コード例 #1
0
def PlotXPAbs(starData,
              clusterName='NGC-0752',
              ionList=kAllIonList,
              fileTag='',
              labelPlot=True,
              labelPoints=False,
              showTrendLine=False,
              modelAtms=None,
              pradks=None,
              referenceCorrect=False):
    # Make XP vs. Ab for the passed star
    # One element per plot.
    starName = starData[0]
    starParmTuple = tuple(starData[1:])

    isGiant = RC.isGiantStar(starParmTuple)
    if isGiant:
        modelPath = k.GiantModelPath
    else:
        modelPath = k.DwarfModelPath

    if modelAtms == None or pradks == None:
        modelFiles = mk.findDataFiles(modelPath)
        modelAtms, pradks = mk.LoadModels(modelFiles)

    abdict, uncorrLines, unusedMin, unusedMax = \
                AB.CalcAbsAndLines(clusterName+' '+starName,
                                   tuple(starData[1:6]), ionList=ionList,
                                   modelAtms=modelAtms, pradks=pradks)
    # uncorrLines:
    # # {elem.ion:[[Wavelength, Ex.Pot., logGf, eqw, logRW, abund],...]}

    if referenceCorrect:
        if isGiant:  # Obligatory comment on bad Giant corrections, and using
            # Solar instead.
            correctDict, referenceLines, lineWeights = \
            RC.GetSolarCorrections(ionList=ionList,
                                modelAtms=modelAtms,
                                pradks=pradks)
        else:
            correctDict, referenceLines, lineWeights = \
            RC.GetDwarfCorrections(ionList=ionList,
                                modelAtms=modelAtms,
                                pradks=pradks)

    correctionsAvailable = False
    if len(correctDict) > 0 and len(referenceLines) > 0:
        correctionsAvailable = True

    for ion in ionList:
        if ion not in uncorrLines.keys():
            continue
        # Does this element have NLTE corrections available? Note: we do
        # this BEFORE Solar corrections, which assumes that the same
        # NLTE corrections are already applied to any Solar corrections
        # we use.
        if ion in NLTEIons:
            LTELines = AB.CorrectNLTEAbs(ion, uncorrLines[ion],
                                         tuple(starData[1:6]))
        else:
            if ion in uncorrLines.keys():
                LTELines = uncorrLines[ion]
            else:
                # Either synthesized lines, or none available
                LTELines = np.array([])

        # Do we want the "reference corrected" abundances?
        if referenceCorrect and correctionsAvailable:
            tempAdj,tempAll = \
                    RC.SortAndFilterLines(LTELines,
                                       ion,
                                       tuple(starData[1:6]),
                                       solarCorrect=referenceCorrect,
                                       solarLines=referenceLines[ion],
                                       solarCorrs=correctDict[ion],
                                       lineWeights=lineWeights[ion])

            # correctedLines:
            #           [[ab, line STR score, wl, "quality"], ...]
            # allLines:
            #           [[ab, line STR score, wl],...]
            # We want to use np.arrays, so...
            allLines = np.array(tempAll)
            correctedLines = np.array(tempAdj)
            if len(allLines) == 0 or len(correctedLines) == 0:
                correctionsAvailable = False
            elif len(allLines) == 1 or len(correctedLines) == 1:
                print('Single Line determination:{0}'.format(starData[0]))
                print(allLines, correctedLines)
        # One plot per ion.
        if labelPlot:
            plotLabel = 'XP vs Ab for [{2}/H] in {0} {1}.'.\
                        format(clusterName, starName, el.getIonName(ion))
        else:
            plotLabel = ''

        if referenceCorrect and correctionsAvailable:
            tempPoints = []
            for line in uncorrLines[ion]:
                correctedAbs = [l[0] for l in correctedLines if \
                                u.in_range(l[2],line[0]-0.05, line[0]+0.05)]
                if len(correctedAbs) > 0:
                    tempPoints.append(
                        [line[1],
                         np.mean(correctedAbs), line[3], line[0]])
                else:
                    tempPoints.append([line[1], line[5], line[3], line[0]])
            XPAbPoints = np.array(tempPoints)
        else:
            XPAbPoints = np.array([[line[1],line[5],line[3],line[0]]\
                                for line in uncorrLines[ion]])
        if labelPoints:
            # Label the points with the wavelength
            pointLabels = ['{0:2.3f}'.format(point[3]) \
                           for point in XPAbPoints]
        else:
            pointLabels = None

        ps.XPAbPlot(XPAbPoints,
                    starName,
                    ion,
                    fileTag=fileTag + 'XPAb',
                    plotTitle=plotLabel,
                    pointLabels=pointLabels,
                    showTrendLine=showTrendLine)
コード例 #2
0
def GetAbsForStar(starData, clusterName='NGC-0752', ions=kAllIonList, \
                  filterBlends=False, refCorrect=False,\
                  refLines=None, refDict=None, lineWeights=None,
                  useDAOSpec=False, modelAtms=None, pradks=None):
    # Get all the elemental abundances for the single passed star (params):
    # starData: (starName, Teff, LogG, VTurb, Met, Mass)
    #
    # Returns a dictionary of {ion:(Ab, std, #lines, avg Quality)...}
    starName = starData[0]
    starParms = tuple(starData[1:6])

    abdict, uncorrLines, unusedMins, unusedMaxes = \
            AB.CalcAbsAndLines(clusterName+' '+starName,
                               starParms,
                               ionList=ions,
                               modelAtms=modelAtms,
                               pradks=pradks,
                               useDAOlines=useDAOSpec)
    # uncorrLines:
    # # {elem.ion:[[Wavelength, Ex.Pot., logGf, eqw, logRW, abund],...]}

    starAbDict = {}
    ionLUT = sorted(list(abdict.keys()))
    ionLUT = sorted(set(ionLUT + [ion for ion in SynthAbsDict.keys()\
                        if starName in SynthAbsDict[ion].keys()]))
    if refCorrect and (refLines is None or refDict is None):
        refCorrect = False

    for ion in ionLUT:
        # We'll make one line per ion. Note, synth elements won't
        # necessarily have lines in the table/dict.
        if ion not in list(uncorrLines.keys()) + list(SynthAbsDict.keys()):
            continue
        if refCorrect and ion not in refLines.keys():
            correctionsAvail = False
        else:
            correctionsAvail = True

        # Does this element have NLTE corrections available? Note: we do
        # this BEFORE Solar corrections, which assumes that the same
        # NLTE corrections are already applied to any Solar corrections
        # we use.
        if ion in NLTEIons:
            LTELines = AB.CorrectNLTEAbs(ion, uncorrLines[ion], starParms)
        else:
            if ion in uncorrLines.keys():
                LTELines = uncorrLines[ion]
            else:
                # Either synthesized lines, or none available
                LTELines = np.array([])

        # Now apply "Solar" or "Astrophysical Log gf" corrections, if requested
        if correctionsAvail and (refCorrect or
                                 filterBlends) and ion in uncorrLines.keys():
            tempAdj,tempAll = \
                    RC.SortAndFilterLines(LTELines,
                                       ion,
                                       starParms,
                                       filterBlends=filterBlends,
                                       solarCorrect=refCorrect,
                                       solarLines=refLines[ion],
                                       solarCorrs=refDict[ion],
                                       lineWeights=lineWeights[ion])

            # correctedLines:
            #           [[ab, line STR score, wl, "quality"], ...]
            # allLines:
            #           [[ab, line STR score, wl],...]
            # We want to use np.arrays, so...
            allLines = np.array(tempAll)
            correctedLines = np.array(tempAdj)

        else:
            if len(LTELines) > 0:
                allLines = np.array(\
                    [[l[5], el.STR(l[2], l[1], starParms[0]), l[0]] \
                                                for l in LTELines])
                correctedLines = np.array(\
                    [[l[0], l[1], l[2], k.AbWeights[-1]] \
                                                for l in allLines])
            else:
                allLines = correctedLines = np.array([])

        if ion in SynthAbsDict.keys() and \
             starName in SynthAbsDict[ion].keys():
            # We have a C I or N I synthesis:
            if ion == 6.0:
                nonSynthLines = np.array([l for l in correctedLines\
                               if l[2]<7110 or l[2]>7120])
            elif ion == 7.0:
                # N I synthesis uses both the 7115 region (giants)
                # and the 7442 region (all). Only the 7442 region
                # has a potentially measured line, tho.
                nonSynthLines = np.array([l for l in correctedLines \
                               if np.floor(l[2]) != 7442])
            else:
                nonSynthLines = []

            synthArray = GetSynthLines(starName, ion,\
                         clusterName=clusterName)
            # Returned tuple: (synthMean, synthStd, synthCount)

            # Include our synthesis as the number of lines measured
            if len(nonSynthLines) == 0:
                starAbDict[ion] = [synthArray[0], synthArray[1],\
                                   synthArray[2],k.NoAbWeight]
            else:
                mean = np.mean(nonSynthLines[:, 0])
                std = np.std(nonSynthLines[:, 0])
                ct = len(nonSynthLines)

                totalCt = ct + synthArray[2]
                totalMean = ((mean*ct)+(synthArray[0]*synthArray[2]))/\
                                (totalCt)
                totalStd = np.sqrt(\
                        (ct*(totalMean-mean)**2+
                         synthArray[2]*(synthArray[0]-mean)**2)/\
                        (totalCt-1))
                starAbDict[ion] = [totalMean, totalStd, totalCt, k.NoAbWeight]
            # We have already created the abundance dictionary for this ion,
            # so skip out on the next part.
            continue
        else:
            # No synthesized lines need to be added.
            pass

        if refCorrect and len(correctedLines) > 0:
            linesToCount = correctedLines
            avgQ = np.mean(correctedLines[:, 3])
        else:
            linesToCount = allLines
            avgQ = k.NoAbWeight

        if len(linesToCount) > 0:
            starAbDict[ion] = [
                np.mean(linesToCount[:, 0]),
                np.std(linesToCount[:, 0]),
                len(linesToCount), avgQ
            ]
        else:
            # No lines to count. Make sure we don't have an entry:
            if ion in starAbDict.keys():
                del starAbDict[ion]
    return starAbDict