Ejemplo n.º 1
0
def kepregr(infile, outfile, datacol, kmethod, kneighb, plot, plotlab, clobber,
            verbose, logfile, status):
    """
    Perform a k-nearest neighbor regression analysis.
    """

    ## startup parameters

    status = 0
    labelsize = 24
    ticksize = 16
    xsize = 16
    ysize = 6
    lcolor = '#47AE10'
    lwidth = 1.0
    fcolor = '#9AFF9A'
    falpha = 0.3

    ## log the call

    hashline = '----------------------------------------------------------------------------'
    kepmsg.log(logfile, hashline, verbose)
    call = 'KEPREGR -- '
    call += 'infile=' + infile + ' '
    call += 'outfile=' + outfile + ' '
    call += 'datacol=' + str(datacol) + ' '
    call += 'kmethod=' + str(kmethod) + ' '
    call += 'kneighb=' + str(kneighb) + ' '
    plotit = 'n'
    if (plot): plotit = 'y'
    call += 'plot=' + plotit + ' '
    call += 'plotlab=' + str(plotlab) + ' '
    overwrite = 'n'
    if (clobber): overwrite = 'y'
    call += 'clobber=' + overwrite + ' '
    chatter = 'n'
    if (verbose): chatter = 'y'
    call += 'verbose=' + chatter + ' '
    call += 'logfile=' + logfile
    kepmsg.log(logfile, call + '\n', verbose)

    ## start time

    kepmsg.clock('KEPREGR started at', logfile, verbose)

    ## test log file

    logfile = kepmsg.test(logfile)

    ## clobber output file

    if clobber: status = kepio.clobber(outfile, logfile, verbose)
    if kepio.fileexists(outfile):
        message = 'ERROR -- KEPREGR: ' + outfile + ' exists. Use clobber=yes'
        status = kepmsg.err(logfile, message, verbose)

## open input file

    if status == 0:
        instr, status = kepio.openfits(infile, 'readonly', logfile, verbose)
        tstart, tstop, bjdref, cadence, status = kepio.timekeys(
            instr, infile, logfile, verbose, status)
        if cadence == 0.0:
            tstart, tstop, ncad, cadence, status = kepio.cadence(
                instr, infile, logfile, verbose, status)
    if status == 0:
        try:
            work = instr[0].header['FILEVER']
            cadenom = 1.0
        except:
            cadenom = cadence

## fudge non-compliant FITS keywords with no values

    if status == 0:
        instr = kepkey.emptykeys(instr, file, logfile, verbose)

## read table structure

    if status == 0:
        table, status = kepio.readfitstab(infile, instr[1], logfile, verbose)

# read time and flux columns

    if status == 0:
        barytime, status = kepio.readtimecol(infile, table, logfile, verbose)
    if status == 0:
        flux, status = kepio.readfitscol(infile, instr[1].data, datacol,
                                         logfile, verbose)

# filter input data table

    if status == 0:
        try:
            nanclean = instr[1].header['NANCLEAN']
        except:
            naxis2 = 0
            for i in range(len(table.field(0))):
                if (numpy.isfinite(barytime[i]) and numpy.isfinite(flux[i])
                        and flux[i] != 0.0):
                    table[naxis2] = table[i]
                    naxis2 += 1
            instr[1].data = table[:naxis2]
            comment = 'NaN cadences removed from data'
            status = kepkey.new('NANCLEAN', True, comment, instr[1], outfile,
                                logfile, verbose)

## read table columns

    if status == 0:
        try:
            intime = instr[1].data.field('barytime')
        except:
            intime, status = kepio.readfitscol(infile, instr[1].data, 'time',
                                               logfile, verbose)
        indata, status = kepio.readfitscol(infile, instr[1].data, datacol,
                                           logfile, verbose)
    if status == 0:
        intime = intime + bjdref
        indata = indata / cadenom

    if status == 0:
        outdata = knn_predict(intime, indata, kmethod, kneighb)

## comment keyword in output file

    if status == 0:
        status = kepkey.history(call, instr[0], outfile, logfile, verbose)

## clean up x-axis unit

    if status == 0:
        intime0 = float(int(tstart / 100) * 100.0)
        if intime0 < 2.4e6: intime0 += 2.4e6
        ptime = intime - intime0
        # print ptime,intime,intime0
        xlab = 'BJD $-$ %d' % intime0

## clean up y-axis units

    if status == 0:
        pout = indata * 1.0
        pout2 = outdata * 1.0
        nrm = len(str(int(numpy.nanmax(pout)))) - 1
        pout = pout / 10**nrm
        pout2 = pout2 / 10**nrm
        ylab = '10$^%d$ %s' % (nrm, plotlab)

        ## data limits

        xmin = numpy.nanmin(ptime)
        xmax = numpy.nanmax(ptime)
        ymin = numpy.min(pout)
        ymax = numpy.nanmax(pout)
        xr = xmax - xmin
        yr = ymax - ymin
        ptime = insert(ptime, [0], [ptime[0]])
        ptime = append(ptime, [ptime[-1]])
        pout = insert(pout, [0], [0.0])
        pout = append(pout, 0.0)
        pout2 = insert(pout2, [0], [0.0])
        pout2 = append(pout2, 0.0)

## plot light curve

    if status == 0 and plot:
        try:
            params = {
                'backend': 'png',
                'axes.linewidth': 2.5,
                'axes.labelsize': labelsize,
                'axes.font': 'sans-serif',
                'axes.fontweight': 'bold',
                'text.fontsize': 12,
                'legend.fontsize': 12,
                'xtick.labelsize': ticksize,
                'ytick.labelsize': ticksize
            }
            rcParams.update(params)
        except:
            print('ERROR -- KEPREGR: install latex for scientific plotting')
            status = 1
    if status == 0 and plot:
        pylab.figure(1, figsize=[xsize, ysize])

        ## plot regression data

        ax = pylab.axes([0.06, 0.1, 0.93, 0.87])
        pylab.gca().xaxis.set_major_formatter(
            pylab.ScalarFormatter(useOffset=False))
        pylab.gca().yaxis.set_major_formatter(
            pylab.ScalarFormatter(useOffset=False))
        # pylab.plot(ptime,pout,color='#ff9900',linestyle='-',linewidth=lwidth)
        pylab.scatter(ptime, pout, color='#214CAE', s=5)
        fill(ptime, pout, color=fcolor, linewidth=0.0, alpha=falpha)
        pylab.plot(ptime[kneighb:-kneighb],
                   pout2[kneighb:-kneighb],
                   color=lcolor,
                   linestyle='-',
                   linewidth=lwidth * 2.0)
        xlabel(xlab, {'color': 'k'})
        ylabel(ylab, {'color': 'k'})
        xlim(xmin - xr * 0.01, xmax + xr * 0.01)
        if ymin >= 0.0:
            ylim(ymin - yr * 0.01, ymax + yr * 0.01)
        else:
            ylim(1.0e-10, ymax + yr * 0.01)
        pylab.grid()
        pylab.draw()
        pylab.savefig(re.sub('\.\S+', '.png', outfile), dpi=100)

## write output file

    if status == 0:
        for i in range(len(outdata)):
            instr[1].data.field(datacol)[i] = outdata[i]
        instr.writeto(outfile)

## close input file

    if status == 0:
        status = kepio.closefits(instr, logfile, verbose)

## end time

    if (status == 0):
        message = 'KEPREGR completed at'
    else:
        message = '\nKEPREGR aborted at'
    kepmsg.clock(message, logfile, verbose)
Ejemplo n.º 2
0
def kepdip(infile,outfile,datacol,dmethod,kneighb,hstd,plot,plotlab,
              clobber,verbose,logfile,status): 
    """
    Perform a k-nearest neighbor regression analysis.
    """

## startup parameters

    status = 0
    labelsize = 24
    ticksize = 16
    xsize = 16
    ysize = 6
    lcolor = '#0000ff'
    lwidth = 1.0
    fcolor = '#9AFF9A'
    falpha = 0.3

## log the call 

    hashline = '----------------------------------------------------------------------------'
    kepmsg.log(logfile,hashline,verbose)
    call = 'KEPDIP -- '
    call += 'infile='+infile+' '
    call += 'outfile='+outfile+' '
    call += 'datacol='+str(datacol)+' '
    call += 'dmethod='+dmethod+' '
    call += 'hstd='+str(hstd)+' '
    call += 'kneighb='+str(kneighb)+' '
    plotit = 'n'
    if (plot): plotit = 'y'
    call += 'plot='+plotit+ ' '
    call += 'plotlab='+str(plotlab)+' '
    overwrite = 'n'
    if (clobber): overwrite = 'y'
    call += 'clobber='+overwrite+ ' '
    chatter = 'n'
    if (verbose): chatter = 'y'
    call += 'verbose='+chatter+' '
    call += 'logfile='+logfile
    kepmsg.log(logfile,call+'\n',verbose)

## start time

    kepmsg.clock('KEPDIP started at',logfile,verbose)

## test log file

    logfile = kepmsg.test(logfile)

## clobber output file

    if clobber: status = kepio.clobber(outfile,logfile,verbose)
    if kepio.fileexists(outfile): 
	    message = 'ERROR -- KEPDIP: ' + outfile + ' exists. Use clobber=yes'
	    status = kepmsg.err(logfile,message,verbose)

## open input file

    if status == 0:
        instr, status = kepio.openfits(infile,'readonly',logfile,verbose)
        tstart, tstop, bjdref, cadence, status = kepio.timekeys(instr,infile,logfile,verbose,status)
        if cadence == 0.0: 
            tstart, tstop, ncad, cadence, status = kepio.cadence(instr,infile,logfile,verbose,status) 
    if status == 0:
        try:
            work = instr[0].header['FILEVER']
            cadenom = 1.0
        except:
            cadenom = cadence

## fudge non-compliant FITS keywords with no values

    if status == 0:
        instr = kepkey.emptykeys(instr,file,logfile,verbose)

## read table structure

    if status == 0:
	table, status = kepio.readfitstab(infile,instr[1],logfile,verbose)

# read time and flux columns

    if status == 0:
        barytime, status = kepio.readtimecol(infile,table,logfile,verbose)
    if status == 0:
        flux, status = kepio.readfitscol(infile,instr[1].data,datacol,logfile,verbose)

# filter input data table

    if status == 0:
        try:
            nanclean = instr[1].header['NANCLEAN']
        except:
            naxis2 = 0
            for i in range(len(table.field(0))):
                if (numpy.isfinite(barytime[i]) and numpy.isfinite(flux[i]) and flux[i] != 0.0):
                    table[naxis2] = table[i]
                    naxis2 += 1
            instr[1].data = table[:naxis2]
            comment = 'NaN cadences removed from data'
            status = kepkey.new('NANCLEAN',True,comment,instr[1],outfile,logfile,verbose)

## read table columns

    if status == 0:
	try:
            intime = instr[1].data.field('barytime')
	except:
            intime, status = kepio.readfitscol(infile,instr[1].data,'time',logfile,verbose)
	indata, status = kepio.readfitscol(infile,instr[1].data,datacol,logfile,verbose)
    if status == 0:
        intime = intime + bjdref
        indata = indata / cadenom

## smooth data

    if status == 0:
        # outdata = knn_predict(intime, indata, kmethod, kneighb)
	outdata_t, outdata_l, outdata_fmt = _find_dips(intime, indata, dmethod, kneighb, hstd)

## comment keyword in output file

    if status == 0:
        status = kepkey.history(call,instr[0],outfile,logfile,verbose)

## clean up x-axis unit

    if status == 0:
	intime0 = float(int(tstart / 100) * 100.0)
        if intime0 < 2.4e6: intime0 += 2.4e6
	ptime = intime - intime0
	ptime2 = outdata_t - intime0
        # print ptime,intime,intime0
	xlab = 'BJD $-$ %d' % intime0

## clean up y-axis units

    if status == 0:
        pout = indata * 1.0
        pout2 = outdata_l * 1.0 
	nrm = len(str(int(numpy.nanmax(pout))))-1
	pout = pout / 10**nrm
	pout2 = pout2 / 10**nrm
	ylab = '10$^%d$ %s' % (nrm, plotlab)

## data limits

	xmin = numpy.nanmin(ptime)
	xmax = numpy.nanmax(ptime)
	ymin = numpy.min(pout)
	ymax = numpy.nanmax(pout)
	xr = xmax - xmin
	yr = ymax - ymin
        ptime = insert(ptime,[0],[ptime[0]]) 
        ptime = append(ptime,[ptime[-1]])
        pout = insert(pout,[0],[0.0]) 
        pout = append(pout,0.0)
	if (len(ptime2) > 0):
	        ptime2 = insert(ptime2,[0],[ptime2[0]]) 
        	ptime2 = append(ptime2,[ptime2[-1]])
	        pout2 = insert(pout2,[0],[0.0]) 
        	pout2 = append(pout2,0.0)

## plot light curve

    if status == 0 and plot:
        try:
            params = {'backend': 'png',
                      'axes.linewidth': 2.5,
                      'axes.labelsize': labelsize,
                      'axes.font': 'sans-serif',
                      'axes.fontweight' : 'bold',
                      'text.fontsize': 12,
                      'legend.fontsize': 12,
                      'xtick.labelsize': ticksize,
                      'ytick.labelsize': ticksize}
            rcParams.update(params)
        except:
            print('ERROR -- KEPDIP: install latex for scientific plotting')
            status = 1
    if status == 0 and plot:
        pylab.figure(1,figsize=[xsize,ysize])

## plot regression data

        ax = pylab.axes([0.06,0.1,0.93,0.87])
        pylab.gca().xaxis.set_major_formatter(pylab.ScalarFormatter(useOffset=False))
        pylab.gca().yaxis.set_major_formatter(pylab.ScalarFormatter(useOffset=False))
	pylab.scatter(ptime, pout, color='#214CAE', s=2)

	if (len(ptime2) > 0):
	        pylab.scatter(ptime2, pout2, color='#47AE10', s=35, marker='o', linewidths=2, alpha=0.4)
        xlabel(xlab, {'color' : 'k'})
        ylabel(ylab, {'color' : 'k'})
        xlim(xmin-xr*0.01,xmax+xr*0.01)
        if ymin >= 0.0: 
            ylim(ymin-yr*0.01,ymax+yr*0.01)
        else:
            ylim(1.0e-10,ymax+yr*0.01)
        pylab.grid()
        pylab.draw()
        pylab.savefig(re.sub('\.\S+','.png',outfile),dpi=100)

## write output file

    if status == 0:
        for i in range(len(outdata_fmt)):
            instr[1].data.field(datacol)[i] = outdata_fmt[i]
        instr.writeto(outfile)
    
## close input file

    if status == 0:
        status = kepio.closefits(instr,logfile,verbose)	    

## end time

    if (status == 0):
	    message = 'KEPDIP completed at'
    else:
	    message = '\nKEPDIP aborted at'
    kepmsg.clock(message,logfile,verbose)
def kepsmooth(infile,outfile,datacol,function,fscale,plot,plotlab,
              clobber,verbose,logfile,status, cmdLine=False): 

## startup parameters

    status = 0
    labelsize = 24
    ticksize = 16
    xsize = 18
    ysize = 6
    lcolor = '#0000ff'
    lwidth = 1.0
    fcolor = '#ffff00'
    falpha = 0.2

## log the call 

    hashline = '----------------------------------------------------------------------------'
    kepmsg.log(logfile,hashline,verbose)
    call = 'KEPSMOOTH -- '
    call += 'infile='+infile+' '
    call += 'outfile='+outfile+' '
    call += 'datacol='+str(datacol)+' '
    call += 'function='+str(function)+' '
    call += 'fscale='+str(fscale)+' '
    plotit = 'n'
    if (plot): plotit = 'y'
    call += 'plot='+plotit+ ' '
    call += 'plotlab='+str(plotlab)+' '
    overwrite = 'n'
    if (clobber): overwrite = 'y'
    call += 'clobber='+overwrite+ ' '
    chatter = 'n'
    if (verbose): chatter = 'y'
    call += 'verbose='+chatter+' '
    call += 'logfile='+logfile
    kepmsg.log(logfile,call+'\n',verbose)

## start time

    kepmsg.clock('KEPSMOOTH started at',logfile,verbose)

## test log file

    logfile = kepmsg.test(logfile)

## clobber output file

    if clobber: status = kepio.clobber(outfile,logfile,verbose)
    if kepio.fileexists(outfile): 
	    message = 'ERROR -- KEPSMOOTH: ' + outfile + ' exists. Use clobber=yes'
	    status = kepmsg.err(logfile,message,verbose)

## open input file

    if status == 0:
        instr, status = kepio.openfits(infile,'readonly',logfile,verbose)
        tstart, tstop, bjdref, cadence, status = kepio.timekeys(instr,infile,logfile,verbose,status)
        if cadence == 0.0: 
            tstart, tstop, ncad, cadence, status = kepio.cadence(instr,infile,logfile,verbose,status) 
    if status == 0:
        try:
            work = instr[0].header['FILEVER']
            cadenom = 1.0
        except:
            cadenom = cadence

## fudge non-compliant FITS keywords with no values

    if status == 0:
        instr = kepkey.emptykeys(instr,file,logfile,verbose)

## read table structure

    if status == 0:
	table, status = kepio.readfitstab(infile,instr[1],logfile,verbose)

# read time and flux columns

    if status == 0:
        barytime, status = kepio.readtimecol(infile,table,logfile,verbose)
    if status == 0:
        flux, status = kepio.readfitscol(infile,instr[1].data,datacol,logfile,verbose)

# filter input data table

    if status == 0:
        try:
            nanclean = instr[1].header['NANCLEAN']
        except:
            naxis2 = 0
            for i in range(len(table.field(0))):
                if (numpy.isfinite(barytime[i]) and numpy.isfinite(flux[i]) and flux[i] != 0.0):
                    table[naxis2] = table[i]
                    naxis2 += 1
            instr[1].data = table[:naxis2]
            comment = 'NaN cadences removed from data'
            status = kepkey.new('NANCLEAN',True,comment,instr[1],outfile,logfile,verbose)

## read table columns

    if status == 0:
	try:
            intime = instr[1].data.field('barytime')
	except:
            intime, status = kepio.readfitscol(infile,instr[1].data,'time',logfile,verbose)
	indata, status = kepio.readfitscol(infile,instr[1].data,datacol,logfile,verbose)
    if status == 0:
        intime = intime + bjdref
        indata = indata / cadenom

## smooth data

    if status == 0:
        outdata = kepfunc.smooth(indata,fscale/(cadence/86400),function)

## comment keyword in output file

    if status == 0:
        status = kepkey.history(call,instr[0],outfile,logfile,verbose)

## clean up x-axis unit

    if status == 0:
	intime0 = float(int(tstart / 100) * 100.0)
        if intime0 < 2.4e6: intime0 += 2.4e6
	ptime = intime - intime0
	xlab = 'BJD $-$ %d' % intime0

## clean up y-axis units

    if status == 0:
        pout = indata * 1.0
        pout2 = outdata * 1.0 
	nrm = len(str(int(numpy.nanmax(pout))))-1
	pout = pout / 10**nrm
	pout2 = pout2 / 10**nrm
	ylab = '10$^%d$ %s' % (nrm, re.sub('_','-',plotlab))

## data limits

	xmin = numpy.nanmin(ptime)
	xmax = numpy.nanmax(ptime)
	ymin = numpy.min(pout)
	ymax = numpy.nanmax(pout)
	xr = xmax - xmin
	yr = ymax - ymin
        ptime = insert(ptime,[0],[ptime[0]]) 
        ptime = append(ptime,[ptime[-1]])
        pout = insert(pout,[0],[0.0]) 
        pout = append(pout,0.0)
        pout2 = insert(pout2,[0],[0.0]) 
        pout2 = append(pout2,0.0)

## plot light curve

    if status == 0 and plot:
        try:
            params = {'backend': 'png',
                      'axes.linewidth': 2.5,
                      'axes.labelsize': labelsize,
                      'axes.font': 'sans-serif',
                      'axes.fontweight' : 'bold',
                      'text.fontsize': 12,
                      'legend.fontsize': 12,
                      'xtick.labelsize': ticksize,
                      'ytick.labelsize': ticksize}
            rcParams.update(params)
        except:
            print 'ERROR -- KEPSMOOTH: install latex for scientific plotting'
            status = 1
    if status == 0 and plot:
        pylab.figure(1,figsize=[xsize,ysize])

# delete any fossil plots in the matplotlib window

        pylab.clf()

# position axes inside the plotting window

	ax = pylab.subplot(111)
	pylab.subplots_adjust(0.06,0.1,0.93,0.88)

# force tick labels to be absolute rather than relative

        pylab.gca().xaxis.set_major_formatter(pylab.ScalarFormatter(useOffset=False))
        pylab.gca().yaxis.set_major_formatter(pylab.ScalarFormatter(useOffset=False))

# rotate y labels by 90 deg

        labels = ax.get_yticklabels()
        setp(labels, 'rotation', 90)

        pylab.plot(ptime[1:-1],pout[1:-1],color='#ff9900',linestyle='-',linewidth=lwidth)
        fill(ptime,pout,color=fcolor,linewidth=0.0,alpha=falpha)
        pylab.plot(ptime,pout2,color=lcolor,linestyle='-',linewidth=lwidth*4.0)
	pylab.xlabel(xlab, {'color' : 'k'})
	pylab.ylabel(ylab, {'color' : 'k'})
	xlim(xmin-xr*0.01,xmax+xr*0.01)
        if ymin >= 0.0: 
            ylim(ymin-yr*0.01,ymax+yr*0.01)
        else:
            ylim(1.0e-10,ymax+yr*0.01)
        pylab.grid()

# render plot

    if cmdLine: 
        pylab.show()
    else: 
        pylab.ion()
        pylab.plot([])
        pylab.ioff()
	
## write output file

    if status == 0:
        for i in range(len(outdata)):
            instr[1].data.field(datacol)[i] = outdata[i]
        instr.writeto(outfile)
    
## close input file

    if status == 0:
        status = kepio.closefits(instr,logfile,verbose)	    

## end time

    if (status == 0):
	    message = 'KEPSMOOTH completed at'
    else:
	    message = '\nKEPSMOOTH aborted at'
    kepmsg.clock(message,logfile,verbose)
Ejemplo n.º 4
0
def kepsmooth(infile,outfile,datacol,function,fscale,plot,plotlab,
              clobber,verbose,logfile,status, cmdLine=False): 

## startup parameters

    status = 0
    labelsize = 24
    ticksize = 16
    xsize = 18
    ysize = 6
    lcolor = '#0000ff'
    lwidth = 1.0
    fcolor = '#ffff00'
    falpha = 0.2

## log the call 

    hashline = '----------------------------------------------------------------------------'
    kepmsg.log(logfile,hashline,verbose)
    call = 'KEPSMOOTH -- '
    call += 'infile='+infile+' '
    call += 'outfile='+outfile+' '
    call += 'datacol='+str(datacol)+' '
    call += 'function='+str(function)+' '
    call += 'fscale='+str(fscale)+' '
    plotit = 'n'
    if (plot): plotit = 'y'
    call += 'plot='+plotit+ ' '
    call += 'plotlab='+str(plotlab)+' '
    overwrite = 'n'
    if (clobber): overwrite = 'y'
    call += 'clobber='+overwrite+ ' '
    chatter = 'n'
    if (verbose): chatter = 'y'
    call += 'verbose='+chatter+' '
    call += 'logfile='+logfile
    kepmsg.log(logfile,call+'\n',verbose)

## start time

    kepmsg.clock('KEPSMOOTH started at',logfile,verbose)

## test log file

    logfile = kepmsg.test(logfile)

## clobber output file

    if clobber: status = kepio.clobber(outfile,logfile,verbose)
    if kepio.fileexists(outfile): 
	    message = 'ERROR -- KEPSMOOTH: ' + outfile + ' exists. Use clobber=yes'
	    status = kepmsg.err(logfile,message,verbose)

## open input file

    if status == 0:
        instr, status = kepio.openfits(infile,'readonly',logfile,verbose)
        tstart, tstop, bjdref, cadence, status = kepio.timekeys(instr,infile,logfile,verbose,status)
        if cadence == 0.0: 
            tstart, tstop, ncad, cadence, status = kepio.cadence(instr,infile,logfile,verbose,status) 
    if status == 0:
        try:
            work = instr[0].header['FILEVER']
            cadenom = 1.0
        except:
            cadenom = cadence

## fudge non-compliant FITS keywords with no values

    if status == 0:
        instr = kepkey.emptykeys(instr,file,logfile,verbose)

## read table structure

    if status == 0:
	table, status = kepio.readfitstab(infile,instr[1],logfile,verbose)

# read time and flux columns

    if status == 0:
        barytime, status = kepio.readtimecol(infile,table,logfile,verbose)
    if status == 0:
        flux, status = kepio.readfitscol(infile,instr[1].data,datacol,logfile,verbose)

# filter input data table

    if status == 0:
        try:
            nanclean = instr[1].header['NANCLEAN']
        except:
            naxis2 = 0
            for i in range(len(table.field(0))):
                if (numpy.isfinite(barytime[i]) and numpy.isfinite(flux[i]) and flux[i] != 0.0):
                    table[naxis2] = table[i]
                    naxis2 += 1
            instr[1].data = table[:naxis2]
            comment = 'NaN cadences removed from data'
            status = kepkey.new('NANCLEAN',True,comment,instr[1],outfile,logfile,verbose)

## read table columns

    if status == 0:
	try:
            intime = instr[1].data.field('barytime')
	except:
            intime, status = kepio.readfitscol(infile,instr[1].data,'time',logfile,verbose)
	indata, status = kepio.readfitscol(infile,instr[1].data,datacol,logfile,verbose)
    if status == 0:
        intime = intime + bjdref
        indata = indata / cadenom

## smooth data

    if status == 0:
        outdata = kepfunc.smooth(indata,fscale/(cadence/86400),function)

## comment keyword in output file

    if status == 0:
        status = kepkey.history(call,instr[0],outfile,logfile,verbose)

## clean up x-axis unit

    if status == 0:
	intime0 = float(int(tstart / 100) * 100.0)
        if intime0 < 2.4e6: intime0 += 2.4e6
	ptime = intime - intime0
	xlab = 'BJD $-$ %d' % intime0

## clean up y-axis units

    if status == 0:
        pout = indata * 1.0
        pout2 = outdata * 1.0 
	nrm = len(str(int(numpy.nanmax(pout))))-1
	pout = pout / 10**nrm
	pout2 = pout2 / 10**nrm
	ylab = '10$^%d$ %s' % (nrm, re.sub('_','-',plotlab))

## data limits

	xmin = numpy.nanmin(ptime)
	xmax = numpy.nanmax(ptime)
	ymin = numpy.min(pout)
	ymax = numpy.nanmax(pout)
	xr = xmax - xmin
	yr = ymax - ymin
        ptime = insert(ptime,[0],[ptime[0]]) 
        ptime = append(ptime,[ptime[-1]])
        pout = insert(pout,[0],[0.0]) 
        pout = append(pout,0.0)
        pout2 = insert(pout2,[0],[0.0]) 
        pout2 = append(pout2,0.0)

## plot light curve

    if status == 0 and plot:
        try:
            params = {'backend': 'png',
                      'axes.linewidth': 2.5,
                      'axes.labelsize': labelsize,
                      'axes.font': 'sans-serif',
                      'axes.fontweight' : 'bold',
                      'text.fontsize': 12,
                      'legend.fontsize': 12,
                      'xtick.labelsize': ticksize,
                      'ytick.labelsize': ticksize}
            rcParams.update(params)
        except:
            print('ERROR -- KEPSMOOTH: install latex for scientific plotting')
            status = 1
    if status == 0 and plot:
        pylab.figure(1,figsize=[xsize,ysize])

# delete any fossil plots in the matplotlib window

        pylab.clf()

# position axes inside the plotting window

	ax = pylab.subplot(111)
	pylab.subplots_adjust(0.06,0.1,0.93,0.88)

# force tick labels to be absolute rather than relative

        pylab.gca().xaxis.set_major_formatter(pylab.ScalarFormatter(useOffset=False))
        pylab.gca().yaxis.set_major_formatter(pylab.ScalarFormatter(useOffset=False))

# rotate y labels by 90 deg

        labels = ax.get_yticklabels()
        setp(labels, 'rotation', 90)

        pylab.plot(ptime[1:-1],pout[1:-1],color='#ff9900',linestyle='-',linewidth=lwidth)
        fill(ptime,pout,color=fcolor,linewidth=0.0,alpha=falpha)
        pylab.plot(ptime,pout2,color=lcolor,linestyle='-',linewidth=lwidth*4.0)
	pylab.xlabel(xlab, {'color' : 'k'})
	pylab.ylabel(ylab, {'color' : 'k'})
	xlim(xmin-xr*0.01,xmax+xr*0.01)
        if ymin >= 0.0: 
            ylim(ymin-yr*0.01,ymax+yr*0.01)
        else:
            ylim(1.0e-10,ymax+yr*0.01)
        pylab.grid()

# render plot

    if cmdLine: 
        pylab.show()
    else: 
        pylab.ion()
        pylab.plot([])
        pylab.ioff()
	
## write output file

    if status == 0:
        for i in range(len(outdata)):
            instr[1].data.field(datacol)[i] = outdata[i]
        instr.writeto(outfile)
    
## close input file

    if status == 0:
        status = kepio.closefits(instr,logfile,verbose)	    

## end time

    if (status == 0):
	    message = 'KEPSMOOTH completed at'
    else:
	    message = '\nKEPSMOOTH aborted at'
    kepmsg.clock(message,logfile,verbose)
Ejemplo n.º 5
0
def kepsmooth(
    infile, outfile, datacol, function, fscale, plot, plotlab, clobber, verbose, logfile, status, cmdLine=False
):

    ## startup parameters

    status = 0
    labelsize = 24
    ticksize = 16
    xsize = 18
    ysize = 6
    lcolor = "#0000ff"
    lwidth = 1.0
    fcolor = "#ffff00"
    falpha = 0.2

    ## log the call

    hashline = "----------------------------------------------------------------------------"
    kepmsg.log(logfile, hashline, verbose)
    call = "KEPSMOOTH -- "
    call += "infile=" + infile + " "
    call += "outfile=" + outfile + " "
    call += "datacol=" + str(datacol) + " "
    call += "function=" + str(function) + " "
    call += "fscale=" + str(fscale) + " "
    plotit = "n"
    if plot:
        plotit = "y"
    call += "plot=" + plotit + " "
    call += "plotlab=" + str(plotlab) + " "
    overwrite = "n"
    if clobber:
        overwrite = "y"
    call += "clobber=" + overwrite + " "
    chatter = "n"
    if verbose:
        chatter = "y"
    call += "verbose=" + chatter + " "
    call += "logfile=" + logfile
    kepmsg.log(logfile, call + "\n", verbose)

    ## start time

    kepmsg.clock("KEPSMOOTH started at", logfile, verbose)

    ## test log file

    logfile = kepmsg.test(logfile)

    ## clobber output file

    if clobber:
        status = kepio.clobber(outfile, logfile, verbose)
    if kepio.fileexists(outfile):
        message = "ERROR -- KEPSMOOTH: " + outfile + " exists. Use clobber=yes"
        status = kepmsg.err(logfile, message, verbose)

    ## open input file

    if status == 0:
        instr, status = kepio.openfits(infile, "readonly", logfile, verbose)
        tstart, tstop, bjdref, cadence, status = kepio.timekeys(instr, infile, logfile, verbose, status)
        if cadence == 0.0:
            tstart, tstop, ncad, cadence, status = kepio.cadence(instr, infile, logfile, verbose, status)
    if status == 0:
        try:
            work = instr[0].header["FILEVER"]
            cadenom = 1.0
        except:
            cadenom = cadence

    ## fudge non-compliant FITS keywords with no values

    if status == 0:
        instr = kepkey.emptykeys(instr, file, logfile, verbose)

    ## read table structure

    if status == 0:
        table, status = kepio.readfitstab(infile, instr[1], logfile, verbose)

    # read time and flux columns

    if status == 0:
        barytime, status = kepio.readtimecol(infile, table, logfile, verbose)
    if status == 0:
        flux, status = kepio.readfitscol(infile, instr[1].data, datacol, logfile, verbose)

    # filter input data table

    if status == 0:
        try:
            nanclean = instr[1].header["NANCLEAN"]
        except:
            naxis2 = 0
            for i in range(len(table.field(0))):
                if numpy.isfinite(barytime[i]) and numpy.isfinite(flux[i]) and flux[i] != 0.0:
                    table[naxis2] = table[i]
                    naxis2 += 1
            instr[1].data = table[:naxis2]
            comment = "NaN cadences removed from data"
            status = kepkey.new("NANCLEAN", True, comment, instr[1], outfile, logfile, verbose)

    ## read table columns

    if status == 0:
        try:
            intime = instr[1].data.field("barytime")
        except:
            intime, status = kepio.readfitscol(infile, instr[1].data, "time", logfile, verbose)
        indata, status = kepio.readfitscol(infile, instr[1].data, datacol, logfile, verbose)
    if status == 0:
        intime = intime + bjdref
        indata = indata / cadenom

    ## smooth data

    if status == 0:
        outdata = kepfunc.smooth(indata, fscale / (cadence / 86400), function)

    ## comment keyword in output file

    if status == 0:
        status = kepkey.history(call, instr[0], outfile, logfile, verbose)

    ## clean up x-axis unit

    if status == 0:
        intime0 = float(int(tstart / 100) * 100.0)
        if intime0 < 2.4e6:
            intime0 += 2.4e6
        ptime = intime - intime0
        xlab = "BJD $-$ %d" % intime0

    ## clean up y-axis units

    if status == 0:
        pout = indata * 1.0
        pout2 = outdata * 1.0
        nrm = len(str(int(numpy.nanmax(pout)))) - 1
        pout = pout / 10 ** nrm
        pout2 = pout2 / 10 ** nrm
        ylab = "10$^%d$ %s" % (nrm, re.sub("_", "-", plotlab))

        ## data limits

        xmin = numpy.nanmin(ptime)
        xmax = numpy.nanmax(ptime)
        ymin = numpy.min(pout)
        ymax = numpy.nanmax(pout)
        xr = xmax - xmin
        yr = ymax - ymin
        ptime = insert(ptime, [0], [ptime[0]])
        ptime = append(ptime, [ptime[-1]])
        pout = insert(pout, [0], [0.0])
        pout = append(pout, 0.0)
        pout2 = insert(pout2, [0], [0.0])
        pout2 = append(pout2, 0.0)

    ## plot light curve

    if status == 0 and plot:
        try:
            params = {
                "backend": "png",
                "axes.linewidth": 2.5,
                "axes.labelsize": labelsize,
                "axes.font": "sans-serif",
                "axes.fontweight": "bold",
                "text.fontsize": 12,
                "legend.fontsize": 12,
                "xtick.labelsize": ticksize,
                "ytick.labelsize": ticksize,
            }
            rcParams.update(params)
        except:
            print "ERROR -- KEPSMOOTH: install latex for scientific plotting"
            status = 1
    if status == 0 and plot:
        pylab.figure(1, figsize=[xsize, ysize])

        # delete any fossil plots in the matplotlib window

        pylab.clf()

        # position axes inside the plotting window

        ax = pylab.subplot(111)
        pylab.subplots_adjust(0.06, 0.1, 0.93, 0.88)

        # force tick labels to be absolute rather than relative

        pylab.gca().xaxis.set_major_formatter(pylab.ScalarFormatter(useOffset=False))
        pylab.gca().yaxis.set_major_formatter(pylab.ScalarFormatter(useOffset=False))

        # rotate y labels by 90 deg

        labels = ax.get_yticklabels()
        setp(labels, "rotation", 90)

        pylab.plot(ptime[1:-1], pout[1:-1], color="#ff9900", linestyle="-", linewidth=lwidth)
        fill(ptime, pout, color=fcolor, linewidth=0.0, alpha=falpha)
        pylab.plot(ptime, pout2, color=lcolor, linestyle="-", linewidth=lwidth * 4.0)
        pylab.xlabel(xlab, {"color": "k"})
        pylab.ylabel(ylab, {"color": "k"})
        xlim(xmin - xr * 0.01, xmax + xr * 0.01)
        if ymin >= 0.0:
            ylim(ymin - yr * 0.01, ymax + yr * 0.01)
        else:
            ylim(1.0e-10, ymax + yr * 0.01)
        pylab.grid()

    # render plot

    if cmdLine:
        pylab.show()
    else:
        pylab.ion()
        pylab.plot([])
        pylab.ioff()

    ## write output file

    if status == 0:
        for i in range(len(outdata)):
            instr[1].data.field(datacol)[i] = outdata[i]
        instr.writeto(outfile)

    ## close input file

    if status == 0:
        status = kepio.closefits(instr, logfile, verbose)

    ## end time

    if status == 0:
        message = "KEPSMOOTH completed at"
    else:
        message = "\nKEPSMOOTH aborted at"
    kepmsg.clock(message, logfile, verbose)