".format(name_sci.replace(" ", ""))
fig.savefig(outdir+fname)


    

In [19]:

    

# Planet b:
#   L = 4.8 + 12.5 = 17.3
#   M = 4.8 + 11.8 = 16.6

# Add known planets
dL_arr  = np.array([12.5,12.5]) # L-Band mag contrast
Lbp     = pynrc.read_filter('F360M') # Approx L-Band
rth_arr = [(0.617,225),(0.625,0)] # sep (asec), PA
for key in filt_keys:
    obs = obs_dict[key]
    obs.kill_planets()
    
    Kobs = S.Observation(obs.sp_sci, bp_k, binset=bp_k.wave)  
    Lobs = S.Observation(obs.sp_sci, Lbp, binset=Lbp.wave)    
    Lmag_arr = Lobs.effstim('vegamag') + dL_arr
#     print(Kobs.effstim('vegamag'), Lobs.effstim('vegamag'))
#     print(Lobs.effstim('vegamag'), Lmag_arr)
    
    mass_arr = [9,9]
    mdot_arr = [5e-8,5e-8]
    av_arr   = [2,2]
    for i, Lmag in enumerate(Lmag_arr):
        obs.add_planet(rtheta=rth_arr[i], runits='asec', age=5, mass=mass_arr[i], entropy=13, 
                       accr=True, mdot=mdot_arr[i], Av=av_arr[i],
                       renorm_args=(Lmag,'vegamag',Lbp))
        
    pl_mags = []
    for pl in obs.planets:
        sp = obs.planet_spec(**pl)
        renorm_args = pl['renorm_args']
        sp_norm = sp.renorm(*renorm_args)
        sp_norm.name = sp.name
        sp = sp_norm

        o = S.Observation(sp, obs.bandpass, binset=obs.bandpass.wave)
        pl_mags.append(o.effstim('vegamag'))
        
    print('Planet Mags:', key, pl_mags)


    

    




Planet Mags: F187N_none_none [18.74084776859304, 18.74084776859304]
Planet Mags: F200W_none_none [18.277539824614124, 18.277539824614124]
Planet Mags: F405N_none_none [16.81379253906075, 16.81379253906075]
Planet Mags: F410M_none_none [16.827134324534114, 16.827134324534114]

In [20]:

    

# Ideal
wfe_ref = 0
wfe_roll = 0
hdul_dict_ideal = do_gen_hdus(obs_dict, filt_keys, wfe_ref, wfe_roll, no_ref=False, opt_diff=False,
                              oversample=4, PA1=0, PA2=0, exclude_noise=True)


    

    




F187N_none_none
F200W_none_none
F405N_none_none
F410M_none_none

In [21]:

    

# Roll Subtracted
wfe_ref = 0
wfe_roll = 1
hdul_dict = do_gen_hdus(obs_dict, filt_keys, wfe_ref, wfe_roll, no_ref=True, opt_diff=False,
                        oversample=4, PA1=-5, PA2=5)


    

    




F187N_none_none
F200W_none_none
F405N_none_none
F410M_none_none

In [22]:

    

fk_images = [
    'F187N_none_none',
    'F200W_none_none',
    'F405N_none_none',
    'F410M_none_none',
]

fk_images = filt_keys


    

In [36]:

    

from copy import deepcopy
fig, axes_arr = plt.subplots(2,4, figsize=(14,6.3))

xylim = 1
xr = yr = np.array([-1,1])*xylim

axes = axes_arr[0]
for i, k in enumerate(fk_images):
    ax = axes[i]
    hdul = deepcopy(hdul_dict_ideal[k])

    # Mask out inner region
    mask_rad = 0.2
    rho = nrc_utils.dist_image(hdul[0].data, pixscale=hdul[0].header['PIXELSCL'])
#     hdul[0].data[rho<=mask_rad] = 0
    
    hdul[0].data = hdul[0].data * rho**2
    
    vmax = np.nanmax(hdul[0].data[(rho>mask_rad) & (rho<xylim)])
    plot_hdulist(hdul, ax=ax, xr=xr, yr=yr, vmax=vmax, cb_label='', interpolation='sinc')
    ax.set_title('Ideal -- {} ($r^2$)'.format(obs_dict[k].filter))

axes = axes_arr[1]
for i, k in enumerate(fk_images):
    ax = axes[i]
    hdul = deepcopy(hdul_dict[k])
    
    # Saturation radius
    sat_rad = sat_dict[k]
    
    # Mask out inner region
    mask_rad = np.max([sat_rad, 0.25])

    rho = nrc_utils.dist_image(hdul[0].data, pixscale=hdul[0].header['PIXELSCL'])
    vmax = np.nanmax(hdul[0].data[(rho>mask_rad) & (rho<xylim)])
    hdul[0].data[rho<=mask_rad] = 0

    plot_hdulist(hdul, ax=ax, xr=xr, yr=yr, vmin=0, vmax=vmax, cb_label='', interpolation='sinc')
    ax.set_title('Roll Sub (' + '$\Delta$' + 'WFE = {} nm)'.format(wfe_roll))
    

# Location of planet
for pl in obs.planets:
    loc = (np.array(pl['xyoff_pix'])) * obs.pix_scale
    for ax in axes_arr.flatten():
        circle = matplotlib.patches.Circle(loc, radius=xylim/10., lw=1, edgecolor='red', facecolor='none')
        ax.add_artist(circle);
        
for axes in axes_arr:
    for i, ax in enumerate(axes):
        if i>0: ax.set_ylabel('')
for ax in axes_arr[0]:
    ax.set_xlabel('')
            

# Title
dist = obs.distance
age_str = 'Age = {:.0f} Myr'.format(age_sci)
dist_str = 'Distance = {:.1f} pc'.format(dist)
title_str = '{} ({}, {})'.format(name_sci,age_str,dist_str)

fig.suptitle(title_str, fontsize=16);

fig.tight_layout()
fig.subplots_adjust(top=0.92)

fname = "{}_images.pdf".format(name_sci.replace(" ", ""))
fig.savefig(outdir+fname)


    

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