コード例 #1
0
def main():
    import optparse
    parser = optparse.OptionParser(usage='%prog [options] <NGC-number>')
    parser.add_option('--threads', dest='threads', type=int, help='use multiprocessing')
    parser.add_option('--itune1',dest='itune1',type=int,help='Individual tuning, first stage',default=5)
    parser.add_option('--itune2',dest='itune2',type=int,help='Individual tuning, second stage',default=5)
    parser.add_option('--ntune',dest='ntune',type=int,help='All objects tuning',default=0)
    parser.add_option('--nocache',dest='nocache',action='store_true',default=False,help='Disable caching for memory reasons')

    opt,args = parser.parse_args()
    if len(args) != 1:
        parser.print_help()
        sys.exit(-1)

    if opt.threads:
        mp = multiproc(nthreads=opt.threads)
    else:
        mp = multiproc()


    ngc = int(args[0])

    j = getNGC(ngc)
    print j
    ra = float(j['RA'][0])
    dec = float(j['DEC'][0])
    itune1 = opt.itune1
    itune2 = opt.itune2
    ntune = opt.ntune
    IRLS_scale = 25.
    radius = (10.**j['LOG_D25'][0])/10.
    dr8 = True
    noarcsinh = False

    print 'Radius', radius
    print 'RA,Dec', ra, dec

    sras, sdecs, smags = tychoMatch(ra,dec,(radius*1.5)/60.)

    for sra,sdec,smag in zip(sras,sdecs,smags):
        print sra,sdec,smag



    rcfs = radec_to_sdss_rcf(ra,dec,radius=math.hypot(radius,13./2.),tablefn="dr8fields.fits")
    print rcfs

    #fieldPlot(ra,dec,radius,ngc)
    
    imkw = dict(psf='dg')
    if dr8:
        getim = st.get_tractor_image_dr8
        getsrc = st.get_tractor_sources_dr8
        imkw.update(zrange=[-3,100])
    else:
        getim = st.get_tractor_image
        getsrc = st.get_tractor_sources_dr8
        imkw.update(useMags=True)

    bands=['u','g','r','i','z']
    #bands=['r']
    bandname = 'r'
    flipBands = ['r']

    imsrcs = mp.map(get_ims_and_srcs, [(rcf + (bands, ra, dec, radius*60./0.396, imkw, getim, getsrc))
                                       for rcf in rcfs])
    timgs = []
    sources = []
    allsources = []
    for ims,s in imsrcs:
        if ims is None:
            continue
        if s is None:
            continue
        timgs.extend(ims)
        allsources.extend(s)
        sources.append(s)

    #rds = [rcf[3:5] for rcf in rcfs]
    plotarea(ra, dec, radius, ngc, timgs) #, rds)
    
    lvl = logging.DEBUG
    logging.basicConfig(level=lvl,format='%(message)s',stream=sys.stdout)
    tractor = st.Tractor(timgs, allsources, mp=mp)

    sa = dict(debug=True, plotAll=False,plotBands=False)

    if noarcsinh:
        sa.update(nlscale=0)
    elif dr8:
        sa.update(chilo=-8.,chihi=8.)

    if opt.nocache:
        tractor.cache = NullCache()
        sg.disable_galaxy_cache()

    zr = timgs[0].zr
    print "zr is: ",zr

    print bands

    print "Number of images: ", len(timgs)
#    for timg,band in zip(timgs,bands):
#        data = timg.getImage()/np.sqrt(timg.getInvvar())
#        plt.hist(data,bins=100)
#        plt.savefig('hist-%s.png' % (band))

    prefix = 'ngc%d' % (ngc)
    saveAll('initial-'+prefix, tractor,**sa)
    #plotInvvar('initial-'+prefix,tractor)

    

    for sra,sdec,smag in zip(sras,sdecs,smags):
        print sra,sdec,smag

        for img in tractor.getImages():
            wcs = img.getWcs()
            starx,stary = wcs.positionToPixel(RaDecPos(sra,sdec))
            starr=25*(2**(max(11-smag,0.)))
            if starx+starr<0. or starx-starr>img.getWidth() or stary+starr <0. or stary-starr>img.getHeight():
                continue
            X,Y = np.meshgrid(np.arange(img.getWidth()), np.arange(img.getHeight()))
            R2 = (X - starx)**2 + (Y - stary)**2
            img.getStarMask()[R2 < starr**2] = 0
            #star =  [(x,y) for x in range(img.getWidth()) for y in range(img.getHeight()) if (x-starx)**2+(y-stary)**2 <= starr**2]
            #for (x,y) in star:
            #    img.getStarMask()[y][x] = 0

    for timgs,sources in imsrcs:
        timg = timgs[0]
        wcs = timg.getWcs()
        xtr,ytr = wcs.positionToPixel(RaDecPos(ra,dec))
    
        print xtr,ytr

        xt = xtr 
        yt = ytr
        r = ((radius*60.))/.396 #radius in pixels
        for src in sources:
            xs,ys = wcs.positionToPixel(src.getPosition(),src)
            if (xs-xt)**2+(ys-yt)**2 <= r**2:
                print "Removed:", src
                print xs,ys
                tractor.removeSource(src)

    #saveAll('removed-'+prefix, tractor,**sa)
    newShape = sg.GalaxyShape(30.,1.,0.)
    newBright = ba.Mags(r=15.0,g=15.0,u=15.0,z=15.0,i=15.0,order=['u','g','r','i','z'])
    EG = st.ExpGalaxy(RaDecPos(ra,dec),newBright,newShape)
    print EG
    tractor.addSource(EG)


    saveAll('added-'+prefix,tractor,**sa)

    print 'Tractor has', tractor.getParamNames()

    for im in tractor.images:
        im.freezeAllParams()
        im.thawParam('sky')
    tractor.catalog.freezeAllBut(EG)

    print 'Tractor has', tractor.getParamNames()
    print 'values', tractor.getParams()

    for i in range(itune1):
        tractor.optimize()
        print resource.getpagesize()
        print resource.getrusage(resource.RUSAGE_SELF)[2]
        tractor.changeInvvar(IRLS_scale)
        print resource.getpagesize()
        print resource.getrusage(resource.RUSAGE_SELF)[2]
        saveAll('itune1-%d-' % (i+1)+prefix,tractor,**sa)
        print resource.getpagesize()
        print resource.getrusage(resource.RUSAGE_SELF)[2]
        tractor.clearCache()
        sg.get_galaxy_cache().clear()
        gc.collect()
        print resource.getpagesize()
        print resource.getrusage(resource.RUSAGE_SELF)[2]
        

    CGPos = EG.getPosition()
    CGShape1 = EG.getShape().copy()
    CGShape2 = EG.getShape().copy()
    EGBright = EG.getBrightness()

    CGu = EGBright[0] + 0.75
    CGg = EGBright[1] + 0.75
    CGr = EGBright[2] + 0.75
    CGi = EGBright[3] + 0.75
    CGz = EGBright[4] + 0.75
    CGBright1 = ba.Mags(r=CGr,g=CGg,u=CGu,z=CGz,i=CGi,order=['u','g','r','i','z'])
    CGBright2 = ba.Mags(r=CGr,g=CGg,u=CGu,z=CGz,i=CGi,order=['u','g','r','i','z'])
    print EGBright
    print CGBright1

    CG = st.CompositeGalaxy(CGPos,CGBright1,CGShape1,CGBright2,CGShape2)
    tractor.removeSource(EG)
    tractor.addSource(CG)

    tractor.catalog.freezeAllBut(CG)
    print resource.getpagesize()
    print resource.getrusage(resource.RUSAGE_SELF)[2]


    for i in range(itune2):
        tractor.optimize()
        tractor.changeInvvar(IRLS_scale)
        saveAll('itune2-%d-' % (i+1)+prefix,tractor,**sa)
        print resource.getpagesize()
        print "RUsage is: ",resource.getrusage(resource.RUSAGE_SELF)[2]
        tractor.clearCache()
        sg.get_galaxy_cache().clear()
        print resource.getpagesize()
        print resource.getrusage(resource.RUSAGE_SELF)[2]



    tractor.catalog.thawAllParams()
    for i in range(ntune):
        tractor.optimize()
        tractor.changeInvvar(IRLS_scale)
        saveAll('ntune-%d-' % (i+1)+prefix,tractor,**sa)
    #plotInvvar('final-'+prefix,tractor)
    sa.update(plotBands=True)
    saveAll('allBands-' + prefix,tractor,**sa)

    print CG
    print CG.getPosition()
    print CGBright1
    print CGBright2
    print CGShape1
    print CGShape2
    print CGBright1+CGBright2
    print CG.getBrightness()

    pfn = 'ngc-%d.pickle' % ngc
    pickle_to_file(CG,pfn)

    makeflipbook(prefix,len(tractor.getImages()),itune1,itune2,ntune)
コード例 #2
0
def main():

    # In LSST meas-deblend (on lsst6):
    # python examples/suprimePlot.py --data ~dstn/lsst/ACT-data -v 126969 -c 5 --data-range -100 300 --roi 0 500 0 500 --psf psf.fits --image img.fits --sources srcs.fits

    from optparse import OptionParser
    import sys

    parser = OptionParser(usage=('%prog <img> <psf> <srcs>'))
    parser.add_option('-v',
                      '--verbose',
                      dest='verbose',
                      action='count',
                      default=0,
                      help='Make more verbose')
    opt, args = parser.parse_args()

    if len(args) != 3:
        parser.print_help()
        sys.exit(-1)

    if opt.verbose == 0:
        lvl = logging.INFO
    else:
        lvl = logging.DEBUG
    logging.basicConfig(level=lvl, format='%(message)s', stream=sys.stdout)

    imgfn, psffn, srcfn = args

    pimg = pyfits.open(imgfn)
    if len(pimg) != 4:
        print('Image must have 3 extensions')
        sys.exit(-1)
    img = pimg[1].data
    mask = pimg[2].data
    maskhdr = pimg[2].header
    var = pimg[3].data
    del pimg

    print('var', var.shape)
    #print var
    print('mask', mask.shape)
    #print mask
    print('img', img.shape)
    #print img

    mask = mask.astype(np.int16)
    for bit in range(16):
        on = ((mask & (1 << bit)) != 0)
        print('Bit', bit, 'has', np.sum(on), 'pixels set')
    '''
	MP_BAD  =                    0
	Bit 0 has 2500 pixels set
	MP_SAT  =                    1
	Bit 1 has 5771 pixels set
	MP_INTRP=                    2
	Bit 2 has 11269 pixels set
	MP_CR   =                    3
	Bit 3 has 136 pixels set
	MP_EDGE =                    4
	Bit 4 has 11856 pixels set
	HIERARCH MP_DETECTED =       5
	Bit 5 has 37032 pixels set
	'''

    print('Mask header:', maskhdr)
    maskplanes = {}
    print('Mask planes:')
    for card in maskhdr.ascardlist():
        if not card.key.startswith('MP_'):
            continue
        print(card.value, card.key)
        maskplanes[card.key[3:]] = card.value

    print('Variance range:', var.min(), var.max())

    print('Image median:', np.median(img.ravel()))

    invvar = 1. / var
    invvar[var == 0] = 0.
    invvar[var < 0] = 0.

    sig = np.sqrt(np.median(var))
    H, W = img.shape
    for k, v in maskplanes.items():
        plt.clf()

        I = ((mask & (1 << v)) != 0)
        rgb = np.zeros((H, W, 3))
        clipimg = np.clip((img - (-3. * sig)) / (13. * sig), 0, 1)
        cimg = clipimg.copy()
        cimg[I] = 1
        rgb[:, :, 0] = cimg
        cimg = clipimg.copy()
        cimg[I] = 0
        rgb[:, :, 1] = cimg
        rgb[:, :, 2] = cimg
        plt.imshow(rgb, interpolation='nearest', origin='lower')
        plt.title(k)
        plt.savefig('mask-%s.png' % k.lower())

    badmask = sum([(1 << maskplanes[k])
                   for k in ['BAD', 'SAT', 'INTRP', 'CR']])
    # HACK -- left EDGE sucks
    badmask += (1 << maskplanes['EDGE'])
    #badmask = (1 << 0) | (1 << 1) | (1 << 2) | (1 << 3)
    #badmask |= (1 << 4)
    print('Masking out: 0x%x' % badmask)
    invvar[(mask & badmask) != 0] = 0.

    assert (all(np.isfinite(img.ravel())))
    assert (all(np.isfinite(invvar.ravel())))

    psf = pyfits.open(psffn)[0].data
    print('psf', psf.shape)
    psf /= psf.sum()

    from tractor.emfit import em_fit_2d
    from tractor.fitpsf import em_init_params

    # Create Gaussian mixture model PSF approximation.
    S = psf.shape[0]
    # number of Gaussian components
    K = 3
    w, mu, sig = em_init_params(K, None, None, None)
    II = psf.copy()
    II /= II.sum()
    # HIDEOUS HACK
    II = np.maximum(II, 0)
    print('Multi-Gaussian PSF fit...')
    xm, ym = -(S / 2), -(S / 2)
    em_fit_2d(II, xm, ym, w, mu, sig)
    print('w,mu,sig', w, mu, sig)
    mypsf = tractor.GaussianMixturePSF(w, mu, sig)

    P = mypsf.getPointSourcePatch(S / 2, S / 2)
    mn, mx = psf.min(), psf.max()
    ima = dict(interpolation='nearest', origin='lower', vmin=mn, vmax=mx)
    plt.clf()
    plt.subplot(1, 2, 1)
    plt.imshow(psf, **ima)
    plt.subplot(1, 2, 2)
    pimg = np.zeros_like(psf)
    P.addTo(pimg)
    plt.imshow(pimg, **ima)
    plt.savefig('psf.png')

    sig = np.sqrt(np.median(var))

    plt.clf()
    plt.hist(img.ravel(), 100, range=(-3. * sig, 3. * sig))
    plt.savefig('imghist.png')

    srcs = fits_table(srcfn)
    print('Initial:', len(srcs), 'sources')
    # Trim sources with x=0 or y=0
    srcs = srcs[(srcs.x != 0) * (srcs.y != 0)]
    print('Trim on x,y:', len(srcs), 'sources left')
    # Zero out nans & infs
    for c in ['theta', 'a', 'b']:
        I = np.logical_not(np.isfinite(srcs.get(c)))
        srcs.get(c)[I] = 0.
    # Set sources with flux=NaN to something more sensible...
    I = np.logical_not(np.isfinite(srcs.flux))
    srcs.flux[I] = 1.
    # Sort sources by flux.
    srcs = srcs[np.argsort(-srcs.flux)]

    # Trim sources that are way outside the image.
    margin = 8. * np.maximum(srcs.a, srcs.b)
    H, W = img.shape
    srcs = srcs[(srcs.x > -margin) * (srcs.y > -margin) *
                (srcs.x < (W + margin) * (srcs.y < (H + margin)))]
    print('Trim out-of-bounds:', len(srcs), 'sources left')

    wcs = tractor.FitsWcs(Sip(imgfn, 1))
    #wcs = tractor.NullWCS()

    timg = tractor.Image(data=img,
                         invvar=invvar,
                         psf=mypsf,
                         wcs=wcs,
                         sky=tractor.ConstantSky(0.),
                         photocal=tractor.NullPhotoCal(),
                         name='image')

    inverr = timg.getInvError()
    assert (all(np.isfinite(inverr.ravel())))

    tsrcs = []
    for s in srcs:
        #pos = tractor.PixPos(s.x, s.y)
        pos = tractor.RaDecPos(s.ra, s.dec)
        if s.a > 0 and s.b > 0:
            eflux = tractor.Flux(s.flux / 2.)
            dflux = tractor.Flux(s.flux / 2.)
            re, ab, phi = s.a, s.b / s.a, 90. - s.theta
            eshape = gal.GalaxyShape(re, ab, phi)
            dshape = gal.GalaxyShape(re, ab, phi)
            print('Fluxes', eflux, dflux)
            tsrc = gal.CompositeGalaxy(pos, eflux, eshape, dflux, dshape)
        else:
            flux = tractor.Flux(s.flux)
            print('Flux', flux)
            tsrc = tractor.PointSource(pos, flux)
        tsrcs.append(tsrc)

    chug = tractor.Tractor([timg])
    for src in tsrcs:
        if chug.getModelPatch(timg, src) is None:
            print('Dropping non-overlapping source:', src)
            continue
        chug.addSource(src)
    print('Kept a total of', len(chug.catalog), 'sources')

    ima = dict(interpolation='nearest',
               origin='lower',
               vmin=-3. * sig,
               vmax=10. * sig)
    chia = dict(interpolation='nearest', origin='lower', vmin=-5., vmax=5.)

    plt.clf()
    plt.imshow(img, **ima)
    plt.colorbar()
    plt.savefig('img.png')

    plt.clf()
    plt.imshow(invvar, interpolation='nearest', origin='lower')
    plt.colorbar()
    plt.savefig('invvar.png')

    mod = chug.getModelImages()[0]
    plt.clf()
    plt.imshow(mod, **ima)
    plt.colorbar()
    plt.savefig('mod-0.png')

    chi = chug.getChiImage(0)
    plt.clf()
    plt.imshow(chi, **chia)
    plt.colorbar()
    plt.savefig('chi-0.png')

    for step in range(5):
        cat = chug.getCatalog()
        for src in cat:
            if chug.getModelPatch(timg, src) is None:
                print('Dropping non-overlapping source:', src)
                chug.removeSource(src)
        print('Kept a total of', len(chug.catalog), 'sources')

        #cat = chug.getCatalog()
        #for i,src in enumerate([]):
        #for i,src in enumerate(chug.getCatalog()):
        #for i in range(len(cat)):
        i = 0
        while i < len(cat):
            src = cat[i]

            #print 'Step', i
            #for j,s in enumerate(cat):
            #	x,y = timg.getWcs().positionToPixel(s, s.getPosition())
            #	print '  ',
            #	if j == i:
            #		print '*',
            #	print '(%6.1f, %6.1f)'%(x,y), s

            print('Optimizing source', i, 'of', len(cat))

            x, y = timg.getWcs().positionToPixel(src.getPosition(), src)
            print('(%6.1f, %6.1f)' % (x, y), src)
            # pre = src.getModelPatch(timg)

            s1 = str(src)
            print('src1 ', s1)
            dlnp1, X, a = chug.optimizeCatalogFluxes(srcs=[src])
            s2 = str(src)
            dlnp2, X, a = chug.optimizeCatalogAtFixedComplexityStep(srcs=[src],
                                                                    sky=False)
            s3 = str(src)

            #post = src.getModelPatch(timg)

            print('src1 ', s1)
            print('src2 ', s2)
            print('src3 ', s3)
            print('dlnp', dlnp1, dlnp2)

            if chug.getModelPatch(timg, src) is None:
                print('After optimizing, no overlap!')
                print('Removing source', src)
                chug.removeSource(src)
                i -= 1
            i += 1

            # plt.clf()
            # plt.subplot(2,2,1)
            # img = timg.getImage()
            # (x0,x1,y0,y1) = pre.getExtent()
            # plt.imshow(img, **ima)
            # ax = plt.axis()
            # plt.plot([x0,x0,x1,x1,x0], [y0,y1,y1,y0,y0], 'k-', lw=2)
            # plt.axis(ax)
            # plt.subplot(2,2,3)
            # plt.imshow(pre.getImage(), **ima)
            # plt.subplot(2,2,4)
            # plt.imshow(post.getImage(), **ima)
            # plt.savefig('prepost-s%i-s%03i.png' % (step, i))
            #
            # mod = chug.getModelImages()[0]
            # plt.clf()
            # plt.imshow(mod, **ima)
            # plt.colorbar()
            # plt.savefig('mod-s%i-s%03i.png' % (step, i))
            # chi = chug.getChiImage(0)
            # plt.clf()
            # plt.imshow(chi, **chia)
            # plt.colorbar()
            # plt.savefig('chi-s%i-s%03i.png' % (step, i))

        #dlnp,x,a = chug.optimizeCatalogFluxes()
        #print 'fluxes: dlnp', dlnp
        #dlnp,x,a = chug.optimizeCatalogAtFixedComplexityStep()
        #print 'opt: dlnp', dlnp

        mod = chug.getModelImages()[0]
        plt.clf()
        plt.imshow(mod, **ima)
        plt.colorbar()
        plt.savefig('mod-%i.png' % (step + 1))

        chi = chug.getChiImage(0)
        plt.clf()
        plt.imshow(chi, **chia)
        plt.colorbar()
        plt.savefig('chi-%i.png' % (step + 1))

    return

    for step in range(5):
        chug.optimizeCatalogFluxes()
        mod = chug.getModelImages()[0]
        plt.clf()
        plt.imshow(mod, **ima)
        plt.colorbar()
        plt.savefig('mod-s%i.png' % step)

        chi = chug.getChiImage(0)
        plt.clf()
        plt.imshow(chi, **chia)
        plt.colorbar()
        plt.savefig('chi-s%i.png' % step)
コード例 #3
0
def main():
    ra = 126.925
    dec = 21.4833
    itune1 = 5
    itune2 = 5
    ntune = 2
    run = [4517, 4576, 4576]
    field = [103, 99, 100]
    camcol = [2, 6, 6]

    bands = ['r']
    bandname = 'r'
    flipBands = ['r']

    rerun = 0

    TI = []
    sources = []

    table = pyfits.open("J082742.02+212844.7-r.fits")
    table.info()

    header = table[0].header
    data = table[0].data
    invvar = table[1].data
    skyobj = ba.ConstantSky(header['skyval'])
    psffn = 'J082742.02+212844.7-r-bpsf.fits.gz'
    psfimg = pyfits.open(psffn)[0].data
    print('PSF image shape', psfimg.shape)
    # number of Gaussian components
    PS = psfimg.shape[0]
    K = 3
    w, mu, sig = em_init_params(K, None, None, None)
    II = psfimg.copy()
    II /= II.sum()
    # HACK
    II = np.maximum(II, 0)
    print('Multi-Gaussian PSF fit...')
    xm, ym = -(PS / 2), -(PS / 2)
    em_fit_2d(II, xm, ym, w, mu, sig)
    print('w,mu,sig', w, mu, sig)
    psf = GaussianMixturePSF(w, mu, sig)

    sources = []
    #    for run,camcol,field in zip(run,camcol,field):
    #        sources.append(st.get_tractor_sources(run,camcol,field,bandname,bands=bands))
    wcs = Tan("J082742.02+212844.7-r.fits", 0)
    wcs = FitsWcs(wcs)
    wcs.setX0Y0(1., 1.)
    photocal = ba.NasaSloanPhotoCal(bandname)  #Also probably not right
    TI.append(
        en.Image(data=data,
                 invvar=invvar,
                 sky=skyobj,
                 psf=psf,
                 wcs=wcs,
                 photocal=photocal,
                 name="NASA-Sloan Test"))

    lvl = logging.DEBUG
    logging.basicConfig(level=lvl, format='%(message)s', stream=sys.stdout)
    tims = [TI[0]]
    tractor = st.SDSSTractor(tims)
    for source in sources:
        tractor.addSources(source)

    zr = np.array([-5., +5.])  # * info['skysig']

    print(bands)

    prefix = 'ngc2595'
    #    saveAll('initial-'+prefix, tractor,zr,flipBands,debug=True)
    bright = None
    lowbright = 1000
    sources = []

    for timg, sources in zip(tims, sources):
        wcs = timg.getWcs()
        xtr, ytr = wcs.positionToPixel(RaDecPos(ra, dec))

        print(xtr, ytr)

        xt = xtr
        yt = ytr
        r = 250.
        for src in sources:
            xs, ys = wcs.positionToPixel(src.getPosition(), src)
            if (xs - xt)**2 + (ys - yt)**2 <= r**2:
                print("Removed:", src)
                print(xs, ys)
                tractor.removeSource(src)


#    saveAll('removed-'+prefix, tractor,zr,flipBands,debug=True)
    newShape = sg.GalaxyShape(30., 1., 0.)
    newBright = ba.Mags(r=15.0, g=15.0, u=15.0, z=15.0, i=15.0)
    EG = st.ExpGalaxy(RaDecPos(ra, dec), newBright, newShape)
    print(EG)
    tractor.addSource(EG)

    saveAll('added-' + prefix, tractor, zr, flipBands, debug=True)
    plotInvvar('added-' + prefix, tractor)

    for i in range(itune1):
        if (i % 5 == 0):
            tractor.optimizeCatalogLoop(nsteps=1, srcs=[EG], sky=True)
        else:
            tractor.optimizeCatalogLoop(nsteps=1, srcs=[EG], sky=False)
        tractor.changeInvvar(9.)
        tractor.clearCache()
        saveAll('itune1-%d-' % (i + 1) + prefix,
                tractor,
                zr,
                flipBands,
                debug=True)
        plotInvvar('itune1-%d-' % (i + 1) + prefix, tractor)

    CGPos = EG.getPosition()
    CGShape = EG.getShape()
    EGBright = EG.getBrightness()
    print(EGBright)
    CGg = EGBright[0] * 1.25
    CGi = EGBright[1] * 1.25
    CGr = EGBright[2] * 1.25
    CGu = EGBright[3] * 1.25
    CGz = EGBright[4] * 1.25
    CGBright = ba.Mags(r=CGr, g=CGg, u=CGu, z=CGz, i=CGi)
    print(EGBright)
    print(CGBright)

    CG = st.CompositeGalaxy(CGPos, CGBright, CGShape, CGBright, CGShape)
    tractor.removeSource(EG)
    tractor.addSource(CG)

    for i in range(itune2):
        if (i % 5 == 0):
            tractor.optimizeCatalogLoop(nsteps=1, srcs=[CG], sky=True)
        else:
            tractor.optimizeCatalogLoop(nsteps=1, srcs=[CG], sky=False)
        tractor.changeInvvar(9.)
        tractor.clearCache()
        saveAll('itune2-%d-' % (i + 1) + prefix,
                tractor,
                zr,
                flipBands,
                debug=True)
        plotInvvar('itune2-%d-' % (i + 1) + prefix, tractor)

    for i in range(ntune):
        tractor.optimizeCatalogLoop(nsteps=1, sky=True)
        saveAll('ntune-%d-' % (i + 1) + prefix,
                tractor,
                zr,
                flipBands,
                debug=True)
        tractor.clearCache()

    makeflipbook(prefix, len(tractor.getImages()), itune1, itune2, ntune)
コード例 #4
0
def twogalaxies(name1, ra1, dec1, name2, ra2, dec2):
    name = "%s %s" % (name1, name2)
    ra = float(ra1)
    dec = float(dec1)
    ra2 = float(ra2)
    dec2 = float(dec2)
    remradius = 6.
    fieldradius = 6.
    threads = None
    itune1 = 5
    itune2 = 5
    ntune = 0
    nocache = True
    #Radius should be in arcminutes
    if threads:
        mp = multiproc(nthreads=threads)
    else:
        mp = multiproc()

    IRLS_scale = 25.
    dr9 = True
    dr8 = False
    noarcsinh = False
    print(name)

    prefix = '%s' % (name.replace(' ', '_'))
    prefix1 = '%s' % (name1.replace(' ', '_'))
    prefix2 = '%s' % (name2.replace(' ', '_'))
    print('Removal Radius', remradius)
    print('Field Radius', fieldradius)
    print('RA,Dec', ra, dec)

    print(os.getcwd())

    rcfs = radec_to_sdss_rcf(ra,
                             dec,
                             radius=math.hypot(fieldradius, 13. / 2.),
                             tablefn="dr9fields.fits")
    print(rcfs)
    assert (len(rcfs) > 0)
    assert (len(rcfs) < 15)

    sras, sdecs, smags = tychoMatch(ra, dec, (fieldradius * 1.5) / 60.)

    for sra, sdec, smag in zip(sras, sdecs, smags):
        print(sra, sdec, smag)

    imkw = dict(psf='dg')
    if dr9:
        getim = st.get_tractor_image_dr9
        getsrc = st.get_tractor_sources_dr9
        imkw.update(zrange=[-3, 100])
    elif dr8:
        getim = st.get_tractor_image_dr8
        getsrc = st.get_tractor_sources_dr8
        imkw.update(zrange=[-3, 100])
    else:
        getim = st.get_tractor_image
        getsrc = st.get_tractor_sources_dr8
        imkw.update(useMags=True)

    bands = ['u', 'g', 'r', 'i', 'z']
    bandname = 'r'
    flipBands = ['r']
    print(rcfs)

    imsrcs = mp.map(
        get_ims_and_srcs,
        [(rcf +
          (bands, ra, dec, fieldradius * 60. / 0.396, imkw, getim, getsrc))
         for rcf in rcfs])
    timgs = []
    sources = []
    allsources = []
    for ims, s in imsrcs:
        if ims is None:
            continue
        if s is None:
            continue
        timgs.extend(ims)
        allsources.extend(s)
        sources.append(s)

    #rds = [rcf[3:5] for rcf in rcfs]
    plotarea(ra, dec, fieldradius, name, prefix, timgs)  #, rds)
    lvl = logging.DEBUG
    logging.basicConfig(level=lvl, format='%(message)s', stream=sys.stdout)
    tractor = st.Tractor(timgs, allsources, mp=mp)

    sa = dict(debug=True, plotAll=False, plotBands=False)

    if noarcsinh:
        sa.update(nlscale=0)
    elif dr8 or dr9:
        sa.update(chilo=-8., chihi=8.)

    if nocache:
        tractor.cache = NullCache()
        sg.disable_galaxy_cache()

    zr = timgs[0].zr
    print("zr is: ", zr)

    print(bands)

    print("Number of images: ", len(timgs))
    #    for timg,band in zip(timgs,bands):
    #        data = timg.getImage()/np.sqrt(timg.getInvvar())
    #        plt.hist(data,bins=100)
    #        plt.savefig('hist-%s.png' % (band))

    saveAll('initial-' + prefix, tractor, **sa)
    #plotInvvar('initial-'+prefix,tractor)

    for sra, sdec, smag in zip(sras, sdecs, smags):
        print(sra, sdec, smag)

        for img in tractor.getImages():
            wcs = img.getWcs()
            starx, stary = wcs.positionToPixel(RaDecPos(sra, sdec))
            starr = 25 * (2**(max(11 - smag, 0.)))
            if starx + starr < 0. or starx - starr > img.getWidth(
            ) or stary + starr < 0. or stary - starr > img.getHeight():
                continue
            X, Y = np.meshgrid(np.arange(img.getWidth()),
                               np.arange(img.getHeight()))
            R2 = (X - starx)**2 + (Y - stary)**2
            img.getStarMask()[R2 < starr**2] = 0

    for timgs, sources in imsrcs:
        timg = timgs[0]
        wcs = timg.getWcs()
        xtr, ytr = wcs.positionToPixel(RaDecPos(ra, dec))

        print(xtr, ytr)

        xt = xtr
        yt = ytr
        r = ((remradius * 60.)) / .396  #radius in pixels
        for src in sources:
            xs, ys = wcs.positionToPixel(src.getPosition(), src)
            if (xs - xt)**2 + (ys - yt)**2 <= r**2:
                #print "Removed:", src
                #print xs,ys
                tractor.removeSource(src)

    #saveAll('removed-'+prefix, tractor,**sa)
    newShape = sg.GalaxyShape((remradius * 60.) / 10., 1., 0.)
    newBright = ba.Mags(r=15.0,
                        g=15.0,
                        u=15.0,
                        z=15.0,
                        i=15.0,
                        order=['u', 'g', 'r', 'i', 'z'])
    EG = st.ExpGalaxy(RaDecPos(ra, dec), newBright, newShape)
    newShape2 = sg.GalaxyShape((remradius * 60.) / 10., 1., 0.)
    newBright2 = ba.Mags(r=15.0,
                         g=15.0,
                         u=15.0,
                         z=15.0,
                         i=15.0,
                         order=['u', 'g', 'r', 'i', 'z'])
    EG2 = st.ExpGalaxy(RaDecPos(ra2, dec2), newBright2, newShape2)
    print(EG)
    print(EG2)
    tractor.addSource(EG)
    tractor.addSource(EG2)

    saveAll('added-' + prefix, tractor, **sa)

    #print 'Tractor has', tractor.getParamNames()

    for im in tractor.images:
        im.freezeAllParams()
        im.thawParam('sky')
    tractor.catalog.freezeAllBut(EG)
    tractor.catalog.thawParams(EG2)

    #print 'Tractor has', tractor.getParamNames()
    #print 'values', tractor.getParams()

    for i in range(itune1):
        tractor.optimize()
        tractor.changeInvvar(IRLS_scale)
        saveAll('itune1-%d-' % (i + 1) + prefix, tractor, **sa)
        tractor.clearCache()
        sg.get_galaxy_cache().clear()
        gc.collect()
        print(resource.getpagesize())
        print(resource.getrusage(resource.RUSAGE_SELF)[2])

    CGPos = EG.getPosition()
    CGShape1 = EG.getShape().copy()
    CGShape2 = EG.getShape().copy()
    EGBright = EG.getBrightness()

    CGu = EGBright[0] + 0.75
    CGg = EGBright[1] + 0.75
    CGr = EGBright[2] + 0.75
    CGi = EGBright[3] + 0.75
    CGz = EGBright[4] + 0.75
    CGBright1 = ba.Mags(r=CGr,
                        g=CGg,
                        u=CGu,
                        z=CGz,
                        i=CGi,
                        order=['u', 'g', 'r', 'i', 'z'])
    CGBright2 = ba.Mags(r=CGr,
                        g=CGg,
                        u=CGu,
                        z=CGz,
                        i=CGi,
                        order=['u', 'g', 'r', 'i', 'z'])
    print(EGBright)
    print(CGBright1)

    CG = st.CompositeGalaxy(CGPos, CGBright1, CGShape1, CGBright2, CGShape2)

    CG2Pos = EG2.getPosition()
    CG2Shape1 = EG2.getShape().copy()
    CG2Shape2 = EG2.getShape().copy()
    EG2Bright = EG2.getBrightness()

    CG2u = EG2Bright[0] + 0.75
    CG2g = EG2Bright[1] + 0.75
    CG2r = EG2Bright[2] + 0.75
    CG2i = EG2Bright[3] + 0.75
    CG2z = EG2Bright[4] + 0.75
    CG2Bright1 = ba.Mags(r=CG2r,
                         g=CG2g,
                         u=CG2u,
                         z=CG2z,
                         i=CG2i,
                         order=['u', 'g', 'r', 'i', 'z'])
    CG2Bright2 = ba.Mags(r=CG2r,
                         g=CG2g,
                         u=CG2u,
                         z=CG2z,
                         i=CG2i,
                         order=['u', 'g', 'r', 'i', 'z'])
    CG2 = st.CompositeGalaxy(CG2Pos, CG2Bright1, CG2Shape1, CG2Bright2,
                             CG2Shape2)

    tractor.removeSource(EG)
    tractor.removeSource(EG2)
    tractor.addSource(CG)
    tractor.addSource(CG2)

    tractor.catalog.freezeAllBut(CG)
    tractor.catalog.thawParams(CG2)
    print(resource.getpagesize())
    print(resource.getrusage(resource.RUSAGE_SELF)[2])

    for i in range(itune2):
        tractor.optimize()
        tractor.changeInvvar(IRLS_scale)
        saveAll('itune2-%d-' % (i + 1) + prefix, tractor, **sa)
        tractor.clearCache()
        sg.get_galaxy_cache().clear()
        print(resource.getpagesize())
        print(resource.getrusage(resource.RUSAGE_SELF)[2])

    tractor.catalog.thawAllParams()
    for i in range(ntune):
        tractor.optimize()
        tractor.changeInvvar(IRLS_scale)
        saveAll('ntune-%d-' % (i + 1) + prefix, tractor, **sa)
    #plotInvvar('final-'+prefix,tractor)
    sa.update(plotBands=True)
    saveAll('allBands-' + prefix, tractor, **sa)

    print(CG)
    print(CG.getPosition())
    print(CGBright1)
    print(CGBright2)
    print(CGShape1)
    print(CGShape2)
    print(CGBright1 + CGBright2)
    print(CG.getBrightness())

    pfn = '%s.pickle' % prefix
    pickle_to_file([CG, CG2], pfn)

    makeflipbook(prefix, len(tractor.getImages()), itune1, itune2, ntune)

    pickle_to_file(CG, "%s.pickle" % prefix1)
    pickle_to_file(CG2, "%s.pickle" % prefix2)
    os.system('cp %s.pickle RC3_Output' % prefix1)
    os.system('cp %s.pickle RC3_Output' % prefix2)
コード例 #5
0
def general(name,
            ra,
            dec,
            remradius,
            fieldradius,
            threads=None,
            itune1=5,
            itune2=5,
            ntune=0,
            nocache=False,
            scale=1,
            ab=1.,
            angle=0.):
    #Radius should be in arcminutes
    if threads:
        mp = multiproc(nthreads=threads)
    else:
        mp = multiproc()

    IRLS_scale = 25.
    dr9 = True
    dr8 = False
    noarcsinh = False
    print name

    prefix = 'swapCG_%s' % (name.replace(' ', '_'))
    print 'Removal Radius', remradius
    print 'Field Radius', fieldradius
    print 'RA,Dec', ra, dec

    print os.getcwd()
    print ra, dec, math.hypot(fieldradius, 13. / 2.)

    rcfs = radec_to_sdss_rcf(ra,
                             dec,
                             radius=math.hypot(fieldradius, 13. / 2.),
                             tablefn="dr9fields.fits")
    print 'RCFS:', rcfs
    print len(rcfs)
    assert (len(rcfs) > 0)
    if 10 <= len(rcfs) < 20:
        scale = 2
    elif 20 <= len(rcfs) < 40:
        scale = 4
    elif 40 <= len(rcfs) < 80:
        scale = 8
    assert (len(rcfs) < 80)

    sras, sdecs, smags = tychoMatch(ra, dec, (fieldradius * 1.5) / 60.)

    imkw = dict(psf='kl-gm')
    if dr9:
        getim = st.get_tractor_image_dr9
        getsrc = st.get_tractor_sources_dr9
        imkw.update(zrange=[-3, 100])
    elif dr8:
        getim = st.get_tractor_image_dr8
        getsrc = st.get_tractor_sources_dr8
        imkw.update(zrange=[-3, 100])
    else:
        getim = st.get_tractor_image
        getsrc = st.get_tractor_sources_dr8
        imkw.update(useMags=True)

    bands = ['u', 'g', 'r', 'i', 'z']
    #bands=['r']
    bandname = 'r'
    flipBands = ['r']
    print rcfs

    imsrcs = mp.map(
        get_ims_and_srcs,
        [(rcf +
          (bands, ra, dec, fieldradius * 60. / 0.396, imkw, getim, getsrc))
         for rcf in rcfs])
    timgs = []
    sources = []
    allsources = []
    for ims, s in imsrcs:
        if ims is None:
            continue
        if s is None:
            continue
        if scale > 1:
            for im in ims:
                timgs.append(st.scale_sdss_image(im, scale))
        else:
            timgs.extend(ims)
        allsources.extend(s)
        sources.append(s)

    #rds = [rcf[3:5] for rcf in rcfs]
    #plotarea(ra, dec, fieldradius, name, prefix, timgs) #, rds)

    #lvl = logging.DEBUG
    #logging.basicConfig(level=lvl,format='%(message)s',stream=sys.stdout)
    tractor = st.Tractor(timgs, allsources, mp=mp)

    sa = dict(debug=True, plotAll=False, plotBands=False)

    if noarcsinh:
        sa.update(nlscale=0)
    elif dr8 or dr9:
        sa.update(chilo=-8., chihi=8.)

    if nocache:
        tractor.cache = NullCache()
        sg.disable_galaxy_cache()

    zr = timgs[0].zr
    print "zr is: ", zr

    print bands

    print "Number of images: ", len(timgs)
    #for timg,band in zip(timgs,bands):
    #    data = timg.getImage()/np.sqrt(timg.getInvvar())
    #    plt.hist(data,bins=100)
    #    plt.savefig('hist-%s.png' % (band))

    saveAll('initial-' + prefix, tractor, **sa)
    #plotInvvar('initial-'+prefix,tractor)

    for sra, sdec, smag in zip(sras, sdecs, smags):

        for img in tractor.getImages():
            wcs = img.getWcs()
            starx, stary = wcs.positionToPixel(RaDecPos(sra, sdec))
            starr = 25 * (2**(max(11 - smag, 0.)))
            if starx + starr < 0. or starx - starr > img.getWidth(
            ) or stary + starr < 0. or stary - starr > img.getHeight():
                continue
            X, Y = np.meshgrid(np.arange(img.getWidth()),
                               np.arange(img.getHeight()))
            R2 = (X - starx)**2 + (Y - stary)**2
            img.getStarMask()[R2 < starr**2] = 0

    for timgs, sources in imsrcs:
        timg = timgs[0]
        wcs = timg.getWcs()
        xtr, ytr = wcs.positionToPixel(RaDecPos(ra, dec))

        xt = xtr
        yt = ytr
        r = ((remradius * 60.)) / .396  #radius in pixels
        for src in sources:
            xs, ys = wcs.positionToPixel(src.getPosition(), src)
            if (xs - xt)**2 + (ys - yt)**2 <= r**2:
                #print "Removed:", src
                #print xs,ys
                tractor.removeSource(src)

    #saveAll('removed-'+prefix, tractor,**sa)
    newShape = sg.GalaxyShape((remradius * 60.) / 10., ab, angle)
    newBright = ba.Mags(r=15.0,
                        g=15.0,
                        u=15.0,
                        z=15.0,
                        i=15.0,
                        order=['u', 'g', 'r', 'i', 'z'])
    EG = st.ExpGalaxy(RaDecPos(ra, dec), newBright, newShape)
    print EG
    tractor.addSource(EG)

    saveAll('added-' + prefix, tractor, **sa)

    #print 'Tractor has', tractor.getParamNames()

    for im in tractor.images:
        im.freezeAllParams()
        im.thawParam('sky')
    tractor.catalog.freezeAllBut(EG)

    #print 'Tractor has', tractor.getParamNames()
    #print 'values', tractor.getParams()

    for i in range(itune1):
        tractor.optimize()
        tractor.changeInvvar(IRLS_scale)
        saveAll('itune1-%d-' % (i + 1) + prefix, tractor, **sa)
        tractor.clearCache()
        sg.get_galaxy_cache().clear()
        gc.collect()
        print resource.getpagesize()
        print resource.getrusage(resource.RUSAGE_SELF)[2]

    CGPos = EG.getPosition()
    CGShape1 = EG.getShape().copy()
    CGShape2 = EG.getShape().copy()
    EGBright = EG.getBrightness()

    CGu = EGBright[0] + 0.75
    CGg = EGBright[1] + 0.75
    CGr = EGBright[2] + 0.75
    CGi = EGBright[3] + 0.75
    CGz = EGBright[4] + 0.75
    CGBright1 = ba.Mags(r=CGr,
                        g=CGg,
                        u=CGu,
                        z=CGz,
                        i=CGi,
                        order=['u', 'g', 'r', 'i', 'z'])
    CGBright2 = ba.Mags(r=CGr,
                        g=CGg,
                        u=CGu,
                        z=CGz,
                        i=CGi,
                        order=['u', 'g', 'r', 'i', 'z'])
    print EGBright
    print CGBright1

    CG = st.CompositeGalaxy(CGPos, CGBright1, CGShape1, CGBright2, CGShape2)

    tractor.removeSource(EG)
    tractor.addSource(CG)

    tractor.catalog.freezeAllBut(CG)
    print resource.getpagesize()
    print resource.getrusage(resource.RUSAGE_SELF)[2]

    for i in range(itune2):
        tractor.optimize()
        tractor.changeInvvar(IRLS_scale)
        saveAll('itune2-%d-' % (i + 1) + prefix, tractor, **sa)
        tractor.clearCache()
        sg.get_galaxy_cache().clear()
        print resource.getpagesize()
        print resource.getrusage(resource.RUSAGE_SELF)[2]

    tractor.catalog.thawAllParams()
    for i in range(ntune):
        tractor.optimize()
        tractor.changeInvvar(IRLS_scale)
        saveAll('ntune-%d-' % (i + 1) + prefix, tractor, **sa)
    #plotInvvar('final-'+prefix,tractor)
    sa.update(plotBands=True)
    saveAll('allBands-' + prefix, tractor, **sa)

    print "end of first round of optimization:", tractor.getLogLikelihood()
    print CG
    print CG.getPosition()
    print CGBright1
    print CGBright2
    print CGShape1
    print CGShape2
    print CGBright1 + CGBright2
    print CG.getBrightness()

    pfn = '%s.pickle' % prefix
    pickle_to_file(CG, pfn)

    makeflipbook(prefix, len(tractor.getImages()), itune1, itune2, ntune)

    # now SWAP exp and dev and DO IT AGAIN
    newCG = st.CompositeGalaxy(CG.getPosition, CG.brightnessDev.copy(),
                               CG.shapeDev.copy(), CG.brightnessExp.copy(),
                               CG.shapeExp.copy())
    tractor.removeSource(CG)
    tractor.addSource(newCG)

    tractor.catalog.thawAllParams()
    for i in range(ntune):
        tractor.optimize()
        tractor.changeInvvar(IRLS_scale)
        saveAll('ntune-swap-%d-' % (i + 1) + prefix, tractor, **sa)
    #plotInvvar('final-'+prefix,tractor)
    sa.update(plotBands=True)
    saveAll('allBands-swap-' + prefix, tractor, **sa)

    print "end of second (swapped) round of optimization:", tractor.getLogLikelihood(
    )
    print newCG
    print newCG.getPosition()
    print newCG.getBrightness()

    pfn = '%s-swap.pickle' % prefix
    pickle_to_file(newCG, pfn)

    makeflipbook(prefix + "-swap", len(tractor.getImages()), itune1, itune2,
                 ntune)