예제 #1
0
파일: ModLinAlg.py 프로젝트: saopicc/killMS
def invSVD(A):


    try:
        u,s,v=np.linalg.svd(np.complex128(A))#+np.random.randn(*A.shape)*(1e-6*A.max()))
    except:
        Name="errSVDArray_%i"%int(np.random.rand(1)[0]*10000)
        print(ModColor.Str("Problem inverting Matrix, saving as %s"%Name))
        print(ModColor.Str("  will make it svd-able"))
        np.save(Name,A)
        # weird - I found a matrix I cannot do svd on... - that works
        Cut=1e-20
        #Ar=np.complex64(Ar)
        u,s,v=np.linalg.svd(np.complex128(A)+np.random.randn(*A.shape)*(1e-10*np.abs(A).max()))


    #s[s<0.]=1.e-6
    s0=s.copy()
    Th=1e-10
    s[s<Th*s.max()]=Th*s.max()
    ssq=(1./s)
    #Asq=np.conj(np.dot(np.dot(v.T,ssq),u.T))
    v0=v.T*ssq.reshape(1,ssq.size)
    Asq=np.conj(np.dot(v0,u.T))
    #PlotMatSVD(A,s0.flatten(),Asq)
    return Asq
예제 #2
0
파일: ClassMS.py 프로젝트: saopicc/killMS
    def __str__(self):
        ll = []
        ll.append(ModColor.Str(" MS PROPERTIES: "))
        ll.append("   - File Name: %s" %
                  ModColor.Str(self.MSName, col="green"))
        ll.append("   - Column Name: %s" %
                  ModColor.Str(str(self.ColName), col="green"))
        ll.append("   - Selection: %s" %
                  (ModColor.Str(str(self.TaQL), col="green")))
        ll.append("   - Pointing center: (ra, dec)=(%s, %s) "%(rad2hmsdms(self.rarad,Type="ra").replace(" ",":")\
                                                               ,rad2hmsdms(self.decrad,Type="dec").replace(" ",".")))
        ll.append("   - Frequency = %s MHz" % str(self.reffreq / 1e6))
        ll.append("   - Wavelength = %5.2f meters" %
                  (np.mean(self.wavelength_chan)))
        ll.append("   - Time bin = %4.1f seconds" % (self.dt))
        ll.append("   - Total Integration time = %6.2f hours" % self.DTh)
        ll.append("   - Number of antenna  = %i" % self.na)
        ll.append("   - Number of baseline = %i" % self.nbl)
        ll.append("   - Number of SPW = %i" % self.NSPW)
        ll.append("   - Number of channels = %i" % self.Nchan)

        s = " ".join(["%.2f" % (x / 1e6) for x in self.ChanFreq.flatten()])
        #ll.append("   - Chan freqs = %s"%(ListToStr(s.split(" "),Unit="MHz")))

        ss = "\n".join(ll) + "\n"
        return ss
예제 #3
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 def Print2(self,par,value,helpit,col="white"):
     WidthTerm=self.getWidth()
     Lpar=len(str(par))
     Lval=len(str(value))
     SFill="."*max(self.LeftW-self.Lproto-Lpar-Lval,2)
     WidthHelp=WidthTerm-(self.Lproto+Lpar+Lval+len(SFill))
     Spar="%s"%ModColor.Str(str(par),col=col,Bold=False)
     Sval="%s"%ModColor.Str(str(value),col=col,Bold=False)
     if helpit=="":
         helpit="Help yourself"
     Shelp="%s"%helpit
     if WidthHelp<0:
          print(self.proto%(Spar,SFill,Sval)+Shelp)
          return
     Lhelp=len(str(helpit))
     listStrHelp=range(0,Lhelp,WidthHelp)
     
     if listStrHelp[-1]!=Lhelp: listStrHelp.append(Lhelp)
     
     
     
     print(self.proto%(Spar,SFill,Sval)+Shelp[0:WidthHelp])
     for i in range(1,len(listStrHelp)-1):
         parout="%s: %s"%(" "*(self.LeftW-2),Shelp[listStrHelp[i]:listStrHelp[i+1]])
         print(parout)
예제 #4
0
파일: ClassMS.py 프로젝트: saopicc/killMS
    def SaveVis(self, vis=None, Col="CORRECTED_DATA", spw=0, DoPrint=True):
        if vis == None:
            vis = self.data
        if DoPrint:
            log.print("Writing data in column %s" %
                      ModColor.Str(Col, col="green"))

        print("Givemain")
        table_all = self.GiveMainTable(readonly=False)

        if self.swapped:
            visout = np.swapaxes(vis[spw * self.Nchan:(spw + 1) * self.Nchan],
                                 0, 1)
            flag_all = np.swapaxes(
                self.flag_all[spw * self.Nchan:(spw + 1) * self.Nchan], 0, 1)
        else:
            visout = vis
            flag_all = self.flag_all

        print("Col")
        table_all.putcol(Col, visout.astype(self.data.dtype), self.ROW0,
                         self.nRowRead)
        print("Flag")
        table_all.putcol("FLAG", flag_all, self.ROW0, self.nRowRead)
        print("Weight")
        if self.HasWeights:

            table_all.putcol("WEIGHT", self.Weights, self.ROW0, self.nRowRead)
            #print("ok w")
        print("Close")
        table_all.close()
예제 #5
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def SharedToDico(Prefix):
    log.print(ModColor.Str("SharedToDico: start [prefix = %s]" % Prefix))
    T = ClassTimeIt.ClassTimeIt("   SharedToDico")
    T.disable()
    Lnames = ListNames()
    T.timeit("0: ListNames")
    keys = [Name for Name in Lnames if Prefix in Name]
    if len(keys) == 0: return None
    DicoOut = {}
    T.timeit("1")
    for Sharedkey in keys:
        key = Sharedkey.split(".")[-1]
        log.print(ModColor.Str("  %s -> %s" % (Sharedkey, key)))
        Shared = GiveArray(Sharedkey)
        DicoOut[key] = Shared
    T.timeit("2a")
    log.print(ModColor.Str("SharedToDico: done"))

    return DicoOut
예제 #6
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def SharedObjectToDico(SObject):
    if SObject == None: return None
    Prefix = SObject.prefixName
    Fields = SObject.DicoKeys
    log.print(ModColor.Str("SharedToDico: start [prefix = %s]" % Prefix))
    T = ClassTimeIt.ClassTimeIt("   SharedToDico")
    T.disable()

    DicoOut = {}
    T.timeit("1")
    for field in Fields:
        Sharedkey = "%s.%s" % (Prefix, field)
        #log.print( ModColor.Str("  %s -> %s"%(Sharedkey,key)))
        Shared = GiveArray(Sharedkey)
        DicoOut[field] = Shared
    T.timeit("2a")
    log.print(ModColor.Str("SharedToDico: done"))

    return DicoOut
예제 #7
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def DicoToShared(Prefix, Dico, DelInput=False):
    DicoOut = {}
    log.print(ModColor.Str("DicoToShared: start [prefix = %s]" % Prefix))
    for key in Dico.keys():
        if type(Dico[key]) != np.ndarray: continue
        #print "%s.%s"%(Prefix,key)
        ThisKeyPrefix = "%s.%s" % (Prefix, key)
        log.print(ModColor.Str("  %s -> %s" % (key, ThisKeyPrefix)))
        ar = Dico[key]
        Shared = ToShared(ThisKeyPrefix, ar)
        #T.timeit("getarray %s"%ThisKeyPrefix)
        DicoOut[key] = Shared
        if DelInput:
            del (Dico[key], ar)

    if DelInput:
        del (Dico)
    log.print(ModColor.Str("DicoToShared: done"))

    return DicoOut
예제 #8
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def ToShared(Name, A):

    try:
        a = SharedArray.create(Name, A.shape, dtype=A.dtype)
    except:
        log.print(ModColor.Str("File %s exists, delete it..." % Name))
        #DelArray(Name.decode("byte"))
        DelArray(Name)
        a = SharedArray.create(Name, A.shape, dtype=A.dtype)

    a[:] = A[:]
    return a
예제 #9
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    def __init__(self, BaseImageName, VS, IdSharedMem, *args, **kwargs):
        ClassImagerDeconv.__init__(self, **kwargs)

        self.BaseImageName = BaseImageName

        self.FileDicoModel = "%s.DicoModel" % self.BaseImageName
        if self.GD["GDkMS"]["ImageSkyModel"]["DicoModel"] is not None:
            log.print(
                ModColor.Str("Using %s instead of %s" %
                             (self.GD["GDkMS"]["ImageSkyModel"]["DicoModel"],
                              self.FileDicoModel)))
            self.FileDicoModel = self.GD["GDkMS"]["ImageSkyModel"]["DicoModel"]

        self.ModelImageName = "%s.model.fits" % self.BaseImageName

        self.VS = VS

        if self.GD["CF"]["wmax"] == 0:
            log.print("Computing wmax from UVW column")
            t = table(self.VS.ListMS[0].MSName, ack=False)
            u, v, w = t.getcol("UVW").T
            t.close()
            self.GD["CF"]["wmax"] = np.max(np.abs(w))
            log.print("  found a wmax=%f meters" % self.GD["CF"]["wmax"])

        # DC=self.GD
        # MSName=DC["VisData"]["MSName"]
        # self.VS=ClassVisServer.ClassVisServer(MSName,
        #                                       ColName=DC["VisData"]["ColName"],
        #                                       TVisSizeMin=DC["VisData"]["TChunkSize"]*60,
        #                                       #DicoSelectOptions=DicoSelectOptions,
        #                                       TChunkSize=DC["VisData"]["TChunkSize"],
        #                                       IdSharedMem=self.IdSharedMem,
        #                                       Robust=DC["ImagerGlobal"]["Robust"],
        #                                       Weighting=DC["ImagerGlobal"]["Weighting"],
        #                                       Super=DC["ImagerGlobal"]["Super"],
        #                                       DicoSelectOptions=dict(DC["DataSelection"]),
        #                                       NCPU=self.GD["Parallel"]["NCPU"],
        #                                       GD=self.GD)

        #self.GD["GAClean"]["GASolvePars"]=["S","Alpha"]

        self.IdSharedMem = IdSharedMem  #kwargs["IdSharedMem"]
        self.SM = ClassImageSM()

        if self.GD["GDkMS"]["ImageSkyModel"]["NodesFile"] is not None:
            self.GD["Facets"]["CatNodes"] = self.GD["GDkMS"]["ImageSkyModel"][
                "NodesFile"]
            self.GD["DDESolutions"]["DDSols"] = None

        # self.InitFacetMachine()
        self.CreateFacetMachines()
        self.LoadModel()
예제 #10
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def print_logo():

    #os.system('clear')
                                                       
    version=report_version()

    print("""       __        _   __   __   ____    ____   ______     """)
    print("""      [  |  _   (_) [  | [  | |_   \  /   _|.' ____ \    """)
    print("""       | | / ]  __   | |  | |   |   \/   |  | (___ \_|   """)
    print("""       | '' <  [  |  | |  | |   | |\  /| |   _.____`.    """)
    print("""       | |`\ \  | |  | |  | |  _| |_\/_| |_ | \____) |   """)
    print("""      [__|  \_][___][___][___]|_____||_____| \______.'   """)
    print("""             This is version : %s""" %ModColor.Str(version))
    print("""                                                        """)
예제 #11
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def PrintOptParse(Obj, ValObj, RejectGroup=[]):
    P = ClassPrint.ClassPrint(HW=30)
    LGroups = Obj.option_groups
    print(ModColor.Str(" Selected Options:"))

    for Group in LGroups:
        Skip = False
        for Name in RejectGroup:
            if Name in Group.title:
                Skip = True

        if Skip: continue
        print(ModColor.Str(Group.title, col="green"))

        option_list = Group.option_list
        for o in option_list:
            lopt = o._long_opts[0]
            oname = lopt.split("--")[-1]

            V = getattr(ValObj, oname)
            #            if (V!="")&(V!=None):
            if True:  #V!="":
                if V == "": V = "''"

                #P.Print(oname,V)
                default = o.default
                H = o.help
                # if H!=None:
                #     H=o.help.replace("%default",str(default))
                #     P.Print2(oname,V,H)
                # else:
                #     P.Print(oname,V)
                P.Print(oname, V)

                # strName=%s
                # print "       "oname,V
        print()
예제 #12
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    def Print(self, RejectGroup=[]):
        P = ClassPrint.ClassPrint(HW=50)
        print(ModColor.Str(" Selected Options:"))

        for Group, V in self.DefaultDict.items():
            Skip = False
            for Name in RejectGroup:
                if Name in Group:
                    Skip = True
            if Skip: continue
            try:
                GroupTitle = self.DicoGroupDesc[Group]
            except:
                GroupTitle = Group
            print(ModColor.Str(GroupTitle, col="green"))

            option_list = self.DefaultDict[Group]
            for oname in option_list:
                V = self.DefaultDict[Group][oname]

                if True:  #V!="":
                    if V == "": V = "''"
                    P.Print(oname, V)
            print()
예제 #13
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    def ReClusterSkyModel(self, SM, MSName):
        SolRefFile = self.GD["PreApply"]["PreApplySols"][0]

        if (SolRefFile != "") & (not (".npz" in SolRefFile)):
            Method = SolRefFile
            ThisMSName = reformat.reformat(os.path.abspath(MSName),
                                           LastSlash=False)
            SolRefFile = "%s/killMS.%s.sols.npz" % (ThisMSName, Method)

        log.print(
            ModColor.Str(
                "Re-clustering input SkyModel to match %s clustering" %
                SolRefFile))

        ClusterCat0 = np.load(SolRefFile)["ClusterCat"]
        ClusterCat0 = ClusterCat0.view(np.recarray)

        lc = ClusterCat0.l
        mc = ClusterCat0.m
        lc = lc.reshape((1, lc.size))
        mc = mc.reshape((1, mc.size))

        l = SM.SourceCat.l
        m = SM.SourceCat.m
        l = l.reshape((l.size, 1))
        m = m.reshape((m.size, 1))
        d = np.sqrt((l - lc)**2 + (m - mc)**2)
        Cluster = np.argmin(d, axis=1)
        #print SM.SourceCat.Cluster
        SM.SourceCat.Cluster[:] = Cluster[:]
        SM.ClusterCat = ClusterCat0
        #print SM.SourceCat.Cluster

        SM.Dirs = sorted(list(set(SM.SourceCat.Cluster.tolist())))
        SM.NDir = len(SM.Dirs)

        log.print("  There are %i clusters in the re-clustered skymodel" %
                  SM.NDir)

        NDir = lc.size
        for iDir in range(NDir):
            ind = (SM.SourceCat.Cluster == iDir)
            SM.ClusterCat.SumI[iDir] = np.sum(SM.SourceCat.I[ind])
예제 #14
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# test

#import numpy
#print numpy.__file__
#import pyrap
#print pyrap.__file__
#stop

if "nocol" in sys.argv:
    print("nocol")
    ModColor.silent = 1
if "nox" in sys.argv:
    import matplotlib
    matplotlib.use('agg')
    print(ModColor.Str(" == !NOX! =="))

import time
import os
import numpy as np
import pickle
from itertools import product as ItP

NameSave = "last_plotSols.obj"


def read_options():

    desc = """killMS Questions and suggestions: [email protected]"""

    opt = optparse.OptionParser(
예제 #15
0
파일: ClassMS.py 프로젝트: saopicc/killMS
    def ReadMSInfo(self, MSname, DoPrint=True):
        T = ClassTimeIt.ClassTimeIt()
        T.enableIncr()
        T.disable()
        #print(MSname+'/ANTENNA')

        # open main table
        table_all = table(MSname, ack=False)

        #print(MSname+'/ANTENNA')
        ta = table(table_all.getkeyword('ANTENNA'), ack=False)
        #ta=table(MSname+'::ANTENNA',ack=False)

        StationNames = ta.getcol('NAME')

        na = ta.getcol('POSITION').shape[0]
        self.StationPos = ta.getcol('POSITION')
        #nbl=(na*(na-1))/2+na

        A0, A1 = table_all.getcol("ANTENNA1"), table_all.getcol("ANTENNA2")
        ind = np.where(A0 == A1)[0]
        self.HasAutoCorr = (ind.size > 0)
        A = np.concatenate([A0, A1])

        nas = np.unique(A).size
        self.nbl = (nas**2 - nas) // 2
        if self.HasAutoCorr:
            self.nbl += nas
        if A0.size % self.nbl != 0:
            log.print(ModColor.Str("MS is non conformant!"))
            raise

        #nbl=(na*(na-1))/2
        ta.close()
        T.timeit()

        #table_all=table(MSname,ack=False)
        self.ColNames = table_all.colnames()
        TimeIntervals = table_all.getcol("INTERVAL")
        SPW = table_all.getcol('DATA_DESC_ID')
        if self.SelectSPW != None:
            self.ListSPW = self.SelectSPW
            #print("dosel")
        else:
            self.ListSPW = sorted(list(set(SPW.tolist())))
        T.timeit()

        self.F_nrows = table_all.getcol("TIME").shape[0]
        F_time_all = table_all.getcol("TIME")[SPW == self.ListSPW[0]]

        self.F_A0 = table_all.getcol("ANTENNA1")[SPW == self.ListSPW[0]]
        self.F_A1 = table_all.getcol("ANTENNA2")[SPW == self.ListSPW[0]]

        #nbl=(np.where(F_time_all==F_time_all[0])[0]).shape[0]
        T.timeit()

        F_time_slots_all = np.array(sorted(list(set(F_time_all.tolist()))))
        F_ntimes = F_time_slots_all.shape[0]

        T.timeit()

        ta_spectral = table(table_all.getkeyword('SPECTRAL_WINDOW'), ack=False)
        reffreq = ta_spectral.getcol('REF_FREQUENCY')
        chan_freq = ta_spectral.getcol('CHAN_FREQ')
        self.NChanOrig = chan_freq.size
        chan_freq = chan_freq[:, self.ChanSlice]
        self.dFreq = ta_spectral.getcol("CHAN_WIDTH").flatten()[self.ChanSlice]
        self.ChanWidth = ta_spectral.getcol('CHAN_WIDTH')[:, self.ChanSlice]
        if chan_freq.shape[0] > len(self.ListSPW):
            print(
                ModColor.Str(
                    "  ====================== >> More SPW in headers, modifying that error...."
                ))
            chan_freq = chan_freq[np.array(self.ListSPW), :]
            reffreq = reffreq[np.array(self.ListSPW)]

        T.timeit()

        wavelength = 299792456. / reffreq
        NSPW = chan_freq.shape[0]
        self.ChanFreq = chan_freq
        self.Freq_Mean = np.mean(chan_freq)
        wavelength_chan = 299792456. / chan_freq

        if NSPW > 1:
            print("Don't deal with multiple SPW yet")

        Nchan = wavelength_chan.shape[1]
        NSPWChan = NSPW * Nchan
        ta = table(table_all.getkeyword('FIELD'), ack=False)
        rarad, decrad = ta.getcol('PHASE_DIR')[self.Field][0]
        if rarad < 0.: rarad += 2. * np.pi

        T.timeit()

        radeg = rarad * 180. / np.pi
        decdeg = decrad * 180. / np.pi
        ta.close()

        self.DoRevertChans = False
        if Nchan > 1:
            self.DoRevertChans = (self.ChanFreq.flatten()[0] >
                                  self.ChanFreq.flatten()[-1])
        if self.DoRevertChans:
            log.print(
                ModColor.Str(
                    "  ====================== >> Revert Channel order!"))
            wavelength_chan = wavelength_chan[0, ::-1]
            self.ChanFreq = self.ChanFreq[0, ::-1]
            self.ChanWidth = -self.ChanWidth[0, ::-1]
            self.dFreq = np.abs(self.dFreq)

        T.timeit()

        MS_STOKES_ENUMS = [
            "Undefined", "I", "Q", "U", "V", "RR", "RL", "LR", "LL", "XX",
            "XY", "YX", "YY", "RX", "RY", "LX", "LY", "XR", "XL", "YR", "YL",
            "PP", "PQ", "QP", "QQ", "RCircular", "LCircular", "Linear",
            "Ptotal", "Plinear", "PFtotal", "PFlinear", "Pangle"
        ]
        tp = table(table_all.getkeyword('POLARIZATION'), ack=False)
        # get list of corrype enums for first row of polarization table, and convert to strings via MS_STOKES_ENUMS.
        # self.CorrelationNames will be a list of strings
        self.CorrelationIds = tp.getcol('CORR_TYPE', 0, 1)[0]
        self.CorrelationNames = [(ctype >= 0 and ctype < len(MS_STOKES_ENUMS)
                                  and MS_STOKES_ENUMS[ctype]) or None
                                 for ctype in self.CorrelationIds]
        self.Ncorr = len(self.CorrelationNames)
        # NB: it is possible for the MS to have different polarization

        table_all.close()

        self.na = na
        self.Nchan = Nchan
        self.NSPW = NSPW
        self.NSPWChan = NSPWChan
        self.F_tstart = F_time_all[0]
        self.F_times_all = F_time_all
        self.F_times = F_time_slots_all
        self.F_ntimes = F_time_slots_all.shape[0]

        self.dt = TimeIntervals[0]
        self.DTs = F_time_all[-1] - F_time_all[0] + self.dt
        self.DTh = self.DTs / 3600.

        self.radec = self.OriginalRadec = (rarad, decrad)
        self.rarad = rarad
        self.decrad = decrad
        self.reffreq = reffreq
        self.StationNames = StationNames
        self.wavelength_chan = wavelength_chan
        self.rac = rarad
        self.decc = decrad
        #self.nbl=nbl
        self.StrRA = rad2hmsdms(self.rarad, Type="ra").replace(" ", ":")
        self.StrDEC = rad2hmsdms(self.decrad, Type="dec").replace(" ", ".")

        if self.ToRADEC is not None:
            ranew, decnew = rarad, decrad
            # get RA/Dec from first MS, or else parse as coordinate string
            if self.ToRADEC == "align":
                stop
                if first_ms is not None:
                    ranew, decnew = first_ms.rarad, first_ms.decrad
                which = "the common phase centre"
            else:
                which = "%s %s" % tuple(self.ToRADEC)
                SRa, SDec = self.ToRADEC
                srah, sram, sras = SRa.split(":")
                sdecd, sdecm, sdecs = SDec.split(":")
                ranew = (np.pi / 180) * 15. * (
                    float(srah) + float(sram) / 60. + float(sras) / 3600.)
                decnew = (np.pi / 180) * np.sign(float(sdecd)) * (abs(
                    float(sdecd)) + float(sdecm) / 60. + float(sdecs) / 3600.)
            # only enable rotation if coordinates actually change
            if ranew != rarad or decnew != decrad:
                print(ModColor.Str("MS %s will be rephased to %s" %
                                   (self.MSName, which)),
                      file=log)
                self.OldRadec = rarad, decrad
                self.NewRadec = ranew, decnew
                rarad, decrad = ranew, decnew
            else:
                self.ToRADEC = None

        T.timeit()
예제 #16
0
파일: ClassMS.py 프로젝트: saopicc/killMS
    def ReadData(self, t0=0, t1=-1, DoPrint=False, ReadWeight=False):

        if DoPrint == True:
            print("   ... Reading MS")

        # TODO: read this from MS properly, as in DDFacet
        self.CorrelationNames = "xx", "xy", "yx", "yy"

        row0 = 0
        row1 = self.F_nrows

        DATA_CHUNK = {}
        if t1 > t0:

            t0 = t0 * 3600.
            t1 = t1 * 3600.
            self.CurrentChunkTimeRange_SinceT0_sec = (t0, t1)
            t0 = t0 + self.F_tstart
            t1 = t1 + self.F_tstart

            #ind0=np.argmin(np.abs(t0-self.F_times))
            #ind1=np.argmin(np.abs(t1-self.F_times))

            # ind0=np.where((t0-self.F_times)<=0)[0][0]
            # row0=ind0*self.nbl
            # ind1=np.where((t1-self.F_times)<0)[0]
            # if ind1.size==0:
            #     row1=self.F_nrows
            # else:
            #     ind1=ind1[0]
            #     row1=ind1*self.nbl

            ind = np.where((self.F_times_all >= t0)
                           & (self.F_times_all < t1))[0]

            if ind.size == 0:
                return None
                # row0=self.ROW1
                # row1=row0
            else:
                row0 = ind[0]
                ind1 = row0 + ind.size
                row1 = ind1

        # print("!!!!!!!=======")
        # row0,row1=1207458, 1589742
        self.ROW0 = row0
        self.ROW1 = row1
        self.nRowRead = row1 - row0

        # if chunk is empty, return None
        if self.nRowRead <= 0:
            return None

        log.print("   Reading rows [%i -> %i]" % (self.ROW0, self.ROW1))
        DATA_CHUNK["ROW0"] = row0
        DATA_CHUNK["ROW1"] = row1
        DATA_CHUNK["nRowRead"] = self.nRowRead

        nRowRead = self.nRowRead

        #table_all=table(self.MSName,ack=False)
        table_all = self.GiveMainTable()
        try:
            SPW = table_all.getcol('DATA_DESC_ID', row0, nRowRead)
        except Exception as e:
            log.print(
                ModColor.Str("There was a problem reading DATA_DESC_ID:" +
                             str(e)))
            DATA_DESC_ID = np.unique(table_all.getcol('DATA_DESC_ID'))
            if DATA_DESC_ID.size == 1:
                log.print(
                    ModColor.Str(
                        "   All DATA_DESC_ID are the same, can proceed"))
                SPW = np.zeros((nRowRead, ), )
                SPW.fill(DATA_DESC_ID[0])
            else:
                raise
        A0 = table_all.getcol('ANTENNA1', row0,
                              nRowRead)[SPW == self.ListSPW[0]]
        A1 = table_all.getcol('ANTENNA2', row0,
                              nRowRead)[SPW == self.ListSPW[0]]
        #print(self.ListSPW[0])
        time_all = table_all.getcol("TIME", row0,
                                    nRowRead)[SPW == self.ListSPW[0]]
        self.Time0 = table_all.getcol("TIME", 0, 1)[0]
        #print(np.max(time_all)-np.min(time_all))
        time_slots_all = np.array(sorted(list(set(time_all))))
        ntimes = time_all.shape[0] / self.nbl

        flag_all = table_all.getcol(
            "FLAG", row0, nRowRead)[SPW == self.ListSPW[0]][:,
                                                            self.ChanSlice, :]

        self.HasWeights = False
        if ReadWeight == True:
            self.Weights = table_all.getcol("WEIGHT", row0, nRowRead)
            self.HasWeights = True

        if self.EqualizeFlag:
            for i in range(self.Nchan):
                fcol = flag_all[:, i,
                                0] | flag_all[:, i,
                                              1] | flag_all[:, i,
                                                            2] | flag_all[:, i,
                                                                          3]
                for pol in range(4):
                    flag_all[:, i, pol] = fcol

        self.multidata = (type(self.ColName) == list)
        self.ReverseAntOrder = (np.where((A0 == 0)
                                         & (A1 == 1))[0]).shape[0] > 0
        self.swapped = False

        uvw = table_all.getcol('UVW', row0, nRowRead)[SPW == self.ListSPW[0]]
        self.TimeInterVal = table_all.getcol("INTERVAL")

        if self.ReOrder:
            vis_all = table_all.getcol(self.ColName, row0,
                                       nRowRead)[:, self.ChanSlice, :]
            if self.zero_flag: vis_all[flag_all == 1] = 0.
            if self.zero_flag:
                noise=(np.random.randn(vis_all.shape[0],vis_all.shape[1],vis_all.shape[2])\
                           +1j*np.random.randn(vis_all.shape[0],vis_all.shape[1],vis_all.shape[2]))*1e-6
                vis_all[flag_all == 1] = noise[flag_all == 1]
            vis_all[np.isnan(vis_all)] = 0.
            listDataSPW = [
                np.swapaxes(vis_all[SPW == i, :, :], 0, 1)
                for i in self.ListSPW
            ]
            self.data = np.concatenate(
                listDataSPW)  #np.swapaxes(np.concatenate(listDataSPW),0,1)
            listFlagSPW = [
                np.swapaxes(flag_all[SPW == i, :, :], 0, 1)
                for i in self.ListSPW
            ]
            flag_all = np.concatenate(
                listFlagSPW)  #np.swapaxes(np.concatenate(listDataSPW),0,1)
            self.uvw = uvw
            self.swapped = True

        else:
            self.uvw = uvw
            if self.multidata:
                self.data = []
                for colin in self.ColName:
                    print("... read %s" % colin)
                    vis_all = table_all.getcol(
                        colin, row0,
                        nRowRead)[SPW == self.ListSPW[0]][:, self.ChanSlice, :]
                    print(" shape: %s" % str(vis_all.shape))
                    if self.zero_flag: vis_all[flag_all == 1] = 0.
                    vis_all[np.isnan(vis_all)] = 0.
                    self.data.append(vis_all)
            else:
                vis_all = table_all.getcol(self.ColName, row0,
                                           nRowRead)[:, self.ChanSlice, :]
                #if self.zero_flag: vis_all[flag_all==1]=0.
                #vis_all[np.isnan(vis_all)]=0.
                self.data = vis_all

        # import pylab
        # pylab.plot(time_all[::111],vis[::111,512,0].real)
        # pylab.show()

        fnan = np.isnan(vis_all)

        vis_all[fnan] = 0.
        flag_all[fnan] = 1
        #flag_all[vis_all==0]=1

        self.flag_all = flag_all
        self.uvw_dt = None

        if self.ReadUVWDT:

            tu = table(self.MSName, ack=False)
            ColNames = tu.colnames()
            tu.close()
            del (tu)

            if 'UVWDT' not in ColNames:
                self.AddUVW_dt()

            log.print("Reading uvw_dt column")
            tu = table(self.MSName, ack=False)
            self.uvw_dt = np.float64(tu.getcol('UVWDT', row0, nRowRead))
            tu.close()

        if self.RejectAutoCorr:
            indGetCorrelation = np.where(A0 != A1)[0]
            A0 = A0[indGetCorrelation]
            A1 = A1[indGetCorrelation]
            self.uvw = self.uvw[indGetCorrelation, :]
            time_all = time_all[indGetCorrelation]
            if self.swapped:
                self.data = self.data[:, indGetCorrelation, :]
                self.flag_all = self.flag_all[:, indGetCorrelation, :]
            else:
                self.data = self.data[indGetCorrelation, :, :]
                self.flag_all = self.flag_all[indGetCorrelation, :, :]
            self.nbl = (self.na * (self.na - 1)) // 2

        if self.DoRevertChans:
            self.flag_all = self.flag_all[:, ::-1, :]
            if not (type(self.data) == list):
                self.data = self.data[:, ::-1, :]
            else:
                for icol in range(len(self.data)):
                    self.data[icol] = self.data[icol][:, ::-1, :]

        if self.ToRADEC is not None:
            DATA = {"uvw": uvw, "data": self.data}
            self.Rotate(DATA, RotateType=["uvw", "vis"])
            self.data = DATA["data"]

        self.NPolOrig = self.data.shape[-1]
        if self.data.shape[-1] != 4:
            log.print(
                ModColor.Str("Data has only two polarisation, adapting shape"))
            nrow, nch, _ = self.data.shape
            flag_all = np.zeros((nrow, nch, 4), self.flag_all.dtype)
            data = np.zeros((nrow, nch, 4), self.data.dtype)
            flag_all[:, :, 0] = self.flag_all[:, :, 0]
            flag_all[:, :, -1] = self.flag_all[:, :, -1]
            data[:, :, 0] = self.data[:, :, 0]
            data[:, :, -1] = self.data[:, :, -1]
            self.data = data
            self.flag_all = flag_all

        if "IMAGING_WEIGHT" in table_all.colnames():
            log.print("Flagging the zeros-weighted visibilities")
            fw = table_all.getcol(
                "IMAGING_WEIGHT", row0,
                nRowRead)[SPW == self.ListSPW[0]][:, self.ChanSlice]
            nrr, nchr = fw.shape
            fw = fw.reshape((nrr, nchr, 1)) * np.ones((1, 1, 4))
            MedW = np.median(fw)
            fflagged0 = np.count_nonzero(flag_all)
            flag_all[fw < MedW * 1e-6] = 1
            fflagged1 = np.count_nonzero(flag_all)
            if fflagged1 > 0 and fflagged0 != 0:
                log.print("  Increase in flag fraction: %f" %
                          (fflagged1 / float(fflagged0) - 1))

        table_all.close()

        self.times_all = time_all
        self.times = time_slots_all
        self.ntimes = time_slots_all.shape[0]
        self.nrows = time_all.shape[0]

        self.IndFlag = np.where(flag_all == True)

        #self.NPol=vis_all.shape[2]
        self.A0 = A0
        self.A1 = A1

        return True
예제 #17
0
파일: ClassMS.py 프로젝트: saopicc/killMS
    def GiveMappingAnt(self,
                       ListStrSel,
                       row0row1=(None, None),
                       FlagAutoCorr=True,
                       WriteAttribute=True):
        row0, row1 = row0row1
        if type(ListStrSel) != list:
            assert (False)

        #ListStrSel=["RT9-RTA", "RTA-RTB", "RTC-RTD", "RT6-RT7", "RT5"]

        log.print(
            ModColor.Str("  ... Building BL-mapping for %s" % str(ListStrSel)))

        if row1 == None:
            row0 = 0
            row1 = self.nbl
        A0 = self.F_A0[row0:row1]
        A1 = self.F_A1[row0:row1]
        MapOut = np.ones((self.nbl, ), dtype=np.bool)
        if FlagAutoCorr:
            ind = np.where(A0 == A1)[0]
            MapOut[ind] = False

        def GiveStrAntToNum(self, StrAnt):
            ind = []
            for i in range(len(self.StationNames)):
                if StrAnt in self.StationNames[i]:
                    ind.append(i)
            #print ind
            return ind

        #MapOut=np.ones(A0.shape,bool)###)

        LFlaggedStations = []
        LNumFlaggedStations = []

        for blsel in ListStrSel:
            if blsel == "": continue
            if "-" in blsel:
                StrA0, StrA1 = blsel.split("-")
                LNumStrA0 = GiveStrAntToNum(self, StrA0)
                LNumStrA1 = GiveStrAntToNum(self, StrA1)
                for NumStrA0 in LNumStrA0:
                    for NumStrA1 in LNumStrA1:
                        NumA0 = np.where(
                            np.array(self.StationNames) == NumStrA0)[0]
                        NumA1 = np.where(
                            np.array(self.StationNames) == NumStrA1)[0]
                        C0 = ((A0 == NumA0) & (A1 == NumA1))
                        C1 = ((A1 == NumA0) & (A0 == NumA1))
                        ind = np.where(C1 | C0)[0]
                        MapOut[ind] = False
            else:
                #NumA0=np.where(np.array(self.StationNames)==blsel)[0]
                StrA0 = blsel
                LNumStrA0 = GiveStrAntToNum(self, StrA0)

                LNumFlaggedStations.append(LNumStrA0)

                for NumStrA0 in LNumStrA0:
                    LFlaggedStations.append(self.StationNames[NumStrA0])
                    # NumA0=np.where(np.array(self.StationNames)==NumStrA0)[0]
                    # stop
                    # print NumStrA0,NumA0
                    C0 = (A0 == NumStrA0)
                    C1 = (A1 == NumStrA0)
                    ind = np.where(C1 | C0)[0]

                    MapOut[ind] = False

        if WriteAttribute:
            self.MapSelBLs = MapOut
            self.LFlaggedStations = list(set(LFlaggedStations))
            return self.MapSelBLs
        else:
            LNumFlaggedStations = sorted(
                list(
                    set(range(self.na)) -
                    set(np.array(LNumFlaggedStations).flatten().tolist())))
            return LNumFlaggedStations
예제 #18
0
    def PrepareGridMachinesMapping(self):
        log.print("  Make the solution-directions to gridmachine mapping")
        ListGrid = []

        NFacets = len(self.DicoImager.keys())

        ClusterCat = self.ClusterCat
        DicoJonesDirToFacet = {}
        for iDir in range(self.ClusterCat.shape[0]):
            DicoJonesDirToFacet[iDir] = {}
            DicoJonesDirToFacet[iDir]["FacetsIDs"] = []
            DicoJonesDirToFacet[iDir]["SumFlux"] = 0.

        model_dict = self.FacetMachine._model_dict
        model_dict.reload()
        for iFacet in sorted(self.FacetMachine.DicoImager.keys()):
            iDirJones = self.FacetMachine.DicoImager[iFacet]["iDirJones"]
            ThisFacetSumFlux = model_dict[iFacet]["SumFlux"]
            ClusterCat.SumI[iDirJones] += np.real(ThisFacetSumFlux)
            self.FacetMachine.DicoImager[iFacet]["SumFlux"] = np.real(
                ThisFacetSumFlux)
            if self.FacetMachine.DicoImager[iFacet]["SumFlux"] != 0.:
                DicoJonesDirToFacet[iDirJones]["FacetsIDs"].append(iFacet)
                DicoJonesDirToFacet[iDirJones]["SumFlux"] += np.real(
                    ThisFacetSumFlux)

        for iFacet in sorted(self.FacetMachine.DicoImager.keys()):
            Grid = model_dict[iFacet]["FacetGrid"]
            ListGrid.append(Grid)

        self.DicoImager = self.FacetMachine.DicoImager
        self.DicoJonesDirToFacet = DicoJonesDirToFacet

        D = {}
        iDirNew = 0

        self.ClusterCatOrig = self.ClusterCat.copy()
        self.NDirsOrig = self.ClusterCat.shape[0]

        self.NDirs = self.ClusterCat.shape[0]

        from killMS.Data import ClassBeam

        #self.GD["Beam"]["BeamModel"]=self.GD["Beam"]["Model"]
        Th = float(self.GD["GDkMS"]["ImageSkyModel"]["ThSolve"])

        Keep = np.zeros((self.NDirs, ), bool)

        if Th > 0:
            log.print("Compute mean beam for direction removal...")
            BeamMachine = ClassBeam.ClassBeam(
                self.VS.ListMS[0].MSName, self.GD["GDkMS"],
                self.SM)  #,ColName=self.GD["Data"]["ColName"])
            AbsMeanBeam = BeamMachine.GiveMeanBeam(NTimes=10)
            AbsMeanBeamAnt = np.mean(AbsMeanBeam[:, :, 0, 0, 0], axis=1)

            AppFlux = np.array([
                self.DicoJonesDirToFacet[iDirJones]["SumFlux"] *
                (AbsMeanBeamAnt[iDirJones])**2
                for iDirJones in sorted(DicoJonesDirToFacet.keys())
            ])
        else:
            AppFlux = np.array([
                self.DicoJonesDirToFacet[iDirJones]["SumFlux"]
                for iDirJones in sorted(DicoJonesDirToFacet.keys())
            ])

        MaxAppFlux = AppFlux.max()

        HasRemoved = 0

        for iDirJones in sorted(DicoJonesDirToFacet.keys()):
            #print(self.DicoJonesDirToFacet[iDirJones]["SumFlux"])
            #if self.DicoJonesDirToFacet[iDirJones]["SumFlux"]==0:

            if AppFlux[iDirJones] <= MaxAppFlux * Th:
                log.print(
                    ModColor.Str(
                        "  Remove Jones direction %i [%f < %f Jy [Th = %f of Max %f Jy]]"
                        % (iDirJones, AppFlux[iDirJones], MaxAppFlux * Th, Th,
                           MaxAppFlux)))
                HasRemoved = 1
                #print("  !!!!!!!!!!!!!!!!!!!!!!!")
            else:
                D[iDirNew] = self.DicoJonesDirToFacet[iDirJones]
                iDirNew += 1
                Keep[iDirJones] = 1

        if not HasRemoved:
            log.print(
                ModColor.Str("All directions have been kept in the solve"))

        #Keep.fill(0)
        #Keep[1:5]=1

        self.MapClusterCatOrigToCut = Keep

        self.DicoJonesDirToFacet = D
        self.ClusterCat = self.ClusterCat[Keep].copy()

        # self.SourceCat=self.SourceCat[Keep].copy()

        self.Dirs = self.DicoJonesDirToFacet.keys()
        self.NDirs = len(self.Dirs)

        # NpShared.PackListArray("%sGrids"%(self.IdSharedMem),ListGrid)

        return True
예제 #19
0
파일: DoSimul.py 프로젝트: saopicc/killMS
    def DoSimul(self):

        Noise = .01
        MS = self.MS
        SM = self.SM
        VS = self.VS
        ApplyBeam = self.ApplyBeam
        na = MS.na
        nd = SM.NDir
        NCPU = 6

        #PM=ClassPredict(NCPU=NCPU,DoSmearing="F")
        PM = ClassPredict(NCPU=NCPU)
        PM5 = ClassPredict5(NCPU=NCPU)
        na = MS.na
        nd = SM.NDir

        Load = VS.LoadNextVisChunk()

        Jones = self.GiveJones()

        log.print(ModColor.Str("Substract sources ... ", col="green"))
        #SM.SelectSubCat(SM.SourceCat.kill==0)

        t0 = np.mean(VS.MS.times_all)
        dt = VS.MS.dt

        def VariableFunc(t, nu):
            f = np.exp(-(t - t0) / (3 * dt))
            if f > 1:
                return 0.
            else:
                return f

        # PredictData=PM.predictKernelPolCluster(VS.ThisDataChunk,SM,ApplyTimeJones=Jones,Noise=Noise,
        #                                        VariableFunc=VariableFunc)

        PredictData = PM.predictKernelPolCluster(VS.ThisDataChunk,
                                                 SM,
                                                 ApplyTimeJones=Jones,
                                                 Noise=Noise,
                                                 VariableFunc=None)
        print(Jones["Beam"].ravel()[0])

        # PredictData=PM5.predictKernelPolCluster(VS.ThisDataChunk,SM,ApplyTimeJones=Jones)

        # import pylab
        # ind=np.where((VS.ThisDataChunk["A0"]==7)&(VS.ThisDataChunk["A1"]==17))[0]
        # op0=np.real
        # op1=np.abs
        # pylab.clf()
        # pylab.subplot(2,1,1)
        # pylab.plot(op0(PredictData[ind,0,0]))
        # pylab.plot(op0(PredictData5[ind,0,0]))
        # pylab.plot(op0(PredictData[ind,0,0])-op0(PredictData5[ind,0,0]))
        # pylab.subplot(2,1,2)
        # pylab.plot(op1(PredictData[ind,0,0]))
        # pylab.plot(op1(PredictData5[ind,0,0]))
        # pylab.plot(op1(PredictData[ind,0,0])-op1(PredictData5[ind,0,0]))
        # pylab.draw()
        # pylab.show(False)
        # stop
        # #PredictData=PM.predictKernelPolCluster(VS.ThisDataChunk,SM)

        #SM.RestoreCat()

        MS.data = PredictData

        #VS.MS.SaveVis(Col="DATA")
        #VS.MS.SaveVis(Col="CORRECTED_DATA")
        VS.MS.SaveVis(Col="CORRECTED_DATA")
        #VS.MS.SaveVis(Col="CORRECTED_DATA")

        t = table(self.MSName, readonly=False)
        # dp=t.getcol("DDF_PREDICT")
        # dp.fill(0)
        # dp[:,:,0]=1.
        # dp[:,:,-1]=1.
        # t.putcol("DDF_PREDICT",dp)
        # t.putcol("DATA",MS.data-dp)

        f = t.getcol("FLAG")
        f.fill(0)
        #r=np.random.rand(*(f.shape[0:2]))
        #ff=(r<0.3)
        # indr,indf=np.where(ff)
        # f[indr,indf,:]=True
        # # MS.flag_all=f
        # # MS.data[f]=1.e10
        t.putcol("FLAG", f)
        #t.putcol("FLAG_BACKUP",f)
        w = t.getcol("IMAGING_WEIGHT")

        w.fill(1)
        t.putcol("IMAGING_WEIGHT", w)

        # # ###############################
        # w.fill(0)
        # A0s = t.getcol("ANTENNA1")
        # A1s = t.getcol("ANTENNA2")
        # C2=self.Cr#np.dot(self.Cr.T.conj(),self.Cr)
        # V=C2[A0s,A1s]
        # ind=(V==0)
        # V[ind]=1e10
        # w0=1./(V+Noise**2)
        # w0[ind]=0
        # for ich in np.arange(w.shape[1]):
        #     w[:,ich]=np.abs(w0)
        # np.save("WSim.npy",w)

        t.close()

        Sols = self.Sols
        FileName = "%s/killMS.%s.sols.npz" % (self.VS.MS.MSName, "Simul")
        print("Saving %s" % FileName)
        print(self.FreqDomains)
        if not self.DoClusterJones:
            np.savez(FileName,
                     Sols=Sols,
                     StationNames=MS.StationNames,
                     SkyModel=SM.ClusterCat,
                     ClusterCat=SM.ClusterCat,
                     BeamTimes=np.array([], np.float64),
                     FreqDomains=self.FreqDomains)
        else:
            np.savez(FileName,
                     Sols=self.SolsCluster,
                     StationNames=MS.StationNames,
                     SkyModel=self.kMS_ClusterDirCat,
                     ClusterCat=self.kMS_ClusterDirCat,
                     BeamTimes=np.array([], np.float64),
                     FreqDomains=self.FreqDomains)
예제 #20
0
파일: DoSimul.py 프로젝트: saopicc/killMS
    def GiveJones(self):
        if self.Sols is None:
            Sols = self.GiveSols()
        else:
            Sols = self.Sols

        MS = self.MS
        SM = self.SM
        VS = self.VS
        ApplyBeam = self.ApplyBeam
        na = MS.na
        nd = SM.NDir

        if self.BeamAt == "facet":
            NDir = SM.SourceCat.shape[0]
            SM.SourceCat.Cluster = np.arange(NDir)
            SM.Dirs = SM.SourceCat.Cluster
            SM.NDir = NDir
            SM.ClusterCat = np.zeros((NDir, ), SM.ClusterCat.dtype)
            SM.ClusterCat = SM.ClusterCat.view(np.recarray)
            SM.ClusterCat.ra = SM.SourceCat.ra
            SM.ClusterCat.dec = SM.SourceCat.dec

        Jones = {}
        Jones["t0"] = Sols.t0
        Jones["t1"] = Sols.t1

        nt, nch, na, nd, _, _ = Sols.G.shape
        G = np.swapaxes(Sols.G, 1, 3).reshape((nt, nd, na, nch, 2, 2))

        # G[:,:,:,:,0,0]/=np.abs(G[:,:,:,:,0,0])
        # G[:,:,:,:,1,1]=G[:,:,:,:,0,0]
        # G.fill(0)
        # G[:,:,:,:,0,0]=1
        # G[:,:,:,:,1,1]=1

        nt, nd, na, nch, _, _ = G.shape

        # G=np.random.randn(*G.shape)+1j*np.random.randn(*G.shape)

        useArrayFactor = True
        useElementBeam = False
        if ApplyBeam:
            print(ModColor.Str("Apply Beam"))
            MS.LoadSR(useElementBeam=useElementBeam,
                      useArrayFactor=useArrayFactor)
            RA = SM.ClusterCat.ra
            DEC = SM.ClusterCat.dec

            NDir = RA.size
            Tm = Sols.tm
            T0s = Sols.t0
            T1s = Sols.t1
            DicoBeam = {}
            DicoBeam["Jones"] = np.zeros(
                (Tm.size, NDir, MS.na, MS.NSPWChan, 2, 2), dtype=np.complex64)
            DicoBeam["t0"] = np.zeros((Tm.size, ), np.float64)
            DicoBeam["t1"] = np.zeros((Tm.size, ), np.float64)
            DicoBeam["tm"] = np.zeros((Tm.size, ), np.float64)

            rac, decc = MS.OriginalRadec

            def GB(time, ra, dec):
                Beam = np.zeros(
                    (ra.shape[0], self.MS.na, self.MS.NSPWChan, 2, 2),
                    dtype=np.complex)
                # Beam[...,0,0]=1
                # Beam[...,1,1]=1
                # return Beam

                for i in range(ra.shape[0]):
                    self.MS.SR.setDirection(ra[i], dec[i])
                    Beam[i] = self.MS.SR.evaluate(time)
                return Beam

            for itime in range(Tm.size):
                print(itime)
                DicoBeam["t0"][itime] = T0s[itime]
                DicoBeam["t1"][itime] = T1s[itime]
                DicoBeam["tm"][itime] = Tm[itime]
                ThisTime = Tm[itime]
                Beam = GB(ThisTime, RA, DEC)

                ###### Normalise
                Beam0 = GB(ThisTime, np.array([rac]), np.array([decc]))
                Beam0inv = ModLinAlg.BatchInverse(Beam0)
                nd, _, _, _, _ = Beam.shape
                Ones = np.ones((nd, 1, 1, 1, 1), np.float32)
                Beam0inv = Beam0inv * Ones
                nd_, na_, nf_, _, _ = Beam.shape
                # Beam_=np.ones((nd_,na_,nf_),np.float32)*(1+np.arange(nd_).reshape((-1,1,1)))
                # Beam.fill(0)
                # Beam[:,:,:,0,0]=Beam_[:,:,:]
                # Beam[:,:,:,1,1]=Beam_[:,:,:]
                Beam = ModLinAlg.BatchDot(Beam0inv, Beam)
                ######

                DicoBeam["Jones"][itime] = Beam

            nt, nd, na, nch, _, _ = DicoBeam["Jones"].shape

            #m=np.mean(np.abs(DicoBeam["Jones"][:,1,:,:,:,:]))
            # m=np.mean(np.abs(DicoBeam["Jones"][:,1,:,:,:,:]))
            # DicoBeam["Jones"][:,1,0:6,:,:,:]*=2
            # DicoBeam["Jones"][:,1,:,:,:,:]/=np.mean(np.abs(DicoBeam["Jones"][:,1,:,:,:,:]))
            # DicoBeam["Jones"][:,1,:,:,:,:]*=m

            # #################"
            # # Single Channel
            # DicoBeam["Jones"]=np.mean(DicoBeam["Jones"],axis=3).reshape((nt,nd,na,1,2,2))

            # G=ModLinAlg.BatchDot(G,DicoBeam["Jones"])

            # #################"
            # Multiple Channel
            Ones = np.ones((1, 1, 1, nch, 1, 1), np.float32)
            G = G * Ones
            G = ModLinAlg.BatchDot(G, DicoBeam["Jones"])

            # #################"

            # G[:,:,:,:,0,0]=1
            # G[:,:,:,:,0,1]=0.5
            # G[:,:,:,:,1,0]=2.
            # G[:,:,:,:,1,1]=1

            print("Done")

        # #################
        # Multiple Channel
        self.ChanMap = range(nch)
        # #################

        Jones["Beam"] = G
        Jones["BeamH"] = ModLinAlg.BatchH(G)
        if self.ChanMap is None:
            self.ChanMap = np.zeros((VS.MS.NSPWChan, ), np.int32).tolist()

        Jones["ChanMap"] = self.ChanMap

        # ###### for PM5
        # Jones["Map_VisToJones_Freq"]=self.ChanMap
        # Jones["Jones"]=Jones["Beam"]
        # nt=VS.MS.times_all.size
        # ntJones=DicoBeam["tm"].size
        # d=VS.MS.times_all.reshape((nt,1))-DicoBeam["tm"].reshape((1,ntJones))
        # Jones["Map_VisToJones_Time"]=np.argmin(np.abs(d),axis=1)

        return Jones