def mkfluxstar(fluxfile, gratcode): import pdb import numpy as np import matplotlib.pyplot as plt from matplotlib.widgets import Cursor from astropy.io import fits from tmath.wombat.get_screen_size import get_screen_size from tmath.wombat.getmswave import getmswave from tmath.wombat.inputter_single import inputter_single from tmath.wombat.inputter import inputter from tmath.wombat.womscipyrebin import womscipyrebin from tmath.pydux.obs_extinction import obs_extinction from tmath.pydux.wave_telluric import wave_telluric from tmath.pydux.fitspl import fitspl from tmath.pydux.finalscaler import finalscaler from tmath.pydux.abcalc import abcalc from tmath.pydux.pacheck import pacheck screen_width, screen_height = get_screen_size() plt.ion() screenpos = '+{}+{}'.format(int(screen_width * 0.2), int(screen_height * 0.05)) fig = plt.figure() fig.canvas.manager.window.wm_geometry(screenpos) fig.canvas.set_window_title('Flux Star') fig.set_size_inches(18, 12) # turns off key stroke interaction fig.canvas.mpl_disconnect(fig.canvas.manager.key_press_handler_id) # this should bring the window to the top, but it doesn't wm = plt.get_current_fig_manager() #fig.canvas.manager.window.attributes('-topmost', 1) blah = wm.window.attributes('-topmost', 1) #plt.pause(0.2) #fig.canvas.manager.window.attributes('-topmost', 0) blah = wm.window.attributes('-topmost', 0) #extinction terms from Allen, 3rd edition extwave= [2400.,2600.,2800.,3000.,3200.,3400.,3600.,3800., \ 4000.,4500.,5000.,5500.,6000.,6500.,7000.,8000., \ 9000.,10000.,12000.,14000.] extvals=[68.0,89.0,36.0,4.5,1.30,0.84,0.68,0.55,0.46,0.31, \ 0.23,0.195,0.170,0.126,0.092,0.062,0.048,0.039, \ 0.028,0.021] fitsfile = fits.open(fluxfile) rawdata = fitsfile[0].data head = fitsfile[0].header num_apertures = rawdata.shape[1] wavearr = np.zeros((rawdata.shape[2], rawdata.shape[1])) objectname = head['OBJECT'] airmass = float(head['AIRMASS']) exptime = float(head['EXPTIME']) head = pacheck(head) if (exptime < 1): exptime = 1. observat = head['OBSERVAT'].strip().lower() sitefactor = obs_extinction(observat) for i in range(0, num_apertures): wavearr[:, i] = getmswave(head, i) if (wavearr[-1, 0] < 3000): print('************************************************') print('Spectrum not wavelength calibrated---bailing out') print('************************************************') sys.exit(1) ap_choice = -1 if (num_apertures != 1): axarr = fig.subplots(num_apertures, sharex=True) fig.subplots_adjust(hspace=0) for i in range(0, num_apertures): x = wavearr[:, i] y = rawdata[0, i, :] axarr[i].clear() plt.pause(0.01) axarr[i].plot(x, y, drawstyle='steps-mid') axarr[i].set_ylabel('Aperture {}'.format(i)) plt.pause(0.01) while (ap_choice < 0) or (ap_choice > num_apertures - 1): ap_choice = inputter( 'Which aperture do you want to use for the flux star? ', 'int', False) fig.clf() else: ap_choice = 0 ymin, ymax = finalscaler(rawdata[0, ap_choice, :]) fig.clf() x1 = wavearr[:, ap_choice] y1 = rawdata[1, ap_choice, :] y0 = rawdata[0, ap_choice, :] plt.plot(x1, y1, drawstyle='steps-mid', color='r') plt.plot(x1, y0, drawstyle='steps-mid', color='k') plt.pause(0.01) plt.ylim([ymin, ymax]) plt.pause(0.01) print('\nPlotting optimal as black, normal as red') extract = inputter_single( 'Do you want to use (n)ormal or (o)ptimal extraction? ', 'no') if (extract == 'o'): star = rawdata[0, ap_choice, :] else: star = rawdata[1, ap_choice, :] # fix IRAF weirdness where data can go negative in dispcor interpolation star[np.where(star < 0)] = 0.01 wave = wavearr[:, ap_choice] extinction = womscipyrebin(extwave, extvals, wave) extfactor = np.exp(extinction * sitefactor * airmass) star = star * extfactor abcurve = abcalc(wave, objectname) wdata = 10.0**(0.4 * abcurve) fstar = star * wdata / exptime print('Now fit the continuum manually\n') plt.clf() ax = fig.add_subplot(111) cursor = Cursor(ax, useblit=True, color='k', linewidth=1) airlimit = 1.5 splineresult = fitspl(wave, np.log10(fstar), (airmass > airlimit), fig) splineresult = 10**(splineresult) plt.cla() plt.plot(wave, splineresult, drawstyle='steps-mid') plt.pause(0.01) delkeylist=['WAT0_001', 'WAT1_001', 'WAT2_001', 'WAT0_002', \ 'WAT1_002', 'WAT2_002', 'WAT3_001', 'WAT2_003', \ 'CTYPE1', 'CTYPE2', 'CTYPE3', 'CD1_1', 'CD2_2', \ 'CD3_3', 'LTM1_1', 'LTM2_2', 'LTM3_3', 'WCSDIM'] for k in delkeylist: try: head.remove(k) except KeyError: pass head.set('CRPIX1', 1) head.set('CRVAL1', wave[0]) head.set('CDELT1', wave[1] - wave[0]) head.set('CTYPE1', 'LINEAR') head.set('FLUXFILE', fluxfile) outfile = 'fluxstar' + gratcode + '.fits' print('Writing data to {}'.format(outfile)) outhdu = fits.PrimaryHDU(splineresult) hdul = fits.HDUList([outhdu]) hdul[0].header = head.copy() hdul.writeto(outfile, overwrite=True) print('mkfluxstar') print(fluxfile, gratcode) return
def final(objectlist, gratcode, secondord, gratcode2, user): import matplotlib.pyplot as plt from matplotlib import gridspec import numpy as np from datetime import datetime import os, pdb import inspect import glob import math from astropy.io import fits from astropy import units as u from astropy.coordinates import SkyCoord # from astropy.time import Time from tmath.wombat.get_screen_size import get_screen_size from tmath.wombat.getmswave import getmswave from tmath.wombat.inputter_single import inputter_single from tmath.wombat.inputter import inputter from tmath.wombat.womcatfinal import womcatfinal from tmath.pydux.scipyrebinsky import scipyrebinsky from tmath.wombat.yesno import yesno from tmath.wombat.womashrebin import womashrebin from tmath.wombat.wominterpofluxconserving import interpo_flux_conserving from tmath.wombat.womspectres import spectres from tmath.pydux.getfitsfile import getfitsfile from tmath.pydux.pacheck import pacheck from tmath.pydux.jdcnv import jdcnv from tmath.pydux.baryvel import baryvel from tmath.pydux.finalscaler import finalscaler from tmath.pydux.envelope import envelope from tmath.pydux.congrid import congrid from tmath.pydux.xcor import xcor from tmath.pydux.telluric_remove import telluric_remove from tmath.pydux.waveparse import waveparse from tmath.pydux.parsehourangle import parsehourangle from tmath.pydux import RADEG plt.ion() screen_width, screen_height = get_screen_size() screenpos = '+{}+{}'.format(int(screen_width * 0.2), int(screen_height * 0.05)) fig = plt.figure() fig.canvas.manager.window.wm_geometry(screenpos) fig.canvas.set_window_title('Final Reductions') fig.set_size_inches(8, 5) # turns off key stroke interaction fig.canvas.mpl_disconnect(fig.canvas.manager.key_press_handler_id) # this should bring the window to the top, but it doesn't # wm=plt.get_current_fig_manager() #fig.canvas.manager.window.attributes('-topmost', 1) # blah=wm.window.attributes('-topmost', 1) #plt.pause(0.2) #fig.canvas.manager.window.attributes('-topmost', 0) # blah=wm.window.attributes('-topmost', 0) bstarfits = fits.open('bstar' + gratcode + '.fits') bstarstar = bstarfits[0].data bstarhead = bstarfits[0].header bstarwavezero = float(bstarhead['CRVAL1']) bstarwavedelt = float(bstarhead['CDELT1']) bstarwave = np.arange(len(bstarstar)) * bstarwavedelt + bstarwavezero bstarairmass = float(bstarhead['AIRMASS']) bstarname = bstarhead['OBJECT'] try: bstarnum = int(bstarhead['OBSNUM']) except KeyError: bstarnum = 0 if (secondord): bstarfits2 = fits.open('bstarstar' + gratcode2 + '.fits') bstarstar2 = bstarfits[0].data bstarhead2 = bstarfits[0].header bstarwavezero2 = float(bstarhead2['CRVAL1']) bstarwavedelt2 = float(bstarhead2['CDELT1']) bstarwave2 = np.arange( len(bstarstar2)) * bstarwavedelt2 + bstarwavezero2 bstarairmass2 = float(bstarhead2['AIRMASS']) bstarname2 = bstarhead2['OBJECT'] try: bstarnum2 = int(bstarhead2['OBSNUM']) except KeyError: bstarnum2 = 0 observat = bstarhead['OBSERVAT'].strip().lower() #reduxdir=os.environ['PY_REDUX'] reduxdir = inspect.getfile(xcor) reduxdir = reduxdir.rsplit('/', 1)[0] + '/' kecksky=['keck','gemini-north','gemini-n','gemini-south','gemini-s', \ 'soar','ctio','vlt','lco','lco-imacs','lapalma'] licksky = ['lick', 'kpno', 'flwo', 'mmto', 'sso'] if (observat in kecksky): mskyfile = reduxdir + 'kecksky.fits' elif (observat in licksky): mskyfile = reduxdir + 'licksky.fits' else: print('\nCannot find mastersky file and observatory unknown\n') mskyfile = getfitsfile('master sky', '.fits') print('Using {} as master sky'.format(mskyfile)) mskyfits = fits.open(mskyfile) mskydata = mskyfits[0].data mskyhead = mskyfits[0].header mskywavezero = float(mskyhead['CRVAL1']) mskywavedelt = float(mskyhead['CDELT1']) mskywave = np.arange(len(mskydata)) * mskywavedelt + mskywavezero if (np.abs(np.mean(mskydata)) < 1e-7): mskydata = mskydata * 1e15 print('\nHello {}\n'.format(user)) lat_dict = { 'keck': 19.8283, 'gemini-north': 19.8238, 'gemini-south': -30.228, 'gemini-n': 19.8238, 'gemini-s': -30.228, 'soar': -30.228, 'kpno': 31.9633, 'lick': 37.3414, 'palomar': 33.35611, 'mcdonald': 30.6717, 'flwo': 31.681, 'mmto': 31.688, 'sso': -31.2734, 'vlt': -24.6254, 'lco': -29.01, 'lco-imacs': -29.01, 'lapalma': 28.75833, 'ctio': -30.16894 } infile = open(objectlist, 'r') objname = '' secondtime = False seconddone = False for inputfile in infile: inputfile = inputfile.strip() if ('.fits' not in inputfile): inputfile = inputfile + '.fits' multifits = fits.open('c' + gratcode + inputfile) multispec = multifits[0].data mshead = multifits[0].header num_apertures = multispec.shape[1] num_bands = multispec.shape[0] wavearr = np.zeros((multispec.shape[2], multispec.shape[1])) if (secondord): multifits2 = fits.open('c' + gratcode2 + inputfile) multispec2 = multifits2[0].data mshead2 = multifits2[0].header pacheck(mshead) objectname = mshead['OBJECT'] print('The object is: {}'.format(objectname)) observat = mshead['OBSERVAT'].strip().lower() airmass = float(mshead['AIRMASS']) if (airmass < 1): airmass = 1.0 stringra = mshead['RA'] stringdec = mshead['DEC'] geminilist = ['gemini-north', 'gemini-south', 'gemini-n', 'gemini-s'] if (observat) in geminilist: ra = float(stringra) dec = float(stringdec) else: coords = SkyCoord(stringra, stringdec, unit=(u.hourangle, u.deg)) ra = coords.ra.deg dec = coords.dec.deg ra = ra / RADEG dec = dec / RADEG haheader = mshead['HA'] ha = parsehourangle(haheader) ha = ha * (360. / 24.) / RADEG if (observat in lat_dict): latitude = lat_dict[observat] else: print('Observatory Unknown!!!!!!!') latitude = 0.0 latitude = latitude / RADEG # Get Julian date and Earth's velocity #epoch=float(mshead['EPOCH']) date = mshead['DATE-OBS'].strip() # get year,month,day from ISO Y2K format YYYY-MM-DDThh:mm:ss.ssss # the time following T is optional, so we get T from UTMIDDLE if (date[4] == '-'): year = int(date.split('-')[0]) month = int(date.split('-')[1]) day = int(date.split('-')[2].split('T')[0]) printdate = '{}{:02d}{:02d}'.format(year, month, day) else: # Old date format DD/MM/YY year = int(date[6:8]) month = int(date[3:5]) day = int(date[0:2]) # try to catch old format written after 2000 # good until 2050, by which time no one should # be doing this if (year > 50): year = year + 1900 else: year = year + 2000 printdate = '{}{:02d}{:02d}'.format(year, month, day) try: ut = mshead['UTMIDDLE'].strip() except KeyError: ut = mshead['UT'].strip() if ('T' in ut): ut = ut.split('T')[1] # some UT/UTMIDDLE values are ISO format hour = int(ut.split(':')[0]) minute = int(ut.split(':')[1]) second = float(ut.split(':')[2]) julian = jdcnv(year, month, day, (hour + (minute / 60.) + (second / 3600.))) vh, vb = baryvel(julian) # Earth's velocity toward object v=vb[0]*np.cos(dec)*np.cos(ra) + vb[1]*np.cos(dec)*np.sin(ra) \ + vb[2]*np.sin(dec) # Correct for earth's rotation. # Note that this isn't strictly correct because ha is set to # the beginning of the observation, while it really should be # the middle. But this is a small difference and doesn't affect # the results in any way that we would notice... v = v - (0.4651 * np.cos(latitude) * np.sin(ha) * np.cos(dec)) print( '\nThe velocity of the Earth toward the target is {} km/s'.format( v)) print('\nThere are {} apertures in the spectrum.\n'.format( num_apertures)) # clean up header """ delkeylist=['WAT0_001', 'WAT1_001', 'WAT2_001', 'WAT0_002', \ 'WAT1_002', 'WAT2_002', 'WAT3_001', 'WAT2_003', \ 'CTYPE1', 'CTYPE2', 'CTYPE3', 'CD1_1', 'CD2_2', \ 'CD3_3', 'LTM1_1', 'LTM2_2', 'LTM3_3', 'WCSDIM'] for k in delkeylist: try: mshead.remove(k) except KeyError: pass """ waveb = None waver = None bshift = None for i in range(0, num_apertures): # plt.close() # fig=plt.figure() # plt.plot(multispec[0,i,:], drawstyle='steps-mid',color='r') # plt.plot(multispec[1,i,:], drawstyle='steps-mid',color='k') # plt.xlim(1750,1900) # plt.pause(0.01) # print('Check plot') # answer=yesno('y') print('\nAperture {}:'.format(i + 1)) wave = getmswave(mshead, i) print(wave[0], wave[-1]) wdelt = wave[1] - wave[0] mean = np.mean(multispec[0, i, :]) ymin, ymax = finalscaler(multispec[0, i, :]) # plt.clf() gs = gridspec.GridSpec(2, 1, height_ratios=[4, 1]) ax0 = plt.subplot(gs[0]) ax1 = plt.subplot(gs[1]) fig.subplots_adjust(hspace=0) ax0.plot(wave, multispec[1, i, :], drawstyle='steps-mid', color='r') ax0.plot(wave, multispec[0, i, :], drawstyle='steps-mid', color='k') # ax0.plot(multispec[0,i,:],multispec[2,i,:],drawstyle='steps-mid',color='r') # ax0.plot(multispec[0,i,:],multispec[1,i,:],drawstyle='steps-mid',color='k') plt.pause(0.01) ax0.set_ylim((ymin, ymax)) ax1.semilogy(wave,np.abs(multispec[1,i,:]-multispec[0,i,:])/mean, \ drawstyle='steps-mid',color='k') ax0.set_ylabel('Flux') ax1.set_ylabel('Log of fractional residuals') ax1.set_xlabel('Wavelength') plt.pause(0.01) print('\nPlotting optimal as black, normal as red\n') extract = inputter_single( 'Do you want to use the (n)ormal or the (o)ptimal extraction? ', 'no') if (extract == 'o'): object = multispec[0, i, :] extractcode = 'optimal' if (secondord): object2 = multispec2[0, i, :] else: object = multispec[1, i, :] extractcode = 'normal' if (secondord): object2 = multispec2[1, i, :] skyband = 2 if (num_bands == 2): skyband = 1 if (num_bands > 3): sigma = multispec[3, i, :] else: sigma = np.sqrt(multispec[skyband, i, :]) if (np.abs(np.mean(object)) < 1e-7): print('\nScaling data up by 10^15\n') object = object * 1.e15 sigma = sigma * 1.e15 if (secondord): if (num_bands > 3): sigma2 = multispec2[3, i, :] else: sigma2 = np.sqrt(multispec2[skyband, i, :]) if (np.abs(np.mean(object)) < 1e-7): object2 = object2 * 1.e15 sigma2 = sigma2 * 1.e15 nandslist = ['gemini-n', 'gemini-s', 'lco-imacs'] if (observat in nandslist): skyfile = inputfile.replace('tot', 'sky') skyfits = fits.open(skyfile) sky = skyfits[0].data[2, 0, :] else: sky = multispec[skyband, i, :] envelope_size = 25 mx, mn = envelope(sky, envelope_size) skycont = congrid(mn, (len(sky), ), minusone=True) test_sky = sky sky = sky - skycont if (np.abs(np.mean(sky)) < 1.e-7): sky = sky * 1.e15 print(len(mskywave), len(mskydata)) msky = scipyrebinsky(mskywave, mskydata, wave) xfactor = 10 maxlag = 200 if 'kast' in mshead.get('VERSION', ''): shift = xcor(msky[50:-50], sky[50:-50], xfactor, maxlag) else: shift = xcor(msky, sky, xfactor, maxlag) angshift = shift * wdelt print('wdeltf', wdelt) print('The x-cor shift in Angstroms is {}'.format(angshift)) wave = wave + angshift #check to make sure signs are right skyshiftdone = False npixsky2 = len(sky) // 2 msky_max = np.max(msky[npixsky2 - 1:]) sky_max = np.max(sky[npixsky2 - 1:]) scale = sky_max / msky_max plt.close() fig = plt.figure(figsize=[8, 5]) fig.subplots_adjust(hspace=0) while (not skyshiftdone): axarr = fig.subplots(2) waveplus = wave - angshift if not secondtime: axarr[0].plot(waveplus[0:npixsky2],scale*msky[0:npixsky2], \ drawstyle='steps-mid',color='k') axarr[0].plot(wave[0:npixsky2],sky[0:npixsky2], \ drawstyle='steps-mid',color='r') axarr[1].plot(waveplus[npixsky2-1:],scale*msky[npixsky2-1:], \ drawstyle='steps-mid',color='k') axarr[1].plot(wave[npixsky2-1:],sky[npixsky2-1:], \ drawstyle='steps-mid',color='r') plt.pause(0.01) print('\nBlack spectrum = master sky') print( 'Red spectrum = object sky shifted to match master sky' ) print('Is this ok?') answer = yesno('y') if (answer == 'n'): wave = wave - angshift angshift = inputter( 'Enter desired shift in Angstroms: ', 'float', False) wave = wave + angshift else: skyshiftdone = True else: wave = wave + angshift skyshiftdone = True plt.close() # B star removal bstarpass = bstarstar bobj, bsig, bangshift=telluric_remove(bstarwave,bstarpass, bstarairmass, wave, \ object, airmass, sigma, object, shift=bshift) # bobj, bsig, bangshift=telluric_remove(bstarwave,bstarpass, bstarairmass, wave, \ # test_sky, airmass, sigma, object) bshift = bangshift if (secondord): bobj2, bsig2, bangshift2 =telluric_remove(bstarwave2,bstarpass2, bstarairmass2, \ wave, object2, airmass, sigma2) print('\nRemoving redshift due to motion of Earth...') z = -1 * v / 2.99792458e5 wave = wave / (1 + z) # rebin fig = plt.figure() axarr = fig.subplots(1, 2) ymin, ymax = finalscaler(bobj[0:100]) axarr[0].plot(wave[0:100], bobj[0:100], drawstyle='steps-mid') axarr[0].set_xlabel('Wavelength') axarr[0].set_ylabel('Flux') #axarr[0].set_ylim((ymin,ymax)) if (secondtime): axarr[0].plot([wavesave0, wavesave0], [ymin, ymax], color='r') plt.pause(0.01) ymin, ymax = finalscaler(bobj[-100:]) axarr[1].plot(wave[-100:], bobj[-100:], drawstyle='steps-mid') axarr[1].set_xlabel('Wavelength') axarr[1].set_ylabel('Flux') try: axarr[1].set_ylim((ymin, ymax)) except ValueError: bobj_median = np.nanmedian(bobj) axarr[1].set_ylim((bobj_median / 10., bobj_median * 10.)) if (secondtime): axarr[1].plot([wavesaven, wavesaven], [ymin, ymax], color='r') newdelt = 0.0 plt.pause(0.01) print('\nCurrent A/pix is {}'.format(wave[1] - wave[0])) if (secondtime): print('\nPrevious resolution choice: {}'.format(deltsave)) else: deltsave = 0.0 newdelt = wave[1] - wave[0] # while (newdelt <= 0) or (newdelt > wave[-1]): # print('Rebin to how many Angstroms per pixel? ') # newdelt=inputter(' <CR> selects previous choice: ','float',True,deltsave) # if (newdelt <= 0) or (newdelt > wave[-1]): # print('Need positive resoution and smaller than the') # print('entire spectrum. Try again') print('\nCurrent range: {} {}'.format(wave[0], wave[-1])) if (secondtime): print('\nPrevious selection was {} {} (marked in red on plot)'. format(wavesave0, wavesaven)) print('\n<CR> selects previous choice\n') else: wavesave0 = 0.0 wavesaven = 0.0 print('Enter the new wavelength range desired: ') waveb, waver = waveparse(wave, wavesave0, wavesaven) newbin = (waver - waveb) / newdelt + 1.0 #should stay the same now # frac,whole=np.modf(newbin) # if (frac > 0.000001): # testwave=newdelt*whole+waveb # print('Closest match is: {} to {}'.format(waveb,testwave)) # print('Would you like this wavelength range?') # answer=yesno('y') # if (answer == 'y'): # waver=testwave wave_locs = np.where((wave > waveb) & (wave < waver)) # deltsave=newdelt wavesave0 = waveb wavesaven = waver waverange = str(waveb) + ' ' + str(waver) secondtime = True # nwave=np.arange(0,whole)*newdelt + waveb # vartmp=bsig*bsig # olddeltvec=wave-np.roll(wave,1) # olddelt=np.mean(olddeltvec) # nwave = wave # finalobj = bobj # finalvar = bsig**2. # finalsig = bsig #NOT TESTED!!! nwave = wave[wave_locs] print(nwave[0], nwave[-1]) finalobj = bobj[wave_locs] finalvar = bsig[wave_locs]**2. finalsig = bsig[wave_locs] # finalobj=womashrebin(wave,bobj,nwave) # finalvar=womashrebin(wave,vartmp,nwave) # finalsig=np.sqrt(finalvar)*np.sqrt(olddelt/newdelt) #Matt's interpolation algorithm. womashrebin is an unreadable monstrosity. # interp_data = interpo_flux_conserving(wave, bobj, 1./vartmp, waveb, waver, dw=newdelt, testing=False) # interp_wave = np.arange(math.ceil(wave[0])+1., math.floor(wave[-1])-1., dtype=float, step=newdelt) # spectres_data = spectres(interp_wave, wave, bobj, spec_errs=bsig) # trim_range = (interp_data[0] > waveb) & (interp_data[0] < waver) # nwave = interp_data[0][trim_range] # finalobj = interp_data[1][trim_range] # finalvar = 1./interp_data[2][trim_range] # finalsig = np.sqrt(finalvar) suffixes = {} suffixes['ap' + str(i + 1)] = '' if os.path.isfile('../HOST_AP_DATA.txt'): with open('../HOST_AP_DATA.txt') as host_ap_data: h_lines = host_ap_data.readlines() for l in h_lines: suffixes[l.split()[0]] = '_' + l.split()[1] #gonna ignore the second order stuff for now if (secondord): vartmp2 = bsig2 * bsig2 finalobj2 = womashrebin(wave, bobj2, nwave) finalvar2 = womashrebin(wave, vartmp2, nwave) finalsig2 = np.sqrt(finalvar2) * np.sqrt(olddelt / newdelt) if (secondord and not seconddone): finalobj, finalsig, wavebeg, waveend, brscale = secondcat( nwave, finalobj, finalobj2, finalsig, finalsig2, secondtime, wavebeg, waveend, brscale) seconddone = True ymin, ymax = finalscaler(finalobj) plt.close() fig = plt.figure() plt.plot(nwave, finalobj, drawstyle='steps-mid') # plt.plot(spectres_data[0],spectres_data[1],drawstyle='steps-mid', color='green') plt.xlabel('Wavelength') plt.ylabel('Flux') plt.title(objectname) plt.savefig(objectname + '-' + gratcode + '_ap' + str(i + 1) + suffixes['ap' + str(i + 1)] + '.png') plt.show() outputdone = False while (not outputdone): print('\nThe file is: {}'.format(inputfile)) print('The object is: {}'.format(objectname)) print('The DATE-OBS is: {}'.format(date)) print('The aperture is: {}'.format(i + 1)) print('The previous name was: {}'.format(objname)) print('\nEnter the object name for the final fits file: ') # objname=inputter('(UT date and .fits will be added): ','string',False) objname = objectname + '-' + gratcode fname = objname + '-' + printdate + '_ap' + str( i + 1) + suffixes['ap' + str(i + 1)] + '.fits' sname = objname + '-' + printdate + '_ap' + str( i + 1) + suffixes['ap' + str(i + 1)] + '-sigma.fits' outputdone = True if (os.path.isfile(fname)): print('{} already exists!!!!'.format(fname)) print('Do you wish to overwrite it? ') answer = yesno('y') if (answer == 'y'): outputdone = True else: outputdone = True # add to header new_mshead = mshead.copy() new_mshead.set('CRPIX1', 1) new_mshead.set('CRVAL1', nwave[0]) new_mshead.set('CDELT1', nwave[1] - nwave[0]) new_mshead.set('CTYPE1', 'LINEAR') new_mshead.set('W_RANGE', waverange) new_mshead.set('BSTAR_Z', bstarairmass) new_mshead.set('BSTARNUM', bstarnum) new_mshead.set('BSTAROBJ', bstarname) new_mshead.set('BARYVEL', v) new_mshead.set('SKYSHIFT', angshift) new_mshead.set('ATMSHIFT', bangshift) new_mshead.set('EXTRACT', extractcode) new_mshead.set('REDUCER', user) new_mshead.set('RED_DATE', str(datetime.now()).split()[0], 'EPOCH OF REDUCTION') new_mshead.set('OBJECT', objectname) # if (secondord): # new_mshead.set('SECOND', 'yes', 'Second order correction attempted') # new_mshead.set('COMBRANGE',combrange) # new_mshead.set('BSTAR_Z2',bstarairmass2) # new_mshead.set('BSTARNU2', bstarnum2) # new_mshead.set('BSTAROB2', bstarname2) # fluxairmass2=mshead2['FLX2_Z'] # fluxnum2=mshead2['FLX2_NUM'] # fluxname2=mshead2['FLX2_OBJ'] # new_mshead.set('FLX2_Z',fluxairmass2) # new_mshead.set('FLX2_NUM', fluxnum2) # new_mshead.set('FLX2_OBJ', fluxname2) outdata = np.zeros((len(finalobj), 2)) outdata[:, 0] = finalobj.copy() outdata[:, 1] = finalsig.copy() outhdu = fits.PrimaryHDU(outdata) hdul = fits.HDUList([outhdu]) mshead.set('NAXIS2', 2) hdul[0].header = new_mshead.copy() hdul.writeto(fname, overwrite=True) spectxt = objname + '-' + printdate + '_ap' + str( i + 1) + suffixes['ap' + str(i + 1)] + '.flm' spectxt = spectxt.strip() np.savetxt(spectxt, np.transpose([nwave, finalobj.copy(), finalsig.copy()])) hdul.close() print('Do you wish to combine with another spectrum? ') answer = yesno('y') fname_comb = None if (answer == 'y'): plt.close() done = False while (not done): files = glob.glob(objname.split('-')[0] + '*.fits') print(files) for f in files: if objname not in f and ('red' in f or 'blue' in f ) and '_ap' + str(i + 1) in f: inputfile = f inputfile = input( 'Name of fits file to be combined? [{}]: '.format( inputfile)) or inputfile print(inputfile) inputfile = inputfile.strip() if (inputfile == ''): return hop if ('.fits' not in inputfile): inputfile = inputfile + '.fits' try: fitsdata = fits.open(inputfile) except OSError: print('File {} cannot be opened.'.format(inputfile)) else: done = True crval1 = fitsdata[0].header['CRVAL1'] try: wdelt = fitsdata[0].header['CDELT1'] except KeyError: wdelt = 0.0000001 if (wdelt < 0.000001): wdelt = fitsdata[0].header['CD1_1'] try: objectname = fitsdata[0].header['OBJECT'] if (not isinstance(objectname, str)): objectname = inputfile except KeyError: objectname = inputfile data_new = fitsdata[0].data wave_new = np.arange(1, len(data_new) + 1) * wdelt + crval1 if (len(data_new.shape) == 2): var_new = data_new[:, 1] var_new = var_new.astype(float) var_new = var_new * var_new flux_new = data_new[:, 0] flux_new = flux_new.astype(float) else: flux_new = data_new.astype(float) var_new = np.ones(data_new.shape) if 'red' in inputfile: wavecomb, fluxcomb, varcomb = womcatfinal( [nwave, finalobj, finalvar], [wave_new, flux_new, var_new]) nwave = wavecomb finalobj = fluxcomb finalsig = np.sqrt(varcomb) elif 'blue' in inputfile: wavecomb, fluxcomb, varcomb = womcatfinal( [wave_new, flux_new, var_new], [nwave, finalobj, finalvar]) nwave = wavecomb finalobj = fluxcomb finalsig = np.sqrt(varcomb) else: print( "Please include 'blue' or 'red' in filename of spectrum to combine" ) plt.clf() plt.plot(nwave, finalobj, drawstyle='steps-mid') plt.xlabel('Wavelength') plt.ylabel('Flux') plt.title(objectname) plt.savefig(objectname + '_combined_ap' + str(i + 1) + suffixes['ap' + str(i + 1)] + '.png') outputdone = False while (not outputdone): print('\nThe file is: {}'.format(inputfile)) print('The object is: {}'.format(objectname)) print('The DATE-OBS is: {}'.format(date)) print('The aperture is: {}'.format(i + 1)) print('The previous name was: {}'.format(objname)) print('\nEnter the object name for the final fits file: ') # objname=inputter('(UT date and .fits will be added): ','string',False) objname = objectname + '-combined' fname_comb = objname + '-' + printdate + '_ap' + str( i + 1) + suffixes['ap' + str(i + 1)] + '.fits' sname_comb = objname + '-' + printdate + '_ap' + str( i + 1) + suffixes['ap' + str(i + 1)] + '-sigma.fits' outputdone = True if (os.path.isfile(fname)): print('{} already exists!!!!'.format(fname)) print('Do you wish to overwrite it? ') answer = yesno('y') if (answer == 'y'): outputdone = True else: outputdone = True # add to header mshead_combined = new_mshead.copy() mshead_combined.set('CRPIX1', 1) mshead_combined.set('CRVAL1', nwave[0]) mshead_combined.set('CDELT1', nwave[1] - nwave[0]) mshead_combined.set('CTYPE1', 'LINEAR') mshead_combined.set('W_RANGE', waverange) mshead_combined.set('BSTAR_Z', bstarairmass) mshead_combined.set('BSTARNUM', bstarnum) mshead_combined.set('BSTAROBJ', bstarname) mshead_combined.set('BARYVEL', v) mshead_combined.set('SKYSHIFT', angshift) mshead_combined.set('ATMSHIFT', bangshift) mshead_combined.set('EXTRACT', extractcode) mshead_combined.set('REDUCER', user) mshead_combined.set( 'RED_DATE', datetime.now().strftime("%Y-%M-%d %I:%M%p"), 'EPOCH OF REDUCTION') mshead_combined.set('OBJECT', objectname) if (secondord): #not implemented mshead_combined.set('SECOND', 'yes', 'Second order correction attempted') mshead_combined.set('COMBRANGE', combrange) mshead_combined.set('BSTAR_Z2', bstarairmass2) mshead_combined.set('BSTARNU2', bstarnum2) mshead_combined.set('BSTAROB2', bstarname2) fluxairmass2 = mshead2['FLX2_Z'] fluxnum2 = mshead2['FLX2_NUM'] fluxname2 = mshead2['FLX2_OBJ'] mshead_combined.set('FLX2_Z', fluxairmass2) mshead_combined.set('FLX2_NUM', fluxnum2) mshead_combined.set('FLX2_OBJ', fluxname2) outdata = np.zeros((len(finalobj), 2)) outdata[:, 0] = finalobj.copy() outdata[:, 1] = finalsig.copy() outhdu = fits.PrimaryHDU(outdata) hdul = fits.HDUList([outhdu]) mshead_combined.set('NAXIS2', 2) hdul[0].header = mshead_combined.copy() hdul.writeto(fname_comb, overwrite=True) hdul.close() spectxt = objname + '-' + printdate + '_ap' + str( i + 1) + suffixes['ap' + str(i + 1)] + '.flm' spectxt = spectxt.strip() np.savetxt( spectxt, np.transpose([nwave, finalobj.copy(), finalsig.copy()])) is_final = input('Is this a final reduction? [y]/n: ') or 'y' if is_final: if not os.path.isdir('../../final_reductions/'): os.mkdir('../../final_reductions/') os.system('cp ' + fname + ' ' + '../../final_reductions/' + fname) if fname_comb: os.system('cp ' + fname_comb + ' ' + '../../final_reductions/' + fname_comb) print('final') print(objectlist, gratcode, secondord, gratcode2) plt.close() return
def mkbstar(bfile, gratcode): import numpy as np import matplotlib.pyplot as plt from matplotlib.widgets import Cursor from astropy.io import fits from tmath.wombat.get_screen_size import get_screen_size from tmath.wombat.getmswave import getmswave from tmath.wombat.inputter_single import inputter_single from tmath.wombat.inputter import inputter from tmath.wombat.yesno import yesno from tmath.pydux.obs_extinction import obs_extinction from tmath.pydux.wave_telluric import wave_telluric from tmath.pydux.fitspl import fitspl from tmath.pydux.bblo import bblo from tmath.pydux.finalscaler import finalscaler from tmath.pydux.pacheck import pacheck screen_width, screen_height = get_screen_size() plt.ion() screenpos = '+{}+{}'.format(int(screen_width * 0.2), int(screen_height * 0.05)) fig = plt.figure() fig.canvas.manager.window.wm_geometry(screenpos) fig.canvas.set_window_title('B Star') fig.set_size_inches(18, 12) # turns off key stroke interaction fig.canvas.mpl_disconnect(fig.canvas.manager.key_press_handler_id) # this should bring the window to the top, but it doesn't wm = plt.get_current_fig_manager() #fig.canvas.manager.window.attributes('-topmost', 1) blah = wm.window.attributes('-topmost', 1) #plt.pause(0.2) #fig.canvas.manager.window.attributes('-topmost', 0) blah = wm.window.attributes('-topmost', 0) fitsfile = fits.open(bfile) rawdata = fitsfile[0].data head = fitsfile[0].header num_apertures = rawdata.shape[1] wavearr = np.zeros((rawdata.shape[2], rawdata.shape[1])) objectname = head['OBJECT'] airmass = float(head['AIRMASS']) exptime = float(head['EXPTIME']) if (exptime < 1): exptime = 1. head = pacheck(head) observat = head['OBSERVAT'].strip().lower() sitefactor = obs_extinction(observat) for i in range(0, num_apertures): wavearr[:, i] = getmswave(head, i) if (wavearr[-1, 0] < 3000): print('************************************************') print('Spectrum not wavelength calibrated---bailing out') print('************************************************') sys.exit(1) ap_choice = -1 if (np.mean(rawdata[0, 0, :]) < 1e-7): rawdata = rawdata * 1e15 # scale to rational numbers for fit (rational as in sane, # not opposed to irrational) if (num_apertures != 1): axarr = fig.subplots(num_apertures, sharex=True) fig.subplots_adjust(hspace=0) for i in range(0, num_apertures): x = wavearr[:, i] y = rawdata[0, i, :] axarr[i].clear() plt.pause(0.01) axarr[i].plot(x, y, drawstyle='steps-mid') axarr[i].set_ylabel('Aperture {}'.format(i)) plt.pause(0.01) while (ap_choice < 0) or (ap_choice > num_apertures - 1): ap_choice = inputter( 'Which aperture do you want to use for the B star? ', 'int', False) fig.clf() else: ap_choice = 0 ymin, ymax = finalscaler(rawdata[0, ap_choice, :]) fig.clf() x1 = wavearr[:, ap_choice] y1 = rawdata[1, ap_choice, :] y0 = rawdata[0, ap_choice, :] plt.plot(x1, y1, drawstyle='steps-mid', color='r') plt.plot(x1, y0, drawstyle='steps-mid', color='k') plt.pause(0.01) plt.ylim([ymin, ymax]) plt.pause(0.01) print('\nPlotting optimal as black, normal as red') extract = inputter_single( 'Do you want to use (n)ormal or (o)ptimal extraction? ', 'no') if (extract == 'o'): bstar = rawdata[0, ap_choice, :] else: bstar = rawdata[1, ap_choice, :] # fix IRAF weirdness where data can go negative in dispcor interpolation bstar[np.where(bstar < 0)] = 0.01 wave = wavearr[:, ap_choice] print('\nAirmass: {}\n'.format(airmass)) airlimit = 0.5 while (airlimit < 1.0) or (airlimit > 10.): airlimit = inputter('Above what airmass is considered high? ', 'float', False) print('\nNow fit the continuum manually\n') plt.clf() ax = fig.add_subplot(111) cursor = Cursor(ax, useblit=True, color='k', linewidth=1) airlimit = 1.5 splineresult = fitspl(wave, np.log10(bstar), (airmass > airlimit), fig) splineresult = 10**(splineresult) plt.cla() plt.plot(wave, splineresult, drawstyle='steps-mid') plt.pause(0.01) bstar = bstar / splineresult if (airmass > airlimit): loc = wave_telluric(wave, 'high') else: loc = wave_telluric(wave, 'low') #invert loc and convert all good sections to np.nan so they won't plot loc = np.invert(loc) bstar[loc] = 1.0 bstar[np.where(bstar > 1.)] = 1.0 bstar[np.where(bstar <= 0.)] = 0.01 plt.cla() plt.plot(wave, bstar, drawstyle='steps-mid') plt.pause(0.01) print('\nDo you want to blotch the B-star?') blotch = yesno('n') if (blotch == 'y'): bstar = bblo(wave, bstar, (airmass > airlimit), fig) delkeylist=['WAT0_001', 'WAT1_001', 'WAT2_001', 'WAT0_002', \ 'WAT1_002', 'WAT2_002', 'WAT3_001', 'WAT2_003', \ 'CTYPE1', 'CTYPE2', 'CTYPE3', 'CD1_1', 'CD2_2', \ 'CD3_3', 'LTM1_1', 'LTM2_2', 'LTM3_3', 'WCSDIM'] for k in delkeylist: try: head.remove(k) except KeyError: pass plt.cla() plt.plot(wave, bstar, drawstyle='steps-mid') plt.pause(0.01) head.set('CRPIX1', 1) head.set('CRVAL1', wave[0]) head.set('CDELT1', wave[1] - wave[0]) head.set('CTYPE1', 'LINEAR') outfile = 'bstar' + gratcode + '.fits' print('Writing data to {}'.format(outfile)) outhdu = fits.PrimaryHDU(bstar) hdul = fits.HDUList([outhdu]) hdul[0].header = head.copy() hdul.writeto(outfile, overwrite=True) print('mkbstar') print(bfile, gratcode) return
def telluric_remove(bstarwave, bstar, bairmass, wave, object, airmass, variance, spectrum, shift=None): import numpy as np import pdb import matplotlib.pyplot as plt from tmath.wombat.inputter import inputter from tmath.wombat.yesno import yesno from tmath.wombat.womscipyrebin import womscipyrebin from tmath.wombat.womget_element import womget_element from tmath.pydux.xcor import xcor from tmath.pydux.finalscaler import finalscaler bstartmp = womscipyrebin(bstarwave, bstar, wave) # plt.cla() # plt.plot(bstarwave,bstartmp) # plt.pause(0.01) # answer=yesno('y') print('\nThe ratio of airmasses (object/B-star) is {}'.format(airmass / bairmass)) if (airmass / bairmass > 3.0) or (airmass / bairmass < 0.33): print('\nWARNING: OBJECT AND B-STAR HAVE WILDLY DIFFERENT') print('AIRMASSES: ATMOSPHERIC BAND DIVISION MAY BE LOUSY\n') wmin = wave[0] wmax = wave[-1] npix = len(object) wdelt = wave[1] - wave[0] print('wdelt', wdelt) lag = np.zeros(3) lagflag = [False] * 3 xfactor = 10 maxlag = 200 if not shift: print('\nCross-correlating object with B-star spectrum\n') fig = plt.figure() axarr = fig.subplots(2, 1) if (wmin < 6200) and (wmax > 6400) and (wmax < 6900): indblue = womget_element(wave, 6200) indred = womget_element(wave, 6400) lag[0] = xcor(object[indblue:indred + 1], bstartmp[indblue:indred + 1], xfactor, maxlag) lagflag[0] = True print('The shift at the 6250A band is {} angstroms'.format(lag[0] * wdelt)) if (wmin < 6800) and (wmax > 6500): indblue = womget_element(wave, 6800) indred = womget_element(wave, 6950) scale = 1. / np.max(object[indblue:indred + 1]) obb = scale * object[indblue:indred + 1] bb = bstartmp[indblue:indred + 1] lag[1] = xcor(obb, bb, xfactor, maxlag) lagflag[1] = True print('The shift at the B band is {} angstroms'.format(lag[1] * wdelt)) plt.cla() # ymin,ymax=finalscaler(object) # plt.plot(wave,object,drawstyle='steps-mid',color='r') # plt.plot(wave,newobject,drawstyle='steps-mid',color='k') ymin, ymax = finalscaler(bstartmp[indblue:indred + 1]) axarr[0].plot(wave[indblue:indred + 1], scale * object[indblue:indred + 1], drawstyle='steps-mid', color='r') axarr[0].plot(wave[indblue:indred + 1], bstartmp[indblue:indred + 1], drawstyle='steps-mid', color='k') axarr[0].plot(wave[indblue:indred + 1] + lag[1] * wdelt, bstartmp[indblue:indred + 1], drawstyle='steps-mid', color='g') plt.pause(0.01) if (wmin < 7500) and (wmax > 8000): indblue = womget_element(wave, 7500) indred = womget_element(wave, 8000) scale = 1. / np.max(object[indblue:indred + 1]) lag[2] = xcor(scale * object[indblue:indred + 1], bstartmp[indblue:indred + 1], xfactor, maxlag) print('The shift at the A band is {} angstroms'.format(lag[2] * wdelt)) lagflag[2] = True # ymin,ymax=finalscaler(object) # plt.plot(wave,object,drawstyle='steps-mid',color='r') # plt.plot(wave,newobject,drawstyle='steps-mid',color='k') ymin, ymax = finalscaler(bstartmp[indblue:indred + 1]) axarr[1].plot(wave[indblue:indred + 1], scale * object[indblue:indred + 1], drawstyle='steps-mid', color='r') axarr[1].plot(wave[indblue:indred + 1], bstartmp[indblue:indred + 1], drawstyle='steps-mid', color='k') axarr[1].plot(wave[indblue:indred + 1] + lag[2] * wdelt, bstartmp[indblue:indred + 1], drawstyle='steps-mid', color='g') plt.pause(0.01) check = inputter('Check plot [enter when done]: ', 'string', False) if (sum(lagflag) > 0): avglag = np.sum(lag) / sum(lagflag) angshift = avglag * wdelt print('The mean shift is {} Angstroms'.format(angshift)) else: angshift = 0.0 plt.close() else: angshift = shift fig = plt.figure(figsize=[9, 5]) telluric_done = False bstartmpcopy = bstartmp.copy() while (not telluric_done): print('Applying a shift of {} Angstroms'.format(angshift)) bstartmp = bstartmpcopy.copy() tmp = womscipyrebin(wave + angshift, bstartmp, wave) bstartmp = tmp.copy() bstartmp = bstartmp**((airmass / bairmass)**0.55) # newobject=object/bstartmp newobject = spectrum / bstartmp bvar = variance / bstartmp print('\nPlotting before and after atmospheric band correction\n') plt.cla() # ymin,ymax=finalscaler(object) # plt.plot(wave,object,drawstyle='steps-mid',color='r') # plt.plot(wave,newobject,drawstyle='steps-mid',color='k') ymin, ymax = finalscaler(spectrum) plt.plot(wave, spectrum, drawstyle='steps-mid', color='r') plt.plot(wave, newobject, drawstyle='steps-mid', color='k') plt.ylim([ymin, ymax]) plt.pause(0.01) if not shift: print('Is this OK?') answer = yesno('y') if (answer == 'n'): angshift = inputter('Enter B-star shift in Angstroms: ', 'float', False) else: telluric_done = True else: check = inputter('Check plot [enter when done]: ', 'string', False) telluric_done = True plt.close() return newobject, bvar, angshift