from asap.scantable import scantable from asap.parameters import rcParams from asap.logging import asaplog, asaplog_post_dec from asap.selector import selector #from asap import asaplotgui from asap.asapplotter import new_asaplot @asaplog_post_dec def average_time(*args, **kwargs): """ Return the (time) average of a scan or list of scans. [in channels only] The cursor of the output scan is set to 0 Parameters: one scan or comma separated scans or a list of scans mask: an optional mask (only used for 'var' and 'tsys' weighting) scanav: True averages each scan separately. False (default) averages all scans together, weight: Weighting scheme. 'none' (mean no weight) 'var' (1/var(spec) weighted) 'tsys' (1/Tsys**2 weighted) 'tint' (integration time weighted) 'tintsys' (Tint/Tsys**2) 'median' ( median averaging) align: align the spectra in velocity before averaging. It takes the time of the first spectrum in the first scantable as reference time. Example: # return a time averaged scan from scana and scanb # without using a mask scanav = average_time(scana,scanb) # or equivalent # scanav = average_time([scana, scanb]) # return the (time) averaged scan, i.e. the average of # all correlator cycles scanav = average_time(scan, scanav=True) """ scanav = False if kwargs.has_key('scanav'): scanav = kwargs.get('scanav') weight = 'tint' if kwargs.has_key('weight'): weight = kwargs.get('weight') mask = () if kwargs.has_key('mask'): mask = kwargs.get('mask') align = False if kwargs.has_key('align'): align = kwargs.get('align') compel = False if kwargs.has_key('compel'): compel = kwargs.get('compel') varlist = vars() if isinstance(args[0],list): lst = args[0] elif isinstance(args[0],tuple): lst = list(args[0]) else: lst = list(args) del varlist["kwargs"] varlist["args"] = "%d scantables" % len(lst) # need special formatting here for history... from asap._asap import stmath stm = stmath() for s in lst: if not isinstance(s,scantable): msg = "Please give a list of scantables" raise TypeError(msg) if scanav: scanav = "SCAN" else: scanav = "NONE" alignedlst = [] if align: refepoch = lst[0].get_time(0) for scan in lst: alignedlst.append(scan.freq_align(refepoch,insitu=False)) else: alignedlst = lst if weight.upper() == 'MEDIAN': # median doesn't support list of scantables - merge first merged = None if len(alignedlst) > 1: merged = merge(alignedlst) else: merged = alignedlst[0] s = scantable(stm._averagechannel(merged, 'MEDIAN', scanav)) del merged else: #s = scantable(stm._average(alignedlst, mask, weight.upper(), scanav)) s = scantable(stm._new_average(alignedlst, compel, mask, weight.upper(), scanav)) s._add_history("average_time",varlist) return s @asaplog_post_dec def quotient(source, reference, preserve=True): """ Return the quotient of a 'source' (signal) scan and a 'reference' scan. The reference can have just one scan, even if the signal has many. Otherwise they must have the same number of scans. The cursor of the output scan is set to 0 Parameters: source: the 'on' scan reference: the 'off' scan preserve: you can preserve (default) the continuum or remove it. The equations used are preserve: Output = Toff * (on/off) - Toff remove: Output = Toff * (on/off) - Ton """ varlist = vars() from asap._asap import stmath stm = stmath() stm._setinsitu(False) s = scantable(stm._quotient(source, reference, preserve)) s._add_history("quotient",varlist) return s @asaplog_post_dec def dototalpower(calon, caloff, tcalval=0.0): """ Do calibration for CAL on,off signals. Adopted from GBTIDL dototalpower Parameters: calon: the 'cal on' subintegration caloff: the 'cal off' subintegration tcalval: user supplied Tcal value """ varlist = vars() from asap._asap import stmath stm = stmath() stm._setinsitu(False) s = scantable(stm._dototalpower(calon, caloff, tcalval)) s._add_history("dototalpower",varlist) return s @asaplog_post_dec def dosigref(sig, ref, smooth, tsysval=0.0, tauval=0.0): """ Calculate a quotient (sig-ref/ref * Tsys) Adopted from GBTIDL dosigref Parameters: sig: on source data ref: reference data smooth: width of box car smoothing for reference tsysval: user specified Tsys (scalar only) tauval: user specified Tau (required if tsysval is set) """ varlist = vars() from asap._asap import stmath stm = stmath() stm._setinsitu(False) s = scantable(stm._dosigref(sig, ref, smooth, tsysval, tauval)) s._add_history("dosigref",varlist) return s @asaplog_post_dec def calps(scantab, scannos, smooth=1, tsysval=0.0, tauval=0.0, tcalval=0.0, verify=False): """ Calibrate GBT position switched data Adopted from GBTIDL getps Currently calps identify the scans as position switched data if source type enum is pson or psoff. The data must contains 'CAL' signal on/off in each integration. To identify 'CAL' on state, the source type enum of poncal and poffcal need to be present in the source name field. (GBT MS data reading process to scantable automatically append these id names to the source names) Parameters: scantab: scantable scannos: list of scan numbers smooth: optional box smoothing order for the reference (default is 1 = no smoothing) tsysval: optional user specified Tsys (default is 0.0, use Tsys in the data) tauval: optional user specified Tau tcalval: optional user specified Tcal (default is 0.0, use Tcal value in the data) verify: Verify calibration if true """ varlist = vars() # check for the appropriate data ## s = scantab.get_scan('*_ps*') ## if s is None: ## msg = "The input data appear to contain no position-switch mode data." ## raise TypeError(msg) s = scantab.copy() from asap._asap import srctype sel = selector() sel.set_types( srctype.pson ) try: scantab.set_selection( sel ) except Exception, e: msg = "The input data appear to contain no position-switch mode data." raise TypeError(msg) s.set_selection() sel.reset() ssub = s.get_scan(scannos) if ssub is None: msg = "No data was found with given scan numbers!" raise TypeError(msg) #ssubon = ssub.get_scan('*calon') #ssuboff = ssub.get_scan('*[^calon]') sel.set_types( [srctype.poncal,srctype.poffcal] ) ssub.set_selection( sel ) ssubon = ssub.copy() ssub.set_selection() sel.reset() sel.set_types( [srctype.pson,srctype.psoff] ) ssub.set_selection( sel ) ssuboff = ssub.copy() ssub.set_selection() sel.reset() if ssubon.nrow() != ssuboff.nrow(): msg = "mismatch in numbers of CAL on/off scans. Cannot calibrate. Check the scan numbers." raise TypeError(msg) cals = dototalpower(ssubon, ssuboff, tcalval) #sig = cals.get_scan('*ps') #ref = cals.get_scan('*psr') sel.set_types( srctype.pson ) cals.set_selection( sel ) sig = cals.copy() cals.set_selection() sel.reset() sel.set_types( srctype.psoff ) cals.set_selection( sel ) ref = cals.copy() cals.set_selection() sel.reset() if sig.nscan() != ref.nscan(): msg = "mismatch in numbers of on/off scans. Cannot calibrate. Check the scan numbers." raise TypeError(msg) #for user supplied Tsys if tsysval>0.0: if tauval<=0.0: msg = "Need to supply a valid tau to use the supplied Tsys" raise TypeError(msg) else: sig.recalc_azel() ref.recalc_azel() #msg = "Use of user specified Tsys is not fully implemented yet." #raise TypeError(msg) # use get_elevation to get elevation and # calculate a scaling factor using the formula # -> tsys use to dosigref #ress = dosigref(sig, ref, smooth, tsysval) ress = dosigref(sig, ref, smooth, tsysval, tauval) ### if verify: # get data import numpy precal={} postcal=[] keys=['ps','ps_calon','psr','psr_calon'] types=[srctype.pson,srctype.poncal,srctype.psoff,srctype.poffcal] ifnos=list(ssub.getifnos()) polnos=list(ssub.getpolnos()) sel=selector() for i in range(2): #ss=ssuboff.get_scan('*'+keys[2*i]) ll=[] for j in range(len(ifnos)): for k in range(len(polnos)): sel.set_ifs(ifnos[j]) sel.set_polarizations(polnos[k]) sel.set_types(types[2*i]) try: #ss.set_selection(sel) ssuboff.set_selection(sel) except: continue #ll.append(numpy.array(ss._getspectrum(0))) ll.append(numpy.array(ssuboff._getspectrum(0))) sel.reset() ssuboff.set_selection() precal[keys[2*i]]=ll #del ss #ss=ssubon.get_scan('*'+keys[2*i+1]) ll=[] for j in range(len(ifnos)): for k in range(len(polnos)): sel.set_ifs(ifnos[j]) sel.set_polarizations(polnos[k]) sel.set_types(types[2*i+1]) try: #ss.set_selection(sel) ssubon.set_selection(sel) except: continue #ll.append(numpy.array(ss._getspectrum(0))) ll.append(numpy.array(ssubon._getspectrum(0))) sel.reset() ssubon.set_selection() precal[keys[2*i+1]]=ll #del ss for j in range(len(ifnos)): for k in range(len(polnos)): sel.set_ifs(ifnos[j]) sel.set_polarizations(polnos[k]) try: ress.set_selection(sel) except: continue postcal.append(numpy.array(ress._getspectrum(0))) sel.reset() ress.set_selection() del sel # plot asaplog.post() asaplog.push('Plot only first spectrum for each [if,pol] pairs to verify calibration.') asaplog.post('WARN') #p=asaplotgui.asaplotgui() p=new_asaplot() #nr=min(6,len(ifnos)*len(polnos)) nr=len(ifnos)*len(polnos) titles=[] btics=[] if nr<4: p.set_panels(rows=nr,cols=2,nplots=2*nr,ganged=False) for i in range(2*nr): b=False if i >= 2*nr-2: b=True btics.append(b) elif nr==4: p.set_panels(rows=2,cols=4,nplots=8,ganged=False) for i in range(2*nr): b=False if i >= 2*nr-4: b=True btics.append(b) elif nr<7: p.set_panels(rows=3,cols=4,nplots=2*nr,ganged=False) for i in range(2*nr): if i >= 2*nr-4: b=True btics.append(b) else: asaplog.post() asaplog.push('Only first 6 [if,pol] pairs are plotted.') asaplog.post('WARN') nr=6 for i in range(2*nr): b=False if i >= 2*nr-4: b=True btics.append(b) p.set_panels(rows=3,cols=4,nplots=2*nr,ganged=False) for i in range(nr): p.subplot(2*i) p.color=0 title='raw data IF%s POL%s' % (ifnos[int(i/len(polnos))],polnos[i%len(polnos)]) titles.append(title) #p.set_axes('title',title,fontsize=40) ymin=1.0e100 ymax=-1.0e100 nchan=s.nchan(ifnos[int(i/len(polnos))]) edge=int(nchan*0.01) for j in range(4): spmin=min(precal[keys[j]][i][edge:nchan-edge]) spmax=max(precal[keys[j]][i][edge:nchan-edge]) ymin=min(ymin,spmin) ymax=max(ymax,spmax) for j in range(4): if i==0: p.set_line(label=keys[j]) else: p.legend() p.plot(precal[keys[j]][i]) p.axes.set_ylim(ymin-0.1*abs(ymin),ymax+0.1*abs(ymax)) if not btics[2*i]: p.axes.set_xticks([]) p.subplot(2*i+1) p.color=0 title='cal data IF%s POL%s' % (ifnos[int(i/len(polnos))],polnos[i%len(polnos)]) titles.append(title) #p.set_axes('title',title) p.legend() ymin=postcal[i][edge:nchan-edge].min() ymax=postcal[i][edge:nchan-edge].max() p.plot(postcal[i]) p.axes.set_ylim(ymin-0.1*abs(ymin),ymax+0.1*abs(ymax)) if not btics[2*i+1]: p.axes.set_xticks([]) for i in range(2*nr): p.subplot(i) p.set_axes('title',titles[i],fontsize='medium') x=raw_input('Accept calibration ([y]/n): ' ) if x.upper() == 'N': p.quit() del p return scabtab p.quit() del p ### ress._add_history("calps", varlist) return ress @asaplog_post_dec def calnod(scantab, scannos=[], smooth=1, tsysval=0.0, tauval=0.0, tcalval=0.0, verify=False): """ Do full (but a pair of scans at time) processing of GBT Nod data calibration. Adopted from GBTIDL's getnod Parameters: scantab: scantable scannos: a pair of scan numbers, or the first scan number of the pair smooth: box car smoothing order tsysval: optional user specified Tsys value tauval: optional user specified tau value (not implemented yet) tcalval: optional user specified Tcal value verify: Verify calibration if true """ varlist = vars() from asap._asap import stmath from asap._asap import srctype stm = stmath() stm._setinsitu(False) # check for the appropriate data ## s = scantab.get_scan('*_nod*') ## if s is None: ## msg = "The input data appear to contain no Nod observing mode data." ## raise TypeError(msg) s = scantab.copy() sel = selector() sel.set_types( srctype.nod ) try: s.set_selection( sel ) except Exception, e: msg = "The input data appear to contain no Nod observing mode data." raise TypeError(msg) sel.reset() del sel del s # need check correspondance of each beam with sig-ref ... # check for timestamps, scan numbers, subscan id (not available in # ASAP data format...). Assume 1st scan of the pair (beam 0 - sig # and beam 1 - ref...) # First scan number of paired scans or list of pairs of # scan numbers (has to have even number of pairs.) #data splitting scan1no = scan2no = 0 if len(scannos)==1: scan1no = scannos[0] scan2no = scannos[0]+1 pairScans = [scan1no, scan2no] else: #if len(scannos)>2: # msg = "calnod can only process a pair of nod scans at time." # raise TypeError(msg) # #if len(scannos)==2: # scan1no = scannos[0] # scan2no = scannos[1] pairScans = list(scannos) if tsysval>0.0: if tauval<=0.0: msg = "Need to supply a valid tau to use the supplied Tsys" raise TypeError(msg) else: scantab.recalc_azel() resspec = scantable(stm._donod(scantab, pairScans, smooth, tsysval,tauval,tcalval)) ### if verify: # get data import numpy precal={} postcal=[] keys=['','_calon'] types=[srctype.nod,srctype.nodcal] ifnos=list(scantab.getifnos()) polnos=list(scantab.getpolnos()) sel=selector() ss = scantab.copy() for i in range(2): #ss=scantab.get_scan('*'+keys[i]) ll=[] ll2=[] for j in range(len(ifnos)): for k in range(len(polnos)): sel.set_ifs(ifnos[j]) sel.set_polarizations(polnos[k]) sel.set_scans(pairScans[0]) sel.set_types(types[i]) try: ss.set_selection(sel) except: continue ll.append(numpy.array(ss._getspectrum(0))) sel.reset() ss.set_selection() sel.set_ifs(ifnos[j]) sel.set_polarizations(polnos[k]) sel.set_scans(pairScans[1]) sel.set_types(types[i]) try: ss.set_selection(sel) except: ll.pop() continue ll2.append(numpy.array(ss._getspectrum(0))) sel.reset() ss.set_selection() key='%s%s' %(pairScans[0],keys[i]) precal[key]=ll key='%s%s' %(pairScans[1],keys[i]) precal[key]=ll2 #del ss keys=precal.keys() for j in range(len(ifnos)): for k in range(len(polnos)): sel.set_ifs(ifnos[j]) sel.set_polarizations(polnos[k]) sel.set_scans(pairScans[0]) try: resspec.set_selection(sel) except: continue postcal.append(numpy.array(resspec._getspectrum(0))) sel.reset() resspec.set_selection() del sel # plot asaplog.post() asaplog.push('Plot only first spectrum for each [if,pol] pairs to verify calibration.') asaplog.post('WARN') #p=asaplotgui.asaplotgui() p=new_asaplot() #nr=min(6,len(ifnos)*len(polnos)) nr=len(ifnos)*len(polnos) titles=[] btics=[] if nr<4: p.set_panels(rows=nr,cols=2,nplots=2*nr,ganged=False) for i in range(2*nr): b=False if i >= 2*nr-2: b=True btics.append(b) elif nr==4: p.set_panels(rows=2,cols=4,nplots=8,ganged=False) for i in range(2*nr): b=False if i >= 2*nr-4: b=True btics.append(b) elif nr<7: p.set_panels(rows=3,cols=4,nplots=2*nr,ganged=False) for i in range(2*nr): if i >= 2*nr-4: b=True btics.append(b) else: asaplog.post() asaplog.push('Only first 6 [if,pol] pairs are plotted.') asaplog.post('WARN') nr=6 for i in range(2*nr): b=False if i >= 2*nr-4: b=True btics.append(b) p.set_panels(rows=3,cols=4,nplots=2*nr,ganged=False) for i in range(nr): p.subplot(2*i) p.color=0 title='raw data IF%s POL%s' % (ifnos[int(i/len(polnos))],polnos[i%len(polnos)]) titles.append(title) #p.set_axes('title',title,fontsize=40) ymin=1.0e100 ymax=-1.0e100 nchan=scantab.nchan(ifnos[int(i/len(polnos))]) edge=int(nchan*0.01) for j in range(4): spmin=min(precal[keys[j]][i][edge:nchan-edge]) spmax=max(precal[keys[j]][i][edge:nchan-edge]) ymin=min(ymin,spmin) ymax=max(ymax,spmax) for j in range(4): if i==0: p.set_line(label=keys[j]) else: p.legend() p.plot(precal[keys[j]][i]) p.axes.set_ylim(ymin-0.1*abs(ymin),ymax+0.1*abs(ymax)) if not btics[2*i]: p.axes.set_xticks([]) p.subplot(2*i+1) p.color=0 title='cal data IF%s POL%s' % (ifnos[int(i/len(polnos))],polnos[i%len(polnos)]) titles.append(title) #p.set_axes('title',title) p.legend() ymin=postcal[i][edge:nchan-edge].min() ymax=postcal[i][edge:nchan-edge].max() p.plot(postcal[i]) p.axes.set_ylim(ymin-0.1*abs(ymin),ymax+0.1*abs(ymax)) if not btics[2*i+1]: p.axes.set_xticks([]) for i in range(2*nr): p.subplot(i) p.set_axes('title',titles[i],fontsize='medium') x=raw_input('Accept calibration ([y]/n): ' ) if x.upper() == 'N': p.quit() del p return scabtab p.quit() del p ### resspec._add_history("calnod",varlist) return resspec @asaplog_post_dec def calfs(scantab, scannos=[], smooth=1, tsysval=0.0, tauval=0.0, tcalval=0.0, verify=False): """ Calibrate GBT frequency switched data. Adopted from GBTIDL getfs. Currently calfs identify the scans as frequency switched data if source type enum is fson and fsoff. The data must contains 'CAL' signal on/off in each integration. To identify 'CAL' on state, the source type enum of foncal and foffcal need to be present in the source name field. (GBT MS data reading via scantable automatically append these id names to the source names) Parameters: scantab: scantable scannos: list of scan numbers smooth: optional box smoothing order for the reference (default is 1 = no smoothing) tsysval: optional user specified Tsys (default is 0.0, use Tsys in the data) tauval: optional user specified Tau verify: Verify calibration if true """ varlist = vars() from asap._asap import stmath from asap._asap import srctype stm = stmath() stm._setinsitu(False) # check = scantab.get_scan('*_fs*') # if check is None: # msg = "The input data appear to contain no Nod observing mode data." # raise TypeError(msg) s = scantab.get_scan(scannos) del scantab resspec = scantable(stm._dofs(s, scannos, smooth, tsysval,tauval,tcalval)) ### if verify: # get data ssub = s.get_scan(scannos) #ssubon = ssub.get_scan('*calon') #ssuboff = ssub.get_scan('*[^calon]') sel = selector() sel.set_types( [srctype.foncal,srctype.foffcal] ) ssub.set_selection( sel ) ssubon = ssub.copy() ssub.set_selection() sel.reset() sel.set_types( [srctype.fson,srctype.fsoff] ) ssub.set_selection( sel ) ssuboff = ssub.copy() ssub.set_selection() sel.reset() import numpy precal={} postcal=[] keys=['fs','fs_calon','fsr','fsr_calon'] types=[srctype.fson,srctype.foncal,srctype.fsoff,srctype.foffcal] ifnos=list(ssub.getifnos()) polnos=list(ssub.getpolnos()) for i in range(2): #ss=ssuboff.get_scan('*'+keys[2*i]) ll=[] for j in range(len(ifnos)): for k in range(len(polnos)): sel.set_ifs(ifnos[j]) sel.set_polarizations(polnos[k]) sel.set_types(types[2*i]) try: #ss.set_selection(sel) ssuboff.set_selection(sel) except: continue ll.append(numpy.array(ss._getspectrum(0))) sel.reset() #ss.set_selection() ssuboff.set_selection() precal[keys[2*i]]=ll #del ss #ss=ssubon.get_scan('*'+keys[2*i+1]) ll=[] for j in range(len(ifnos)): for k in range(len(polnos)): sel.set_ifs(ifnos[j]) sel.set_polarizations(polnos[k]) sel.set_types(types[2*i+1]) try: #ss.set_selection(sel) ssubon.set_selection(sel) except: continue ll.append(numpy.array(ss._getspectrum(0))) sel.reset() #ss.set_selection() ssubon.set_selection() precal[keys[2*i+1]]=ll #del ss #sig=resspec.get_scan('*_fs') #ref=resspec.get_scan('*_fsr') sel.set_types( srctype.fson ) resspec.set_selection( sel ) sig=resspec.copy() resspec.set_selection() sel.reset() sel.set_type( srctype.fsoff ) resspec.set_selection( sel ) ref=resspec.copy() resspec.set_selection() sel.reset() for k in range(len(polnos)): for j in range(len(ifnos)): sel.set_ifs(ifnos[j]) sel.set_polarizations(polnos[k]) try: sig.set_selection(sel) postcal.append(numpy.array(sig._getspectrum(0))) except: ref.set_selection(sel) postcal.append(numpy.array(ref._getspectrum(0))) sel.reset() resspec.set_selection() del sel # plot asaplog.post() asaplog.push('Plot only first spectrum for each [if,pol] pairs to verify calibration.') asaplog.post('WARN') #p=asaplotgui.asaplotgui() p=new_asaplot() #nr=min(6,len(ifnos)*len(polnos)) nr=len(ifnos)/2*len(polnos) titles=[] btics=[] if nr>3: asaplog.post() asaplog.push('Only first 3 [if,pol] pairs are plotted.') asaplog.post('WARN') nr=3 p.set_panels(rows=nr,cols=3,nplots=3*nr,ganged=False) for i in range(3*nr): b=False if i >= 3*nr-3: b=True btics.append(b) for i in range(nr): p.subplot(3*i) p.color=0 title='raw data IF%s,%s POL%s' % (ifnos[2*int(i/len(polnos))],ifnos[2*int(i/len(polnos))+1],polnos[i%len(polnos)]) titles.append(title) #p.set_axes('title',title,fontsize=40) ymin=1.0e100 ymax=-1.0e100 nchan=s.nchan(ifnos[2*int(i/len(polnos))]) edge=int(nchan*0.01) for j in range(4): spmin=min(precal[keys[j]][i][edge:nchan-edge]) spmax=max(precal[keys[j]][i][edge:nchan-edge]) ymin=min(ymin,spmin) ymax=max(ymax,spmax) for j in range(4): if i==0: p.set_line(label=keys[j]) else: p.legend() p.plot(precal[keys[j]][i]) p.axes.set_ylim(ymin-0.1*abs(ymin),ymax+0.1*abs(ymax)) if not btics[3*i]: p.axes.set_xticks([]) p.subplot(3*i+1) p.color=0 title='sig data IF%s POL%s' % (ifnos[2*int(i/len(polnos))],polnos[i%len(polnos)]) titles.append(title) #p.set_axes('title',title) p.legend() ymin=postcal[2*i][edge:nchan-edge].min() ymax=postcal[2*i][edge:nchan-edge].max() p.plot(postcal[2*i]) p.axes.set_ylim(ymin-0.1*abs(ymin),ymax+0.1*abs(ymax)) if not btics[3*i+1]: p.axes.set_xticks([]) p.subplot(3*i+2) p.color=0 title='ref data IF%s POL%s' % (ifnos[2*int(i/len(polnos))+1],polnos[i%len(polnos)]) titles.append(title) #p.set_axes('title',title) p.legend() ymin=postcal[2*i+1][edge:nchan-edge].min() ymax=postcal[2*i+1][edge:nchan-edge].max() p.plot(postcal[2*i+1]) p.axes.set_ylim(ymin-0.1*abs(ymin),ymax+0.1*abs(ymax)) if not btics[3*i+2]: p.axes.set_xticks([]) for i in range(3*nr): p.subplot(i) p.set_axes('title',titles[i],fontsize='medium') x=raw_input('Accept calibration ([y]/n): ' ) if x.upper() == 'N': p.quit() del p return scabtab p.quit() del p ### resspec._add_history("calfs",varlist) return resspec @asaplog_post_dec def merge(*args): """ Merge a list of scanatables, or comma-sperated scantables into one scnatble. Parameters: A list [scan1, scan2] or scan1, scan2. Example: myscans = [scan1, scan2] allscans = merge(myscans) # or equivalent sameallscans = merge(scan1, scan2) """ varlist = vars() if isinstance(args[0],list): lst = tuple(args[0]) elif isinstance(args[0],tuple): lst = args[0] else: lst = tuple(args) varlist["args"] = "%d scantables" % len(lst) # need special formatting her for history... from asap._asap import stmath stm = stmath() for s in lst: if not isinstance(s,scantable): msg = "Please give a list of scantables" raise TypeError(msg) s = scantable(stm._merge(lst)) s._add_history("merge", varlist) return s @asaplog_post_dec def calibrate( scantab, scannos=[], calmode='none', verify=None ): """ Calibrate data. Parameters: scantab: scantable scannos: list of scan number calmode: calibration mode verify: verify calibration """ import re antname = scantab.get_antennaname() if ( calmode == 'nod' ): asaplog.push( 'Calibrating nod data.' ) scal = calnod( scantab, scannos=scannos, verify=verify ) elif ( calmode == 'quotient' ): asaplog.push( 'Calibrating using quotient.' ) scal = scantab.auto_quotient( verify=verify ) elif ( calmode == 'ps' ): asaplog.push( 'Calibrating %s position-switched data.' % antname ) if ( antname.find( 'APEX' ) != -1 ): scal = apexcal( scantab, scannos, calmode, verify ) elif ( antname.find( 'ALMA' ) != -1 or antname.find( 'OSF' ) != -1 or re.match('DV[0-9][0-9]$',antname) is not None or re.match('PM[0-9][0-9]$',antname) is not None or re.match('CM[0-9][0-9]$',antname) is not None or re.match('DA[0-9][0-9]$',antname) is not None ): scal = almacal( scantab, scannos, calmode, verify ) else: scal = calps( scantab, scannos=scannos, verify=verify ) elif ( calmode == 'fs' or calmode == 'fsotf' ): asaplog.push( 'Calibrating %s frequency-switched data.' % antname ) if ( antname.find( 'APEX' ) != -1 ): scal = apexcal( scantab, scannos, calmode, verify ) elif ( antname.find( 'ALMA' ) != -1 or antname.find( 'OSF' ) != -1 ): scal = almacal( scantab, scannos, calmode, verify ) else: scal = calfs( scantab, scannos=scannos, verify=verify ) elif ( calmode == 'otf' ): asaplog.push( 'Calibrating %s On-The-Fly data.' % antname ) scal = almacal( scantab, scannos, calmode, verify ) else: asaplog.push( 'No calibration.' ) scal = scantab.copy() return scal def apexcal( scantab, scannos=[], calmode='none', verify=False ): """ Calibrate APEX data Parameters: scantab: scantable scannos: list of scan number calmode: calibration mode verify: verify calibration """ from asap._asap import stmath stm = stmath() antname = scantab.get_antennaname() ssub = scantab.get_scan( scannos ) scal = scantable( stm.cwcal( ssub, calmode, antname ) ) return scal def almacal( scantab, scannos=[], calmode='none', verify=False ): """ Calibrate ALMA data Parameters: scantab: scantable scannos: list of scan number calmode: calibration mode verify: verify calibration """ from asap._asap import stmath stm = stmath() selection=selector() selection.set_scans(scannos) orig = scantab.get_selection() scantab.set_selection(orig+selection) ## ssub = scantab.get_scan( scannos ) ## scal = scantable( stm.almacal( ssub, calmode ) ) scal = scantable( stm.almacal( scantab, calmode ) ) scantab.set_selection(orig) return scal @asaplog_post_dec def splitant(filename, outprefix='',overwrite=False): """ Split Measurement set by antenna name, save data as a scantables, and return a list of filename. Notice this method can only be available from CASA. Prameter filename: the name of Measurement set to be read. outprefix: the prefix of output scantable name. the names of output scantable will be outprefix.antenna1, outprefix.antenna2, .... If not specified, outprefix = filename is assumed. overwrite If the file should be overwritten if it exists. The default False is to return with warning without writing the output. USE WITH CARE. """ # Import the table toolkit from CASA import casac from asap.scantable import is_ms tbtool = casac.homefinder.find_home_by_name('tableHome') tb = tbtool.create() # Check the input filename if isinstance(filename, str): import os.path filename = os.path.expandvars(filename) filename = os.path.expanduser(filename) if not os.path.exists(filename): s = "File '%s' not found." % (filename) raise IOError(s) # check if input file is MS #if not os.path.isdir(filename) \ # or not os.path.exists(filename+'/ANTENNA') \ # or not os.path.exists(filename+'/table.f1'): if not is_ms(filename): s = "File '%s' is not a Measurement set." % (filename) raise IOError(s) else: s = "The filename should be string. " raise TypeError(s) # Check out put file name outname='' if len(outprefix) > 0: prefix=outprefix+'.' else: prefix=filename.rstrip('/') # Now do the actual splitting. outfiles=[] tb.open(tablename=filename,nomodify=True) ant1=tb.getcol('ANTENNA1',0,-1,1) #anttab=tb.getkeyword('ANTENNA').split()[-1] anttab=tb.getkeyword('ANTENNA').lstrip('Table: ') tb.close() #tb.open(tablename=filename+'/ANTENNA',nomodify=True) tb.open(tablename=anttab,nomodify=True) nant=tb.nrows() antnames=tb.getcol('NAME',0,nant,1) tb.close() tmpname='asapmath.splitant.tmp' for antid in set(ant1): tb.open(tablename=filename,nomodify=True) tbsel=tb.query('ANTENNA1 == %s && ANTENNA2 == %s'%(antid,antid),tmpname) scan=scantable(tmpname,average=False,getpt=True,antenna=int(antid)) outname=prefix+antnames[antid]+'.asap' scan.save(outname,format='ASAP',overwrite=overwrite) tbsel.close() tb.close() del tbsel del scan outfiles.append(outname) os.system('rm -rf '+tmpname) del tb return outfiles @asaplog_post_dec def _array2dOp( scan, value, mode="ADD", tsys=False, insitu=None): """ This function is workaround on the basic operation of scantable with 2 dimensional float list. scan: scantable operand value: float list operand mode: operation mode (ADD, SUB, MUL, DIV) tsys: if True, operate tsys as well insitu: if False, a new scantable is returned. Otherwise, the array operation is done in-sitsu. """ nrow = scan.nrow() s = None from asap._asap import stmath stm = stmath() stm._setinsitu(insitu) if len( value ) == 1: s = scantable( stm._arrayop( scan, value[0], mode, tsys ) ) elif len( value ) != nrow: raise ValueError( 'len(value) must be 1 or conform to scan.nrow()' ) else: from asap._asap import stmath if not insitu: s = scan.copy() else: s = scan # insitu must be True as we go row by row on the same data stm._setinsitu( True ) basesel = s.get_selection() # generate a new selector object based on basesel sel = selector(basesel) for irow in range( nrow ): sel.set_rows( irow ) s.set_selection( sel ) if len( value[irow] ) == 1: stm._unaryop( s, value[irow][0], mode, tsys ) else: #stm._arrayop( s, value[irow], mode, tsys, 'channel' ) stm._arrayop( s, value[irow], mode, tsys ) s.set_selection(basesel) return s