コード例 #1
0
 def timed_out(self, dt):
     now = datenow()
     dt  = (now - self.lastNewFile).total_seconds()
     print('No new images seen for', dt, 'seconds.')
     markmjds = []
     if dt > self.longtime:
         edate = (self.lastNewFile +
                  datetime.timedelta(0, self.longtime))
         markmjds.append((datetomjd(edate),'r'))
     self.plot_recent(markmjds=markmjds)
コード例 #2
0
ファイル: decbot.py プロジェクト: rblum5/obsbot
    def queue_initial_exposures(self):
        # Queue two exposures to start
        e0 = self.queue_exposure()
        e1 = self.queue_exposure()

        # When should we queue the next exposure?
        dt = e0['expTime'] + e1['expTime'] + 2 * self.nom.overhead
        # margin
        dt -= self.queueMargin
        self.queuetime = (datenow() +
                          datetime.timedelta(0, dt))
        self.queuetime = self.queuetime.replace(microsecond = 0)
コード例 #3
0
ファイル: decbot.py プロジェクト: rblum5/obsbot
    def heartbeat(self):
        if self.queuetime is None:
            return
        ## Is it time to queue a new exposure?
        now = datenow().replace(microsecond=0)
        print('Heartbeat.  Now is', now.isoformat(),
              'queue time is', self.queuetime.isoformat(),
              'dt %i' % (int((self.queuetime - now).total_seconds())))
        if now < self.queuetime:
            return
        print('Time to queue an exposure!')
        e = self.queue_exposure()
        # schedule next one
        dt = e['expTime'] + self.nom.overhead - self.queueMargin
        self.queuetime = now + datetime.timedelta(0, dt)
        self.queuetime = self.queuetime.replace(microsecond = 0)

        self.write_plans()
コード例 #4
0
def main(cmdlineargs=None, get_copilot=False):
    global gSFD
    import optparse
    parser = optparse.OptionParser(usage='%prog')

    # Mosaic or Decam?
    from camera import (nominal_cal, ephem_observer, default_extension,
                        tile_path)
    nom = nominal_cal
    obs = ephem_observer()
    
    plotfn_default = 'recent.png'
    
    parser.add_option('--ext', default=default_extension,
                      help='Extension to read for computing observing conditions: default %default')
    parser.add_option('--extnum', type=int, help='Integer extension to read')
    parser.add_option('--rawdata', help='Directory to monitor for new images: default $MOS3_DATA if set, else "rawdata"', default=None)

    parser.add_option('--n-fwhm', default=None, type=int, help='Number of stars on which to measure FWHM')
    
    parser.add_option('--no-db', dest='db', default=True, action='store_false',
                      help='Do not append results to database')

    parser.add_option('--no-focus', dest='focus', default=True,
                      action='store_false', help='Do not analyze focus frames')
    
    parser.add_option('--fits', help='Write database to given FITS table')
    parser.add_option('--plot', action='store_true',
                      help='Plot recent data and quit')
    parser.add_option('--plot-filename', default=None,
                      help='Save plot to given file, default %s' % plotfn_default)

    parser.add_option('--nightplot', '--night', action='store_true',
                      help="Plot tonight's data and quit")

    parser.add_option('--qa-plots', dest='doplots', default=False,
                      action='store_true', help='Create QA plots')

    parser.add_option('--keep-plots', action='store_true',
                      help='Do not remove PNG-format plots (normally merged into PDF)')
    
    parser.add_option('--mjdstart', type=float, default=None,
                      help='MJD (UTC) at which to start plot')

    now = mjdnow()
    parser.add_option('--mjdend', type=float, default=None,
                      help='MJD (UTC) at which to end plot (default: now, which is %.3f)' % now)

    parser.add_option('--skip', action='store_true',
                      help='Skip images that already exist in the database')

    parser.add_option('--threads', type=int, default=None,
                      help='Run multi-threaded when processing list of files on command-line')

    parser.add_option('--fix-db', action='store_true')

    parser.add_option('--tiles', default=tile_path,
                      help='Tiles table, default %default')

    parser.add_option('--no-show', dest='show', default=True, action='store_false',
                      help='Do not show plot window, just save it.')

    if cmdlineargs is None:
        opt,args = parser.parse_args()
    else:
        opt,args = parser.parse_args(cmdlineargs)
        
    if not opt.show:
        import matplotlib
        matplotlib.use('Agg')

    imagedir = opt.rawdata
    if imagedir is None:
        imagedir = os.environ.get('MOS3_DATA', 'rawdata')

    rawext = opt.ext
    if opt.extnum is not None:
        rawext = opt.extnum
    assert(rawext is not None)
        
    from astrometry.util.fits import fits_table
    tiles = fits_table(opt.tiles)

    from django.conf import settings
    import obsdb

    import pylab as plt
    plt.figure(figsize=(8,10))

    markmjds = []

    if opt.nightplot:
        opt.plot = True

        if opt.plot_filename is None:
            opt.plot_filename = 'night.png'

        # Are we at Tololo or Kitt Peak?  Look for latest image.
        o = obsdb.MeasuredCCD.objects.all().order_by('-mjd_obs')
        cam = o[0].camera
        print('Camera:', cam)

        if opt.mjdstart is not None:
            sdate = ephem.Date(mjdtodate(opt.mjdend))
        else:
            sdate = ephem.Date(datenow())
        
        (sunset, eve12, eve18, morn18, morn12, sunrise) = get_twilight(
            cam, sdate)
        if opt.mjdstart is None:
            opt.mjdstart = ephemdate_to_mjd(sunset)
            print('Set mjd start to sunset:', sunset, opt.mjdstart)
        if opt.mjdend is None:
            opt.mjdend = ephemdate_to_mjd(sunrise)
            print('Set mjd end to sunrise', sunrise, opt.mjdend)

        markmjds.append((ephemdate_to_mjd(eve18),'b'))
        print('Evening twi18:', eve18, markmjds[-1])
        markmjds.append((ephemdate_to_mjd(morn18),'b'))
        print('Morning twi18:', morn18, markmjds[-1])
        markmjds.append((ephemdate_to_mjd(eve12),'g'))
        print('Evening twi12:', eve12, markmjds[-1])
        markmjds.append((ephemdate_to_mjd(morn12),'g'))
        print('Morning twi12:', morn12, markmjds[-1])
            
        
    if opt.plot_filename is None:
        opt.plot_filename = plotfn_default

    if opt.fits:
        ccds = obsdb.MeasuredCCD.objects.all()
        print(ccds.count(), 'measured CCDs')
        T = db_to_fits(ccds)
        T.writeto(opt.fits)
        print('Wrote', opt.fits)
        return 0

    if opt.fix_db:

        from astrometry.util.fits import fits_table
        tiles = fits_table('obstatus/mosaic-tiles_obstatus.fits')

        now = mjdnow()
        
        #ccds = obsdb.MeasuredCCD.objects.all()
        #ccds = obsdb.MeasuredCCD.objects.all().filter(mjd_obs__gt=now - 0.25)
        ccds = obsdb.MeasuredCCD.objects.all().filter(mjd_obs__gt=57434)
        
        print(ccds.count(), 'measured CCDs')
        for ccd in ccds:
            try:
                hdr = fitsio.read_header(ccd.filename, ext=0)
                # band = hdr['FILTER']
                # band = band.split()[0]
                # ccd.band = band

                set_tile_fields(ccd, hdr, tiles)

                ccd.save()
                print('Fixed', ccd.filename)
            except:
                import traceback
                traceback.print_exc()

        return 0


    if opt.plot:
        plot_recent(opt, nom, tiles=tiles, markmjds=markmjds, show_plot=False)
        return 0
        
    print('Loading SFD maps...')
    sfd = SFDMap()
    
    if len(args) > 0:
        mp = None
        if opt.threads > 1:
            gSFD = sfd
            from astrometry.util.multiproc import multiproc
            mp = multiproc(opt.threads)

        if opt.skip:
            fns = skip_existing_files(args, rawext)
        else:
            fns = args
            
        if mp is None:
            for fn in fns:
                process_image(fn, rawext, nom, sfd, opt, obs, tiles)
        else:
            sfd = None
            mp.map(bounce_process_image,
                   [(fn, rawext, nom, sfd, opt, obs, tiles) for fn in fns])
        plot_recent(opt, nom, tiles=tiles, markmjds=markmjds, show_plot=False)
        return 0
    

    copilot = Copilot(imagedir, rawext, opt, nom, sfd, obs, tiles)

    # for testability
    if get_copilot:
        return copilot

    copilot.run()
    return 0
コード例 #5
0
def process_image(fn, ext, nom, sfd, opt, obs, tiles):
    db = opt.db
    print('Reading', fn)

    if sfd is None:
        sfd = gSFD

    # Read primary FITS header
    phdr = fitsio.read_header(fn)

    obstype = phdr.get('OBSTYPE','').strip()
    print('obstype:', obstype)
    exptime = phdr.get('EXPTIME', 0)
    expnum = phdr.get('EXPNUM', 0)

    filt = phdr.get('FILTER', None)
    if filt is not None:
        filt = filt.strip()
        filt = filt.split()[0]
    if filt is None:
        filt = ''

    airmass = phdr.get('AIRMASS', 0.)
    ra  = hmsstring2ra (phdr.get('RA', '0'))
    dec = dmsstring2dec(phdr.get('DEC', '0'))
    
    # Write QA plots to files named by the exposure number
    print('Exposure number:', expnum)

    skip = False
    if obstype in ['zero', 'focus', 'dome flat', '']:
        print('Skipping obstype =', obstype)
        skip = True
    if exptime == 0:
        print('Exposure time EXPTIME in header =', exptime)
        skip = True
    if expnum == '':
        print('No expnum in header')
        skip = True
    if filt == 'solid':
        print('Solid (block) filter.')
        skip = True

    if skip and not db:
        return None

    if db:
        import obsdb
        if ext is None:
            ext = get_default_extension(fn)
        m,created = obsdb.MeasuredCCD.objects.get_or_create(
            filename=fn, extension=ext)
        m.obstype = obstype
        m.camera  = camera_name(phdr)
        m.expnum  = expnum
        m.exptime = exptime
        m.mjd_obs = phdr.get('MJD-OBS', 0.)
        m.airmass = airmass
        m.rabore  = ra
        m.decbore = dec
        m.band = filt
        m.bad_pixcnt = ('PIXCNT1' in phdr)
        m.readtime = phdr.get('READTIME', 0.)

    if opt.focus and obstype == 'focus' and m.camera == 'mosaic3':
        from mosaic_focus import Mosaic3FocusMeas
        show_plot = opt.show
        if show_plot:
            import pylab as plt
            plt.figure(2, figsize=(8,10))
        if ext is None:
            ext = get_default_extension(fn)
        meas = Mosaic3FocusMeas(fn, ext, nom)
        focusfn = 'focus.png'
        meas.run(ps=None, plotfn=focusfn)
        print('Wrote', focusfn)
        if show_plot:
            plt.draw()
            plt.show(block=False)
            plt.pause(0.001)
            plt.figure(1)
        
    if skip:
        m.save()
        return None
        
    if opt.doplots:
        from astrometry.util.plotutils import PlotSequence
        ps = PlotSequence('qa-%i' % expnum)
        ps.printfn = False
    else:
        ps = None

    # Measure the new image
    kwa = {}
    if ext is not None:
        kwa.update(ext=ext)
    if opt.n_fwhm is not None:
        kwa.update(n_fwhm=opt.n_fwhm)
    M = measure_raw(fn, ps=ps, **kwa)

    if opt.doplots:
        from glob import glob
        # Gather all the QAplots into a single pdf and clean them up.
        qafile = 'qa-%i.pdf' % expnum
        pnglist = sorted(glob('qa-%i-??.png' % expnum))
        cmd = 'convert {} {}'.format(' '.join(pnglist), qafile)
        print('Writing out {}'.format(qafile))
        #print(cmd)
        os.system(cmd)
        if not opt.keep_plots:
            [os.remove(png) for png in pnglist]

    # (example results for testig)
    #M = {'seeing': 1.4890481099577366, 'airmass': 1.34,
    #'skybright': 18.383479116033314, 'transparency': 0.94488537276869045,
    #'band': 'z', 'zp': 26.442847814941093}

    #print('Measurements:', M)

    trans = M.get('transparency', 0)
    band = M['band']
    # Look up E(B-V) in SFD map
    ebv = sfd.ebv(ra, dec)[0]
    print('E(B-V): %.3f' % ebv)

    if trans > 0:

        fid = nom.fiducial_exptime(band)

        expfactor = exposure_factor(fid, nom,
                                    airmass, ebv, M['seeing'], M['skybright'],
                                    trans)
        print('Exposure factor:              %6.3f' % expfactor)
        t_exptime = expfactor * fid.exptime
        print('Target exposure time:         %6.1f' % t_exptime)
        t_exptime = np.clip(t_exptime, fid.exptime_min, fid.exptime_max)
        print('Clipped exposure time:        %6.1f' % t_exptime)
    
        if band == 'z':
            t_sat = nom.saturation_time(band, M['skybright'])
            if t_exptime > t_sat:
                t_exptime = t_sat
                print('Reduced exposure time to avoid z-band saturation: %.1f' % t_exptime)

        print

        print('Actual exposure time taken:   %6.1f' % exptime)
    
        print('Depth (exposure time) factor: %6.3f' % (exptime / t_exptime))
        
        # If you were going to re-plan, you would run with these args:
        plandict = dict(seeing=M['seeing'], transparency=trans)
        # Assume the sky is as much brighter than canonical in each band... unlikely
        dsky = M['skybright'] - nom.sky(M['band'])
        for b in 'grz':
            plandict['sb'+b] = nom.sky(b) + dsky
        # Note that nightlystrategy.py takes UTC dates.
        start = datenow()
        # Start the strategy 5 minutes from now.
        start += datetime.timedelta(0, 5*60)
        d = start.date()
        plandict['startdate'] = '%04i-%02i-%02i' % (d.year, d.month, d.day)
        t = start.time()
        plandict['starttime'] = t.strftime('%H:%M:%S')
        # Make an hour-long plan
        end = start + datetime.timedelta(0, 3600)
        d = end.date()
        plandict['enddate'] = '%04i-%02i-%02i' % (d.year, d.month, d.day)
        t = end.time()
        plandict['endtime'] = t.strftime('%H:%M:%S')
    
        # Set "--date" to be the UTC date at previous sunset.
        # (nightlystrategy will ask for the next setting of the sun below
        # -18-degrees from that date to define the sn_18).  We could
        # probably also get away with subtracting, like, 12 hours from
        # now()...
        sun = ephem.Sun()
        obs.date = datenow()
        # not the proper horizon, but this doesn't matter -- just need it to
        # be before -18-degree twilight.
        obs.horizon = 0.
        sunset = obs.previous_setting(sun)
        # pyephem's Date.tuple() splits a date into y,m,d,h,m,s
        d = sunset.tuple()
        #print('Date at sunset, UTC:', d)
        year,month,day = d[:3]
        plandict['date'] = '%04i-%02i-%02i' % (year, month, day)
    
        # Decide the pass.
        goodseeing = plandict['seeing'] < 1.3
        photometric = plandict['transparency'] > 0.9
    
        if goodseeing and photometric:
            passnum = 1
        elif goodseeing or photometric:
            passnum = 2
        else:
            passnum = 3
        plandict['pass'] = passnum
    
        ## ??
        plandict['portion'] = 1.0
        
        print('Replan command:')
        print()
        print('python2.7 nightlystrategy.py --seeg %(seeing).3f --seer %(seeing).3f --seez %(seeing).3f --sbg %(sbg).3f --sbr %(sbr).3f --sbz %(sbz).3f --transparency %(transparency).3f --start-date %(startdate)s --start-time %(starttime)s --end-date %(enddate)s --end-time %(endtime)s --date %(date)s --portion %(portion)f --pass %(pass)i' % plandict) 
        print()
    else:
        plandict = None
        expfactor = 0.

    rtn = (M, plandict, expnum)
    if not db:
        return rtn

    m.racenter  = M['ra_ccd']
    m.deccenter = M['dec_ccd']
    m.ebv  = ebv
    zp = M.get('zp', 0.)
    if zp is None:
        zp = 0.
    m.zeropoint = zp
    m.transparency = trans
    m.seeing = M.get('seeing', 0.)
    m.sky = M['skybright']
    m.expfactor = expfactor
    m.dx = M.get('dx', 0)
    m.dy = M.get('dy', 0)
    m.nmatched = M.get('nmatched',0)

    img = fitsio.read(fn, ext=1)
    cheaphash = np.sum(img)
    # cheaphash becomes an int64.
    m.md5sum = cheaphash

    set_tile_fields(m, phdr, tiles)

    m.save()

    return rtn