Exemplo n.º 1
0
def run(config, tim=None):
    """
    This method is where the data reduction process gets done.

    @param config: Object containing the data reduction configuration
                   information.
    @type config: L{hlr_utils.Configure}

    @param tim: (OPTIONAL) Object that will allow the method to perform
                           timing evaluations.
    @type tim: C{sns_time.DiffTime}
    """
    import common_lib
    import dr_lib
    import DST
    
    if tim is not None:
        tim.getTime(False)
        old_time = tim.getOldTime()

    if config.data is None:
        raise RuntimeError("Need to pass a data filename to the driver "\
                           +"script.")

    # Read in geometry if one is provided
    if config.inst_geom is not None:
        if config.verbose:
            print "Reading in instrument geometry file"
            
        inst_geom_dst = DST.getInstance("application/x-NxsGeom",
                                        config.inst_geom)
    else:
        inst_geom_dst = None

    config.so_axis = "time_of_flight"

    # Steps 1-3: Produce a scaled summed dark current dataset
    dc_som = dr_lib.scaled_summed_data(config.dkcur, config,
                                       dataset_type="dark_current",
                                       timer=tim)

    # Perform Steps 3-6 on black can data
    if config.bcan is not None:
        b_som1 = dr_lib.calibrate_dgs_data(config.bcan, config, dc_som,
                                           dataset_type="black_can",
                                           inst_geom_dst=inst_geom_dst,
                                           tib_const=config.tib_const,
                                           cwp=config.cwp_bcan,
                                           timer=tim)
    else:
        b_som1 = None

    # Perform Steps 3-6 on empty can data    
    if config.ecan is not None:
        e_som1 = dr_lib.calibrate_dgs_data(config.ecan, config, dc_som,
                                           dataset_type="empty_can",
                                           inst_geom_dst=inst_geom_dst,
                                           tib_const=config.tib_const,
                                           cwp=config.cwp_ecan,
                                           timer=tim)
    else:
        e_som1 = None

    # Perform Steps 3-6 on normalization data
    n_som1 = dr_lib.calibrate_dgs_data(config.data, config, dc_som,
                                       dataset_type="normalization",
                                       inst_geom_dst=inst_geom_dst,
                                       tib_const=config.tib_const,
                                       cwp=config.cwp_data,
                                       timer=tim)

    # Perform Steps 7-16 on normalization data
    if config.norm_trans_coeff is None:
        norm_trans_coeff = None
    else:
        norm_trans_coeff = config.norm_trans_coeff.toValErrTuple()

    # Determine if we need to rebin the empty or black can data
    if config.ecan is not None and e_som1 is not None:
        ecan_cwp = True
    else:
        ecan_cwp = False

    if config.bcan is not None and b_som1 is not None:
        bcan_cwp = True
    else:
        bcan_cwp = False        

    cwp_used = ecan_cwp or bcan_cwp

    n_som2 = dr_lib.process_dgs_data(n_som1, config, b_som1, e_som1,
                                     norm_trans_coeff,
                                     dataset_type="normalization",
                                     cwp_used=cwp_used,
                                     timer=tim)
        
    del n_som1, b_som1, e_som1

    # Step 17: Integrate normalization spectra
    if config.verbose:
        print "Integrating normalization spectra"

    if tim is not None:
        tim.getTime(False)

    if config.norm_int_range is None:
        start_val = float("inf")
        end_val = float("inf")
    else:
        if not config.wb_norm:
            # Translate energy transfer to final energy
            ef_start = config.initial_energy.getValue() - \
                       config.norm_int_range[0]
            ef_end = config.initial_energy.getValue() - \
                     config.norm_int_range[1]
            # Convert final energy to final wavelength
            start_val = common_lib.energy_to_wavelength((ef_start, 0.0))[0]
            end_val = common_lib.energy_to_wavelength((ef_end, 0.0))[0]
        else:
            start_val = config.norm_int_range[0]
            end_val = config.norm_int_range[1]
            
    n_som3 = dr_lib.integrate_spectra(n_som2, start=start_val,
                                      end=end_val, width=True)

    del n_som2
    
    if tim is not None:
        tim.getTime(msg="After integrating normalization spectra ")

    file_comment = "Normalization Integration range: %0.3fA, %0.3fA" \
                   % (start_val, end_val)
        
    hlr_utils.write_file(config.output, "text/num-info", n_som3,
                         output_ext="norm",
                         data_ext=config.ext_replacement,
                         path_replacement=config.path_replacement,
                         verbose=config.verbose,
                         message="normalization values",
                         comments=[file_comment],
                         tag="Integral", units="counts")   
    
    if tim is not None:
        tim.getTime(False)

    if config.verbose:
        print "Making mask file"

    # Make mask file from threshold
    dr_lib.filter_normalization(n_som3, config.lo_threshold,
                                config.hi_threshold, config)

    if tim is not None:
        tim.getTime(msg="After making mask file ")

    # Write out RMD file
    n_som3.attr_list["config"] = config

    hlr_utils.write_file(config.output, "text/rmd", n_som3,
                         output_ext="rmd",
                         data_ext=config.ext_replacement,         
                         path_replacement=config.path_replacement,
                         verbose=config.verbose,
                         message="metadata")
    
    if tim is not None:
        tim.setOldTime(old_time)
        tim.getTime(msg="Total Running Time")
Exemplo n.º 2
0
def run(config, tim=None):
    """
    This method is where the data reduction process gets done.

    @param config: Object containing the data reduction configuration
                   information.
    @type config: L{hlr_utils.Configure}

    @param tim: (OPTIONAL) Object that will allow the method to perform
                           timing evaluations.
    @type tim: C{sns_time.DiffTime}
    """
    import common_lib
    import dr_lib
    import DST

    if tim is not None:
        tim.getTime(False)
        old_time = tim.getOldTime()

    if config.data is None:
        raise RuntimeError("Need to pass a data filename to the driver "\
                           +"script.")

    # Read in geometry if one is provided
    if config.inst_geom is not None:
        if config.verbose:
            print "Reading in instrument geometry file"
            
        inst_geom_dst = DST.getInstance("application/x-NxsGeom",
                                        config.inst_geom)
    else:
        inst_geom_dst = None

    # Perform early background subtraction if the hwfix flag is used
    if config.hwfix:
        if not config.mc:
            so_axis = "time_of_flight"
        else:
            so_axis = "Time_of_Flight"
        
        bkg_som0 = dr_lib.add_files(config.back,
                                    Data_Paths=config.data_paths.toPath(),
                                    SO_Axis=so_axis,
                                    Signal_ROI=config.roi_file,
                                    dataset_type="background",
                                    Verbose=config.verbose, Timer=tim)

        bkg_som = dr_lib.fix_bin_contents(bkg_som0)
        del bkg_som0
    else:
        bkg_som = None

    # Perform Steps 1-15 on sample data
    d_som1 = dr_lib.process_igs_data(config.data, config, timer=tim,
                                     inst_geom_dst=inst_geom_dst,
                                     tib_const=config.tib_data_const,
                                     bkg_som=bkg_som)

    # Perform Steps 1-15 on empty can data
    if config.ecan is not None:
        e_som1 = dr_lib.process_igs_data(config.ecan, config, timer=tim,
                                         inst_geom_dst=inst_geom_dst,
                                         dataset_type="empty_can",
                                         tib_const=config.tib_ecan_const,
                                         bkg_som=bkg_som)
    else:
        e_som1 = None

    # Perform Steps 1-15 on normalization data            
    if config.norm is not None:
        n_som1 = dr_lib.process_igs_data(config.norm, config, timer=tim,
                                         inst_geom_dst=inst_geom_dst,
                                         dataset_type="normalization",
                                         tib_const=config.tib_norm_const,
                                         bkg_som=bkg_som)
    else:
        n_som1 = None

    # Perform Steps 1-15 on background data
    if config.back is not None and not config.hwfix:
        b_som1 = dr_lib.process_igs_data(config.back, config, timer=tim,
                                         inst_geom_dst=inst_geom_dst,
                                         dataset_type="background",
                                         tib_const=config.tib_back_const)
    else:
        b_som1 = None

    # Perform Step 1-15 on direct scattering background data
    if config.dsback is not None:
        ds_som1 = dr_lib.process_igs_data(config.dsback, config, timer=tim,
                                          inst_geom_dst=inst_geom_dst,
                                          tib_const=config.tib_dsback_const,
                                          dataset_type="dsbackground",
                                          bkg_som=bkg_som)

        # Note: time_zero_slope MUST be a tuple
        if config.time_zero_slope is not None:
            ds_som1.attr_list["Time_zero_slope"] = \
                                      config.time_zero_slope.toValErrTuple()

        # Note: time_zero_offset MUST be a tuple
        if config.time_zero_offset is not None:
            ds_som1.attr_list["Time_zero_offset"] = \
                                      config.time_zero_offset.toValErrTuple()
        
        # Step 16: Linearly interpolate TOF elastic range in direct scattering
        #          background data

        # First convert TOF elastic range to appropriate pixel initial
        # wavelengths
        if config.verbose:
            print "Determining initial wavelength range for elastic line"

        if tim is not None:
            tim.getTime(False)
        
        if config.tof_elastic is None:
            # Units are in microseconds
            tof_elastic_range = (140300, 141300)
        else:
            tof_elastic_range = config.tof_elastic
        
        ctof_elastic_low = dr_lib.convert_single_to_list(\
               "tof_to_initial_wavelength_igs_lin_time_zero",
               (tof_elastic_range[0], 0.0),
               ds_som1)
        
        ctof_elastic_high = dr_lib.convert_single_to_list(\
               "tof_to_initial_wavelength_igs_lin_time_zero",
               (tof_elastic_range[1], 0.0),
               ds_som1)
        
        ctof_elastic_range = [(ctof_elastic_low[i][0], ctof_elastic_high[i][0])
                              for i in xrange(len(ctof_elastic_low))]

        if tim is not None:
            tim.getTime(msg="After calculating initial wavelength range for "\
                        +"elastic line ")

        del ctof_elastic_low, ctof_elastic_high

        # Now interpolate spectra between TOF elastic range (converted to
        # initial wavelength)
        if config.verbose:
            print "Linearly interpolating direct scattering spectra"

        if tim is not None:
            tim.getTime(False)
            
        ds_som2 = dr_lib.lin_interpolate_spectra(ds_som1, ctof_elastic_range)

        if tim is not None:
            tim.getTime(msg="After linearly interpolating direct scattering "\
                        +"spectra ")

        if config.dump_dslin:
            ds_som2_1 = dr_lib.sum_all_spectra(ds_som2,\
                                  rebin_axis=config.lambda_bins.toNessiList())

            hlr_utils.write_file(config.output, "text/Spec", ds_som2_1,
                                 output_ext="lin",
                                 data_ext=config.ext_replacement,    
                                 path_replacement=config.path_replacement,
                                 verbose=config.verbose,
                                 message="dsbackground linear interpolation")
            del ds_som2_1
        
        del ds_som1
    else:
        ds_som2 = None

    if inst_geom_dst is not None:
        inst_geom_dst.release_resource()
        
    # Steps 17-18: Subtract background spectrum from sample spectrum
    if config.dsback is None:
        back_som = b_som1
        bkg_type = "background"
    else:
        back_som = ds_som2
        bkg_type = "dsbackground"
    d_som2 = dr_lib.subtract_bkg_from_data(d_som1, back_som,
                                           verbose=config.verbose,
                                           timer=tim,
                                           dataset1="data",
                                           dataset2=bkg_type,
                                           scale=config.scale_bs)

    if config.dsback is not None:
        del ds_som2 

    # Step 19: Zero region outside TOF elastic for background for empty can
    if config.dsback is None:
        bcs_som = b_som1
        cs_som = e_som1
    else:
        if config.verbose and b_som1 is not None:
            print "Zeroing background spectra"

        if tim is not None and b_som1 is not None:
            tim.getTime(False)
            
        bcs_som = dr_lib.zero_spectra(b_som1, ctof_elastic_range)

        if tim is not None and b_som1 is not None:
            tim.getTime(msg="After zeroing background spectra")


        if config.verbose and e_som1 is not None:
            print "Zeroing empty can spectra"

        if tim is not None and e_som1 is not None:
            tim.getTime(False)
            
        cs_som = dr_lib.zero_spectra(e_som1, ctof_elastic_range)

        if tim is not None and e_som1 is not None:
            tim.getTime(msg="After zeroing empty can spectra")
            
        del ctof_elastic_range

    # Steps 20-21: Subtract background spectrum from empty can spectrum    
    e_som2 = dr_lib.subtract_bkg_from_data(cs_som, bcs_som,
                                           verbose=config.verbose,
                                           timer=tim,
                                           dataset1="empty_can",
                                           dataset2="background",
                                           scale=config.scale_bcs)

    # Steps 22-23: Subtract background spectrum from empty can spectrum for
    #              normalization
    e_som3 = dr_lib.subtract_bkg_from_data(e_som1, b_som1,
                                           verbose=config.verbose,
                                           timer=tim,
                                           dataset1="empty_can",
                                           dataset2="background",
                                           scale=config.scale_bcn)

    # Steps 24-25: Subtract background spectrum from normalization spectrum
    n_som2 = dr_lib.subtract_bkg_from_data(n_som1, b_som1,
                                           verbose=config.verbose,
                                           timer=tim,
                                           dataset1="normalization",
                                           dataset2="background",
                                           scale=config.scale_bn)

    del b_som1, e_som1, bcs_som, cs_som

    # Steps 26-27: Subtract empty can spectrum from sample spectrum    
    d_som3 = dr_lib.subtract_bkg_from_data(d_som2, e_som2,
                                           verbose=config.verbose,
                                           timer=tim,
                                           dataset1="data",
                                           dataset2="empty_can",
                                           scale=config.scale_cs)

    del d_som2, e_som2
    
    # Steps 28-29: Subtract empty can spectrum from normalization spectrum
    n_som3 = dr_lib.subtract_bkg_from_data(n_som2, e_som3,
                                           verbose=config.verbose,
                                           timer=tim,
                                           dataset1="normalization",
                                           dataset2="empty_can",
                                           scale=config.scale_cn)    

    del n_som2, e_som3

    # Step 30-32: Integrate normalization spectra
    if config.verbose and n_som3 is not None:
        print "Integrating normalization spectra"

    norm_int = dr_lib.integrate_spectra(n_som3, start=config.norm_start,
                                        end=config.norm_end, norm=True)

    del n_som3
        
    # Step 33: Normalize data by integrated values
    if config.verbose and norm_int is not None:
        print "Normalizing data by normalization data"

    if norm_int is not None:
        d_som4 = common_lib.div_ncerr(d_som3, norm_int)
    else:
        d_som4 = d_som3

    if norm_int is not None:
        if tim is not None:
            tim.getTime(msg="After normalizing data ")

    del d_som3, norm_int

    # Step 35: Convert initial wavelength to E_initial
    if config.verbose:
        print "Converting initial wavelength to E_initial"
        
    if tim is not None:
        tim.getTime(False)

    d_som6 = common_lib.wavelength_to_energy(d_som4)
        
    if tim is not None:
        tim.getTime(msg="After converting initial wavelength to E_initial ")

    if config.dump_initial_energy:
        hlr_utils.write_file(config.output, "text/Spec", d_som6,
                             output_ext="ixl",
                             data_ext=config.ext_replacement,
                             path_replacement=config.path_replacement,
                             verbose=config.verbose,
                             message="pixel initial energy information")
            
    del d_som4

    # Steps 36-37: Calculate energy transfer
    if config.verbose:
        print "Calculating energy transfer"

    if tim is not None:
        tim.getTime(False)

    d_som7 = dr_lib.igs_energy_transfer(d_som6)

    if tim is not None:
        tim.getTime(msg="After calculating energy transfer ")
        
    if config.dump_energy:
        hlr_utils.write_file(config.output, "text/Spec", d_som7,
                             output_ext="exl",
                             data_ext=config.ext_replacement,
                             path_replacement=config.path_replacement,
                             verbose=config.verbose,
                             message="pixel energy transfer information")

    # Write 3-column ASCII file for E_t
    d_som7_1 = dr_lib.sum_all_spectra(d_som7,
                                      rebin_axis=config.E_bins.toNessiList())
    hlr_utils.write_file(config.output, "text/Spec", d_som7_1,
                         output_ext="etr",
                         data_ext=config.ext_replacement,
                         path_replacement=config.path_replacement,
                         verbose=config.verbose,
                         message="combined energy transfer information") 
    
    del d_som7_1

    # Steps 34,36-37: Calculate scaled energy transfer
    if config.verbose:
        print "Calculating scaled energy transfer"
        
    d_som9 = dr_lib.igs_energy_transfer(d_som6, scale=True)
    
    if tim is not None:
        tim.getTime(msg="After calculating scaled energy transfer ")

    if config.dump_energy:
        hlr_utils.write_file(config.output, "text/Spec", d_som9,
                             output_ext="sexl",
                             data_ext=config.ext_replacement,    
                             path_replacement=config.path_replacement,
                             verbose=config.verbose,
                             message="pixel scaled energy transfer "\
                             +"information")

    # Write 3-column ASCII file for scaled E_t
    d_som9_1 = dr_lib.sum_all_spectra(d_som9,
                                      rebin_axis=config.E_bins.toNessiList())
    hlr_utils.write_file(config.output, "text/Spec", d_som9_1,
                         output_ext="setr",
                         data_ext=config.ext_replacement,            
                         path_replacement=config.path_replacement,
                         verbose=config.verbose,
                         message="combined scaled energy transfer "\
                         +"information") 
    
    del d_som9_1
    
    del d_som6, d_som7
        
    d_som9.attr_list["config"] = config
    
    hlr_utils.write_file(config.output, "text/rmd", d_som9,
                         output_ext="rmd",
                         data_ext=config.ext_replacement,         
                         path_replacement=config.path_replacement,
                         verbose=config.verbose,
                         message="metadata")
    
    if tim is not None:
        tim.setOldTime(old_time)
        tim.getTime(msg="Total Running Time")
Exemplo n.º 3
0
def calibrate_dgs_data(datalist, conf, dkcur, **kwargs):
    """
    This function combines Steps 3 through 6 in Section 2.1.1 of the data
    reduction process for Direct Geometry Spectrometers as specified by the
    document at 
    U{http://neutrons.ornl.gov/asg/projects/SCL/reqspec/DR_Lib_RS.doc}. The
    function takes a list of file names, a L{hlr_utils.Configure} object and
    processes the data accordingly.
    
    @param datalist: A list containing the filenames of the data to be
                     processed.
    @type datalist: C{list} of C{string}s
    
    @param conf: Object that contains the current setup of the driver.
    @type conf: L{hlr_utils.Configure}

    @param dkcur: The object containing the TOF dark current data.
    @type dkcur: C{SOM.SOM}
    
    @param kwargs: A list of keyword arguments that the function accepts:
    
    @keyword inst_geom_dst: File object that contains instrument geometry
                            information.
    @type inst_geom_dst: C{DST.GeomDST}

    @keyword tib_const: A time-independent background constant to subtract
                        from every pixel.
    @type tib_const: L{hlr_utils.DrParameter}
    
    @keyword dataset_type: The practical name of the dataset being processed.
                           The default value is I{data}.
    @type dataset_type: C{string}

    @keyword cwp: A list of chopper phase corrections in units of microseconds.
    @type cwp: C{list} of C{float}s
    
    @keyword timer: Timing object so the function can perform timing estimates.
    @type timer: C{sns_timer.DiffTime}


    @return: Object that has undergone all requested processing steps
    @rtype: C{SOM.SOM}
    """
    import common_lib
    import dr_lib
    import hlr_utils

    # Check keywords
    try:
        tib_const = kwargs["tib_const"]
    except KeyError:
        tib_const = None
    
    try:
        dataset_type = kwargs["dataset_type"]
    except KeyError:
        dataset_type = "data"

    try:
        t = kwargs["timer"]
    except KeyError:
        t = None

    try:
        i_geom_dst = kwargs["inst_geom_dst"]
    except KeyError:
        i_geom_dst = None

    dataset_cwp = kwargs.get("cwp")

    # Open the appropriate datafiles
    if conf.verbose:
        print "Reading %s file" % dataset_type

    data_paths = conf.data_paths.toPath()
    if conf.no_mon_norm:
        mon_paths = None
    else:
        mon_paths = conf.usmon_path.toPath()

    # Check for mask file since normalization drive doesn't understand option
    try:
        mask_file = conf.mask_file
    except AttributeError:
        mask_file = None

    if t is not None:
        oldtime = t.getOldTime()

    (dp_som0, dm_som0) = dr_lib.add_files_dm(datalist, Data_Paths=data_paths,
                                             Mon_Paths=mon_paths,
                                             SO_Axis=conf.so_axis,
                                             Signal_ROI=conf.roi_file,
                                             Signal_MASK=mask_file,
                                             dataset_type=dataset_type,
                                             dataset_cwp=dataset_cwp,
                                             Verbose=conf.verbose, Timer=t)

    if t is not None:
        t.setOldTime(oldtime)
        t.getTime(msg="After reading %s file" % dataset_type)

    # Cut the spectra if necessary
    dp_somA = dr_lib.cut_spectra(dp_som0, conf.tof_cut_min, conf.tof_cut_max)

    del dp_som0

    dp_somB = dr_lib.fix_bin_contents(dp_somA)

    del dp_somA

    if dp_somB.attr_list.instrument.get_name() != "CNCS":

        if conf.verbose:
            print "Cutting spectrum at minimum TOF"
        
        if t is not None:
            t.getTime(False)

        # Calculate minimum TOF for physical neutrons
        if conf.initial_energy is not None:
            initial_wavelength = common_lib.energy_to_wavelength(\
            conf.initial_energy.toValErrTuple())
            initial_velocity = common_lib.wavelength_to_velocity(\
            initial_wavelength)
        else:
            # This should actually calculate it, but don't have a way right now
            pass

        if conf.time_zero_offset is not None:
            time_zero_offset = conf.time_zero_offset.toValErrTuple()
        else:
            # This should actually calculate it, but don't have a way right now
            time_zero_offset = (0.0, 0.0)

        ss_length = dp_somB.attr_list.instrument.get_primary()
        
        tof_min = (ss_length[0] / initial_velocity[0]) + time_zero_offset[0]

        # Cut all spectra a the minimum TOF
        dp_som1 = dr_lib.cut_spectra(dp_somB, tof_min, None)

        if t is not None:
            t.getTime(msg="After cutting spectrum at minimum TOF ")
    else:
        dp_som1 = dp_somB

    del dp_somB

    if dm_som0 is not None:
        dm_som1 = dr_lib.fix_bin_contents(dm_som0)
    else:
        dm_som1 = dm_som0

    del dm_som0    

    # Override geometry if necessary
    if conf.inst_geom is not None:
        i_geom_dst.setGeometry(data_paths, dp_som1)

    if conf.inst_geom is not None and dm_som1 is not None:
        i_geom_dst.setGeometry(mon_paths, dm_som1)
    
    # Step 3: Integrate the upstream monitor
    if dm_som1 is not None:
        if conf.verbose:
            print "Integrating upstream monitor spectrum"

        if t is not None:
            t.getTime(False)
        
        if conf.mon_int_range is None:
            start_val = float("inf")
            end_val = float("inf")
        else:
            start_val = conf.mon_int_range[0]
            end_val = conf.mon_int_range[1]
        
        dm_som2 = dr_lib.integrate_spectra(dm_som1, start=start_val,
                                           end=end_val,
                                           width=True)
        if t is not None:
            t.getTime(msg="After integrating upstream monitor spectrum ")
    else:
        dm_som2 = dm_som1

    del dm_som1

    tib_norm_const = None
    
    # Step 4: Divide data set by summed monitor spectrum
    if dm_som2 is not None:
        if conf.verbose:
            print "Normalizing %s by monitor sum" % dataset_type

        if t is not None:
            t.getTime(False)

        dp_som2 = common_lib.div_ncerr(dp_som1, dm_som2, length_one_som=True)

        tib_norm_const = dm_som2[0].y

        if t is not None:
            t.getTime(msg="After normalizing %s by monitor sum" % dataset_type)

    elif conf.pc_norm:
        if conf.verbose:
            print "Normalizing %s by proton charge" % dataset_type

        pc_tag = dataset_type+"-proton_charge"
        pc = dp_som1.attr_list[pc_tag]

        # Scale the proton charge and then set the scale PC back to attributes
        if conf.scale_pc is not None:
            if conf.verbose:
                print "Scaling %s proton charge" % dataset_type

            pc = hlr_utils.scale_proton_charge(pc, conf.scale_pc)
            dp_som1.attr_list[pc_tag] = pc

        tib_norm_const = pc.getValue()

        if t is not None:
            t.getTime(False)

        dp_som2 = common_lib.div_ncerr(dp_som1, (pc.getValue(), 0.0))

        if t is not None:
            t.getTime(msg="After normalizing %s by proton charge" \
                      % dataset_type)

    else:
        dp_som2 = dp_som1

    del dp_som1, dm_som2

    # Step 5: Scale dark current by data set measurement time
    if dkcur is not None:
        if conf.verbose:
            print "Scaling dark current by %s acquisition time" % dataset_type

        if t is not None:
            t.getTime(False)

        dstime_tag = dataset_type+"-duration"
        dstime = dp_som2.attr_list[dstime_tag]

        dkcur1 = common_lib.div_ncerr(dkcur, (dstime.getValue(), 0.0))

        if t is not None:
            t.getTime(msg="After scaling dark current by %s acquisition time" \
                      % dataset_type)        
    else:
        dkcur1 = dkcur

    del dkcur

    # Step 6: Subtract scaled dark current from data set
    if dkcur1 is not None:
        if conf.verbose:
            print "Subtracting %s by scaled dark current" % dataset_type

        if t is not None:
            t.getTime(False)

        dp_som3 = common_lib.sub_ncerr(dp_som2, dkcur1)

        if t is not None:
            t.getTime(msg="After subtracting %s by scaled dark current" \
                      % dataset_type)
    elif tib_const is not None and dkcur1 is None:
        if conf.verbose:
            print "Subtracting TIB constant from %s" % dataset_type

        # Normalize the TIB constant by dividing by the current normalization
        # the duration (if necessary) and the conversion from seconds to
        # microseconds
        tib_c = tib_const.toValErrTuple()

        conv_sec_to_usec = 1.0e-6

        if tib_norm_const is None:
            tib_norm_const = 1
            duration = 1
        else:
            duration_tag = dataset_type+"-duration"
            duration = dp_som2.attr_list[duration_tag].getValue()

        norm_const = (duration * conv_sec_to_usec) / tib_norm_const

        tib_val = tib_c[0] * norm_const
        tib_err2 = tib_c[1] * (norm_const * norm_const)

        if t is not None:
            t.getTime(False)
  
        dp_som3 = common_lib.sub_ncerr(dp_som2, (tib_val, tib_err2))

        if t is not None:
            t.getTime(msg="After subtracting TIB constant from %s" \
                      % dataset_type)
    elif conf.tib_range is not None and dkcur1 is None:
        if conf.verbose:
            print "Determining TIB constant from %s" % dataset_type

        if t is not None:
            t.getTime(False)

        TIB = dr_lib.determine_time_indep_bkg(dp_som2, conf.tib_range,
                                              is_range=True)

        if t is not None:
            t.getTime(msg="After determining TIB constant from %s" \
                      % dataset_type)

        if conf.dump_tib:
            file_comment = "TIB TOF Range: [%d, %d]" % (conf.tib_range[0],
                                                        conf.tib_range[1])
        
            hlr_utils.write_file(conf.output, "text/num-info", TIB,
                                 output_ext="tib",
                                 extra_tag=dataset_type,
                                 verbose=conf.verbose,
                                 data_ext=conf.ext_replacement,
                                 path_replacement=conf.path_replacement,
                                 message="time-independent background "\
                                 +"information",
                                 tag="Average TIB",
                                 units="counts/usec",
                                 comments=[file_comment])
            
        if conf.verbose:
            print "Subtracting TIB constant from %s" % dataset_type

        if t is not None:
            t.getTime(False)

        dp_som3 = common_lib.sub_ncerr(dp_som2, TIB)

        if t is not None:
            t.getTime(msg="After subtracting TIB constant from %s" \
                      % dataset_type)

        del TIB
    else:
        dp_som3 = dp_som2

    del dp_som2, dkcur1

    if conf.dump_ctof_comb:
        dp_som3_1 = dr_lib.sum_all_spectra(dp_som3)
        hlr_utils.write_file(conf.output, "text/Spec", dp_som3_1,
                             output_ext="ctof",
                             extra_tag=dataset_type,
                             data_ext=conf.ext_replacement,    
                             path_replacement=conf.path_replacement,
                             verbose=conf.verbose,
                             message="combined calibrated TOF information")
        
        del dp_som3_1
    
    return dp_som3
Exemplo n.º 4
0
def run(config, tim=None):
    """
    This method is where the data reduction process gets done.

    @param config: Object containing the data reduction configuration
                   information.
    @type config: L{hlr_utils.Configure}

    @param tim: (OPTIONAL) Object that will allow the method to perform
                           timing evaluations.
    @type tim: C{sns_time.DiffTime}
    """
    import common_lib
    import dr_lib
    import DST

    if tim is not None:
        tim.getTime(False)
        old_time = tim.getOldTime()

    if config.data is None:
        raise RuntimeError("Need to pass a data filename to the driver "\
                           +"script.")

    # Read in geometry if one is provided
    if config.inst_geom is not None:
        if config.verbose:
            print "Reading in instrument geometry file"
            
        inst_geom_dst = DST.getInstance("application/x-NxsGeom",
                                        config.inst_geom)
    else:
        inst_geom_dst = None

    # Perform early background subtraction if the hwfix flag is used
    if config.hwfix:
        if not config.mc:
            so_axis = "time_of_flight"
        else:
            so_axis = "Time_of_Flight"
        
        bkg_som0 = dr_lib.add_files(config.back,
                                    Data_Paths=config.data_paths.toPath(),
                                    SO_Axis=so_axis,
                                    Signal_ROI=config.roi_file,
                                    dataset_type="background",
                                    Verbose=config.verbose, Timer=tim)

        bkg_som = dr_lib.fix_bin_contents(bkg_som0)
        del bkg_som0
    else:
        bkg_som = None

    # Perform Steps 1-15 on sample data
    d_som1 = dr_lib.process_igs_data(config.data, config, timer=tim,
                                     inst_geom_dst=inst_geom_dst,
                                     tib_const=config.tib_data_const,
                                     bkg_som=bkg_som)

    # Perform Steps 1-15 on empty can data
    if config.ecan is not None:
        e_som1 = dr_lib.process_igs_data(config.ecan, config, timer=tim,
                                         inst_geom_dst=inst_geom_dst,
                                         dataset_type="empty_can",
                                         tib_const=config.tib_ecan_const,
                                         bkg_som=bkg_som)
    else:
        e_som1 = None

    # Perform Steps 1-15 on normalization data            
    if config.norm is not None:
        n_som1 = dr_lib.process_igs_data(config.norm, config, timer=tim,
                                         inst_geom_dst=inst_geom_dst,
                                         dataset_type="normalization",
                                         tib_const=config.tib_norm_const,
                                         bkg_som=bkg_som)
    else:
        n_som1 = None

    # Perform Steps 1-15 on background data
    if config.back is not None:
        b_som1 = dr_lib.process_igs_data(config.back, config, timer=tim,
                                         inst_geom_dst=inst_geom_dst,
                                         dataset_type="background",
                                         tib_const=config.tib_back_const,
                                         bkg_som=bkg_som)
    else:
        b_som1 = None

    # Perform Step 1-15 on direct scattering background data
    if config.dsback is not None:
        ds_som1 = dr_lib.process_igs_data(config.dsback, config, timer=tim,
                                          inst_geom_dst=inst_geom_dst,
                                          tib_const=config.tib_dsback_const,
                                          dataset_type="dsbackground",
                                          bkg_som=bkg_som)

        # Note: time_zero_slope MUST be a tuple
        if config.time_zero_slope is not None:
            ds_som1.attr_list["Time_zero_slope"] = \
                                      config.time_zero_slope.toValErrTuple()

        # Note: time_zero_offset MUST be a tuple
        if config.time_zero_offset is not None:
            ds_som1.attr_list["Time_zero_offset"] = \
                                      config.time_zero_offset.toValErrTuple()
        
        # Step 16: Linearly interpolate TOF elastic range in direct scattering
        #          background data

        # First convert TOF elastic range to appropriate pixel initial
        # wavelengths
        if config.verbose:
            print "Determining initial wavelength range for elastic line"

        if tim is not None:
            tim.getTime(False)
        
        if config.tof_elastic is None:
            # Units are in microseconds
            tof_elastic_range = (140300, 141300)
        else:
            tof_elastic_range = config.tof_elastic
        
        ctof_elastic_low = dr_lib.convert_single_to_list(\
               "tof_to_initial_wavelength_igs_lin_time_zero",
               (tof_elastic_range[0], 0.0),
               ds_som1)
        
        ctof_elastic_high = dr_lib.convert_single_to_list(\
               "tof_to_initial_wavelength_igs_lin_time_zero",
               (tof_elastic_range[1], 0.0),
               ds_som1)
        
        ctof_elastic_range = [(ctof_elastic_low[i][0], ctof_elastic_high[i][0])
                              for i in xrange(len(ctof_elastic_low))]

        if tim is not None:
            tim.getTime(msg="After calculating initial wavelength range for "\
                        +"elastic line ")

        del ctof_elastic_low, ctof_elastic_high

        if config.split:
            lambda_filter = [(d_som1[i].axis[0].val[0],
                              d_som1[i].axis[0].val[-1])
                             for i in xrange(len(d_som1))]
        else:
            lambda_filter = None

        # Now interpolate spectra between TOF elastic range (converted to
        # initial wavelength)
        if config.verbose:
            print "Linearly interpolating direct scattering spectra"

        if tim is not None:
            tim.getTime(False)
            
        ds_som2 = dr_lib.lin_interpolate_spectra(ds_som1, ctof_elastic_range,
                                                 filter_axis=lambda_filter)

        if tim is not None:
            tim.getTime(msg="After linearly interpolating direct scattering "\
                        +"spectra ")

        if config.dump_dslin:
            ds_som2_1 = dr_lib.sum_all_spectra(ds_som2,\
                                  rebin_axis=config.lambda_bins.toNessiList())

            hlr_utils.write_file(config.output, "text/Spec", ds_som2_1,
                                 output_ext="lin",
                                 data_ext=config.ext_replacement,    
                                 path_replacement=config.path_replacement,
                                 verbose=config.verbose,
                                 message="dsbackground linear interpolation")
            del ds_som2_1
        
        del ds_som1
    else:
        ds_som2 = None

    if inst_geom_dst is not None:
        inst_geom_dst.release_resource()

    # Steps 17-18: Subtract background spectrum from sample spectrum
    if config.dsback is None:
        back_som = b_som1
        bkg_type = "background"
    else:
        back_som = ds_som2
        bkg_type = "dsbackground"
    d_som2 = dr_lib.subtract_bkg_from_data(d_som1, back_som,
                                           verbose=config.verbose,
                                           timer=tim,
                                           dataset1="data",
                                           dataset2=bkg_type,
                                           scale=config.scale_bs)

    if config.dsback is not None:
        del ds_som2 

    # Step 19: Zero region outside TOF elastic for background for empty can
    if config.dsback is None:
        bcs_som = b_som1
        cs_som = e_som1
    else:
        if config.verbose and b_som1 is not None:
            print "Zeroing background spectra"

        if tim is not None and b_som1 is not None:
            tim.getTime(False)
            
        bcs_som = dr_lib.zero_spectra(b_som1, ctof_elastic_range)

        if tim is not None and b_som1 is not None:
            tim.getTime(msg="After zeroing background spectra")


        if config.verbose and e_som1 is not None:
            print "Zeroing empty can spectra"

        if tim is not None and e_som1 is not None:
            tim.getTime(False)
            
        cs_som = dr_lib.zero_spectra(e_som1, ctof_elastic_range)

        if tim is not None and e_som1 is not None:
            tim.getTime(msg="After zeroing empty can spectra")
            
        del ctof_elastic_range

    # Steps 20-21: Subtract background spectrum from empty can spectrum    
    e_som2 = dr_lib.subtract_bkg_from_data(cs_som, bcs_som,
                                           verbose=config.verbose,
                                           timer=tim,
                                           dataset1="data-empty_can",
                                           dataset2="background",
                                           scale=config.scale_bcs)

    # Steps 22-23: Subtract background spectrum from empty can spectrum for
    #              normalization

    try:
        config.pre_norm
    except AttributeError:
        config.pre_norm = False

    if not config.pre_norm:
        e_som3 = dr_lib.subtract_bkg_from_data(e_som1, b_som1,
                                               verbose=config.verbose,
                                               timer=tim,
                                               dataset1="norm-empty_can",
                                               dataset2="background",
                                               scale=config.scale_bcn)
    else:
        e_som3 = None

    # Steps 24-25: Subtract background spectrum from normalization spectrum
    if not config.pre_norm:
        n_som2 = dr_lib.subtract_bkg_from_data(n_som1, b_som1,
                                               verbose=config.verbose,
                                               timer=tim,
                                               dataset1="normalization",
                                               dataset2="background",
                                               scale=config.scale_bn)
    else:
        n_som2 = n_som1

    del b_som1, e_som1, bcs_som, cs_som

    # Steps 26-27: Subtract empty can spectrum from sample spectrum    
    d_som3 = dr_lib.subtract_bkg_from_data(d_som2, e_som2,
                                           verbose=config.verbose,
                                           timer=tim,
                                           dataset1="data",
                                           dataset2="empty_can",
                                           scale=config.scale_cs)

    del d_som2, e_som2
    
    # Steps 28-29: Subtract empty can spectrum from normalization spectrum
    if not config.pre_norm:
        n_som3 = dr_lib.subtract_bkg_from_data(n_som2, e_som3,
                                               verbose=config.verbose,
                                               timer=tim,
                                               dataset1="normalization",
                                               dataset2="empty_can",
                                               scale=config.scale_cn)
    else:
        n_som3 = n_som2

    del n_som2, e_som3

    # Step 30-31: Integrate normalization spectra
    if config.verbose and n_som3 is not None and not config.pre_norm:
        print "Integrating normalization spectra"

    if not config.pre_norm:
        norm_int = dr_lib.integrate_spectra(n_som3, start=config.norm_start,
                                            end=config.norm_end, norm=True)
    else:
        norm_int = n_som3

    del n_som3
        
    # Step 32: Normalize data by integrated values
    if config.verbose and norm_int is not None:
        print "Normalizing data by normalization data"

    if norm_int is not None:
        d_som4 = common_lib.div_ncerr(d_som3, norm_int)
    else:
        d_som4 = d_som3

    if norm_int is not None:
        if tim is not None:
            tim.getTime(msg="After normalizing data ")

    del d_som3, norm_int

    if config.dump_norm:
        if tim is not None:
            tim.getTime(False)

        hlr_utils.write_file(config.output, "text/Spec", d_som4,
                             output_ext="wvn",
                             data_ext=config.ext_replacement,    
                             path_replacement=config.path_replacement,
                             verbose=config.verbose,
                             message="wavelength (vanadium norm) information")

        if tim is not None:
            tim.getTime(msg="After writing wavelength (vanadium norm) info ")

    # Steps 33 to end: Creating S(Q,E)
    if config.Q_bins is not None:
        if config.verbose:
            print "Creating 2D spectrum"

        if tim is not None:
            tim.getTime(False)

        d_som5 = dr_lib.create_E_vs_Q_igs(d_som4,
                                          config.E_bins.toNessiList(),
                                          config.Q_bins.toNessiList(),
                                          so_id="Full Detector",
                                          y_label="counts",
                                          y_units="counts / (ueV * A^-1)",
                                          x_labels=["Q transfer",
                                                    "energy transfer"],
                                          x_units=["1/Angstroms","ueV"],
                                          split=config.split,
                                          Q_filter=False,
                                          configure=config)
        if tim is not None:
            tim.getTime(msg="After creation of final spectrum ")

        del d_som4
        
    # Steps 33 to 36: Create S(-cos(polar), E)
    elif config.ncospol_bins is not None:
        if config.verbose:
            print "Convert wavelength to energy transfer"

        if tim is not None:
            tim.getTime(False)

        d_som4a = dr_lib.energy_transfer(d_som4, "IGS", "Wavelength_final",
                                         sa_norm=True, scale=True,
                                         change_units=True)

        if tim is not None:
            tim.getTime(msg="After wavelength to energy transfer conversion ")

        del d_som4

        if config.verbose:
            print "Creating 2D spectrum"

        if tim is not None:
            tim.getTime(False)

        d_som5 = dr_lib.create_param_vs_Y(d_som4a, "polar",
                                        "negcos_param_array",
                                        config.ncospol_bins.toNessiList(),
                                        rebin_axis=config.E_bins.toNessiList(),
                                        y_label="counts",
                                        y_units="counts / ueV",
                                        x_labels=["-cos(polar)",
                                                  "Energy Transfer"], 
                                        x_units=["", "ueV"])

        if tim is not None:
            tim.getTime(msg="After creation of final spectrum ")        
    
    # If rescaling factor present, rescale the data
    if config.rescale_final is not None and not config.split:
        d_som6 = common_lib.mult_ncerr(d_som5, (config.rescale_final, 0.0))
    else:
        d_som6 = d_som5

    if tim is None:
        old_time = None

    if not __name__ == "amorphous_reduction_sqe":
        del d_som5
        __write_output(d_som6, config, tim, old_time)
    else:
        if config.create_output:
            del d_som5
            __write_output(d_som6, config, tim, old_time)
        else:
            return d_som6
Exemplo n.º 5
0
def calibrate_dgs_data(datalist, conf, dkcur, **kwargs):
    """
    This function combines Steps 3 through 6 in Section 2.1.1 of the data
    reduction process for Direct Geometry Spectrometers as specified by the
    document at 
    U{http://neutrons.ornl.gov/asg/projects/SCL/reqspec/DR_Lib_RS.doc}. The
    function takes a list of file names, a L{hlr_utils.Configure} object and
    processes the data accordingly.
    
    @param datalist: A list containing the filenames of the data to be
                     processed.
    @type datalist: C{list} of C{string}s
    
    @param conf: Object that contains the current setup of the driver.
    @type conf: L{hlr_utils.Configure}

    @param dkcur: The object containing the TOF dark current data.
    @type dkcur: C{SOM.SOM}
    
    @param kwargs: A list of keyword arguments that the function accepts:
    
    @keyword inst_geom_dst: File object that contains instrument geometry
                            information.
    @type inst_geom_dst: C{DST.GeomDST}

    @keyword tib_const: A time-independent background constant to subtract
                        from every pixel.
    @type tib_const: L{hlr_utils.DrParameter}
    
    @keyword dataset_type: The practical name of the dataset being processed.
                           The default value is I{data}.
    @type dataset_type: C{string}

    @keyword cwp: A list of chopper phase corrections in units of microseconds.
    @type cwp: C{list} of C{float}s
    
    @keyword timer: Timing object so the function can perform timing estimates.
    @type timer: C{sns_timer.DiffTime}


    @return: Object that has undergone all requested processing steps
    @rtype: C{SOM.SOM}
    """
    import common_lib
    import dr_lib
    import hlr_utils

    # Check keywords
    try:
        tib_const = kwargs["tib_const"]
    except KeyError:
        tib_const = None

    try:
        dataset_type = kwargs["dataset_type"]
    except KeyError:
        dataset_type = "data"

    try:
        t = kwargs["timer"]
    except KeyError:
        t = None

    try:
        i_geom_dst = kwargs["inst_geom_dst"]
    except KeyError:
        i_geom_dst = None

    dataset_cwp = kwargs.get("cwp")

    # Open the appropriate datafiles
    if conf.verbose:
        print "Reading %s file" % dataset_type

    data_paths = conf.data_paths.toPath()
    if conf.no_mon_norm:
        mon_paths = None
    else:
        mon_paths = conf.usmon_path.toPath()

    # Check for mask file since normalization drive doesn't understand option
    try:
        mask_file = conf.mask_file
    except AttributeError:
        mask_file = None

    if t is not None:
        oldtime = t.getOldTime()

    (dp_som0, dm_som0) = dr_lib.add_files_dm(datalist,
                                             Data_Paths=data_paths,
                                             Mon_Paths=mon_paths,
                                             SO_Axis=conf.so_axis,
                                             Signal_ROI=conf.roi_file,
                                             Signal_MASK=mask_file,
                                             dataset_type=dataset_type,
                                             dataset_cwp=dataset_cwp,
                                             Verbose=conf.verbose,
                                             Timer=t)

    if t is not None:
        t.setOldTime(oldtime)
        t.getTime(msg="After reading %s file" % dataset_type)

    # Cut the spectra if necessary
    dp_somA = dr_lib.cut_spectra(dp_som0, conf.tof_cut_min, conf.tof_cut_max)

    del dp_som0

    dp_somB = dr_lib.fix_bin_contents(dp_somA)

    del dp_somA

    if dp_somB.attr_list.instrument.get_name() != "CNCS":

        if conf.verbose:
            print "Cutting spectrum at minimum TOF"

        if t is not None:
            t.getTime(False)

        # Calculate minimum TOF for physical neutrons
        if conf.initial_energy is not None:
            initial_wavelength = common_lib.energy_to_wavelength(\
            conf.initial_energy.toValErrTuple())
            initial_velocity = common_lib.wavelength_to_velocity(\
            initial_wavelength)
        else:
            # This should actually calculate it, but don't have a way right now
            pass

        if conf.time_zero_offset is not None:
            time_zero_offset = conf.time_zero_offset.toValErrTuple()
        else:
            # This should actually calculate it, but don't have a way right now
            time_zero_offset = (0.0, 0.0)

        ss_length = dp_somB.attr_list.instrument.get_primary()

        tof_min = (ss_length[0] / initial_velocity[0]) + time_zero_offset[0]

        # Cut all spectra a the minimum TOF
        dp_som1 = dr_lib.cut_spectra(dp_somB, tof_min, None)

        if t is not None:
            t.getTime(msg="After cutting spectrum at minimum TOF ")
    else:
        dp_som1 = dp_somB

    del dp_somB

    if dm_som0 is not None:
        dm_som1 = dr_lib.fix_bin_contents(dm_som0)
    else:
        dm_som1 = dm_som0

    del dm_som0

    # Override geometry if necessary
    if conf.inst_geom is not None:
        i_geom_dst.setGeometry(data_paths, dp_som1)

    if conf.inst_geom is not None and dm_som1 is not None:
        i_geom_dst.setGeometry(mon_paths, dm_som1)

    # Step 3: Integrate the upstream monitor
    if dm_som1 is not None:
        if conf.verbose:
            print "Integrating upstream monitor spectrum"

        if t is not None:
            t.getTime(False)

        if conf.mon_int_range is None:
            start_val = float("inf")
            end_val = float("inf")
        else:
            start_val = conf.mon_int_range[0]
            end_val = conf.mon_int_range[1]

        dm_som2 = dr_lib.integrate_spectra(dm_som1,
                                           start=start_val,
                                           end=end_val,
                                           width=True)
        if t is not None:
            t.getTime(msg="After integrating upstream monitor spectrum ")
    else:
        dm_som2 = dm_som1

    del dm_som1

    tib_norm_const = None

    # Step 4: Divide data set by summed monitor spectrum
    if dm_som2 is not None:
        if conf.verbose:
            print "Normalizing %s by monitor sum" % dataset_type

        if t is not None:
            t.getTime(False)

        dp_som2 = common_lib.div_ncerr(dp_som1, dm_som2, length_one_som=True)

        tib_norm_const = dm_som2[0].y

        if t is not None:
            t.getTime(msg="After normalizing %s by monitor sum" % dataset_type)

    elif conf.pc_norm:
        if conf.verbose:
            print "Normalizing %s by proton charge" % dataset_type

        pc_tag = dataset_type + "-proton_charge"
        pc = dp_som1.attr_list[pc_tag]

        # Scale the proton charge and then set the scale PC back to attributes
        if conf.scale_pc is not None:
            if conf.verbose:
                print "Scaling %s proton charge" % dataset_type

            pc = hlr_utils.scale_proton_charge(pc, conf.scale_pc)
            dp_som1.attr_list[pc_tag] = pc

        tib_norm_const = pc.getValue()

        if t is not None:
            t.getTime(False)

        dp_som2 = common_lib.div_ncerr(dp_som1, (pc.getValue(), 0.0))

        if t is not None:
            t.getTime(msg="After normalizing %s by proton charge" \
                      % dataset_type)

    else:
        dp_som2 = dp_som1

    del dp_som1, dm_som2

    # Step 5: Scale dark current by data set measurement time
    if dkcur is not None:
        if conf.verbose:
            print "Scaling dark current by %s acquisition time" % dataset_type

        if t is not None:
            t.getTime(False)

        dstime_tag = dataset_type + "-duration"
        dstime = dp_som2.attr_list[dstime_tag]

        dkcur1 = common_lib.div_ncerr(dkcur, (dstime.getValue(), 0.0))

        if t is not None:
            t.getTime(msg="After scaling dark current by %s acquisition time" \
                      % dataset_type)
    else:
        dkcur1 = dkcur

    del dkcur

    # Step 6: Subtract scaled dark current from data set
    if dkcur1 is not None:
        if conf.verbose:
            print "Subtracting %s by scaled dark current" % dataset_type

        if t is not None:
            t.getTime(False)

        dp_som3 = common_lib.sub_ncerr(dp_som2, dkcur1)

        if t is not None:
            t.getTime(msg="After subtracting %s by scaled dark current" \
                      % dataset_type)
    elif tib_const is not None and dkcur1 is None:
        if conf.verbose:
            print "Subtracting TIB constant from %s" % dataset_type

        # Normalize the TIB constant by dividing by the current normalization
        # the duration (if necessary) and the conversion from seconds to
        # microseconds
        tib_c = tib_const.toValErrTuple()

        conv_sec_to_usec = 1.0e-6

        if tib_norm_const is None:
            tib_norm_const = 1
            duration = 1
        else:
            duration_tag = dataset_type + "-duration"
            duration = dp_som2.attr_list[duration_tag].getValue()

        norm_const = (duration * conv_sec_to_usec) / tib_norm_const

        tib_val = tib_c[0] * norm_const
        tib_err2 = tib_c[1] * (norm_const * norm_const)

        if t is not None:
            t.getTime(False)

        dp_som3 = common_lib.sub_ncerr(dp_som2, (tib_val, tib_err2))

        if t is not None:
            t.getTime(msg="After subtracting TIB constant from %s" \
                      % dataset_type)
    elif conf.tib_range is not None and dkcur1 is None:
        if conf.verbose:
            print "Determining TIB constant from %s" % dataset_type

        if t is not None:
            t.getTime(False)

        TIB = dr_lib.determine_time_indep_bkg(dp_som2,
                                              conf.tib_range,
                                              is_range=True)

        if t is not None:
            t.getTime(msg="After determining TIB constant from %s" \
                      % dataset_type)

        if conf.dump_tib:
            file_comment = "TIB TOF Range: [%d, %d]" % (conf.tib_range[0],
                                                        conf.tib_range[1])

            hlr_utils.write_file(conf.output, "text/num-info", TIB,
                                 output_ext="tib",
                                 extra_tag=dataset_type,
                                 verbose=conf.verbose,
                                 data_ext=conf.ext_replacement,
                                 path_replacement=conf.path_replacement,
                                 message="time-independent background "\
                                 +"information",
                                 tag="Average TIB",
                                 units="counts/usec",
                                 comments=[file_comment])

        if conf.verbose:
            print "Subtracting TIB constant from %s" % dataset_type

        if t is not None:
            t.getTime(False)

        dp_som3 = common_lib.sub_ncerr(dp_som2, TIB)

        if t is not None:
            t.getTime(msg="After subtracting TIB constant from %s" \
                      % dataset_type)

        del TIB
    else:
        dp_som3 = dp_som2

    del dp_som2, dkcur1

    if conf.dump_ctof_comb:
        dp_som3_1 = dr_lib.sum_all_spectra(dp_som3)
        hlr_utils.write_file(conf.output,
                             "text/Spec",
                             dp_som3_1,
                             output_ext="ctof",
                             extra_tag=dataset_type,
                             data_ext=conf.ext_replacement,
                             path_replacement=conf.path_replacement,
                             verbose=conf.verbose,
                             message="combined calibrated TOF information")

        del dp_som3_1

    return dp_som3
Exemplo n.º 6
0
def run(config, tim=None):
    """
    This method is where the data reduction process gets done.

    @param config: Object containing the data reduction configuration
                   information.
    @type config: L{hlr_utils.Configure}

    @param tim: (OPTIONAL) Object that will allow the method to perform
                           timing evaluations.
    @type tim: C{sns_time.DiffTime}
    """
    import common_lib
    import dr_lib
    import DST

    if tim is not None:
        tim.getTime(False)
        old_time = tim.getOldTime()

    if config.data is None:
        raise RuntimeError("Need to pass a data filename to the driver "\
                           +"script.")

    # Read in geometry if one is provided
    if config.inst_geom is not None:
        if config.verbose:
            print "Reading in instrument geometry file"

        inst_geom_dst = DST.getInstance("application/x-NxsGeom",
                                        config.inst_geom)
    else:
        inst_geom_dst = None

    # Perform early background subtraction if the hwfix flag is used
    if config.hwfix:
        if not config.mc:
            so_axis = "time_of_flight"
        else:
            so_axis = "Time_of_Flight"

        bkg_som0 = dr_lib.add_files(config.back,
                                    Data_Paths=config.data_paths.toPath(),
                                    SO_Axis=so_axis,
                                    Signal_ROI=config.roi_file,
                                    dataset_type="background",
                                    Verbose=config.verbose,
                                    Timer=tim)

        bkg_som = dr_lib.fix_bin_contents(bkg_som0)
        del bkg_som0
    else:
        bkg_som = None

    # Perform Steps 1-15 on sample data
    d_som1 = dr_lib.process_igs_data(config.data,
                                     config,
                                     timer=tim,
                                     inst_geom_dst=inst_geom_dst,
                                     tib_const=config.tib_data_const,
                                     bkg_som=bkg_som)

    # Perform Steps 1-15 on empty can data
    if config.ecan is not None:
        e_som1 = dr_lib.process_igs_data(config.ecan,
                                         config,
                                         timer=tim,
                                         inst_geom_dst=inst_geom_dst,
                                         dataset_type="empty_can",
                                         tib_const=config.tib_ecan_const,
                                         bkg_som=bkg_som)
    else:
        e_som1 = None

    # Perform Steps 1-15 on normalization data
    if config.norm is not None:
        n_som1 = dr_lib.process_igs_data(config.norm,
                                         config,
                                         timer=tim,
                                         inst_geom_dst=inst_geom_dst,
                                         dataset_type="normalization",
                                         tib_const=config.tib_norm_const,
                                         bkg_som=bkg_som)
    else:
        n_som1 = None

    # Perform Steps 1-15 on background data
    if config.back is not None:
        b_som1 = dr_lib.process_igs_data(config.back,
                                         config,
                                         timer=tim,
                                         inst_geom_dst=inst_geom_dst,
                                         dataset_type="background",
                                         tib_const=config.tib_back_const,
                                         bkg_som=bkg_som)
    else:
        b_som1 = None

    # Perform Step 1-15 on direct scattering background data
    if config.dsback is not None:
        ds_som1 = dr_lib.process_igs_data(config.dsback,
                                          config,
                                          timer=tim,
                                          inst_geom_dst=inst_geom_dst,
                                          tib_const=config.tib_dsback_const,
                                          dataset_type="dsbackground",
                                          bkg_som=bkg_som)

        # Note: time_zero_slope MUST be a tuple
        if config.time_zero_slope is not None:
            ds_som1.attr_list["Time_zero_slope"] = \
                                      config.time_zero_slope.toValErrTuple()

        # Note: time_zero_offset MUST be a tuple
        if config.time_zero_offset is not None:
            ds_som1.attr_list["Time_zero_offset"] = \
                                      config.time_zero_offset.toValErrTuple()

        # Step 16: Linearly interpolate TOF elastic range in direct scattering
        #          background data

        # First convert TOF elastic range to appropriate pixel initial
        # wavelengths
        if config.verbose:
            print "Determining initial wavelength range for elastic line"

        if tim is not None:
            tim.getTime(False)

        if config.tof_elastic is None:
            # Units are in microseconds
            tof_elastic_range = (140300, 141300)
        else:
            tof_elastic_range = config.tof_elastic

        ctof_elastic_low = dr_lib.convert_single_to_list(\
               "tof_to_initial_wavelength_igs_lin_time_zero",
               (tof_elastic_range[0], 0.0),
               ds_som1)

        ctof_elastic_high = dr_lib.convert_single_to_list(\
               "tof_to_initial_wavelength_igs_lin_time_zero",
               (tof_elastic_range[1], 0.0),
               ds_som1)

        ctof_elastic_range = [(ctof_elastic_low[i][0], ctof_elastic_high[i][0])
                              for i in xrange(len(ctof_elastic_low))]

        if tim is not None:
            tim.getTime(msg="After calculating initial wavelength range for "\
                        +"elastic line ")

        del ctof_elastic_low, ctof_elastic_high

        if config.split:
            lambda_filter = [(d_som1[i].axis[0].val[0],
                              d_som1[i].axis[0].val[-1])
                             for i in xrange(len(d_som1))]
        else:
            lambda_filter = None

        # Now interpolate spectra between TOF elastic range (converted to
        # initial wavelength)
        if config.verbose:
            print "Linearly interpolating direct scattering spectra"

        if tim is not None:
            tim.getTime(False)

        ds_som2 = dr_lib.lin_interpolate_spectra(ds_som1,
                                                 ctof_elastic_range,
                                                 filter_axis=lambda_filter)

        if tim is not None:
            tim.getTime(msg="After linearly interpolating direct scattering "\
                        +"spectra ")

        if config.dump_dslin:
            ds_som2_1 = dr_lib.sum_all_spectra(ds_som2,\
                                  rebin_axis=config.lambda_bins.toNessiList())

            hlr_utils.write_file(config.output,
                                 "text/Spec",
                                 ds_som2_1,
                                 output_ext="lin",
                                 data_ext=config.ext_replacement,
                                 path_replacement=config.path_replacement,
                                 verbose=config.verbose,
                                 message="dsbackground linear interpolation")
            del ds_som2_1

        del ds_som1
    else:
        ds_som2 = None

    if inst_geom_dst is not None:
        inst_geom_dst.release_resource()

    # Steps 17-18: Subtract background spectrum from sample spectrum
    if config.dsback is None:
        back_som = b_som1
        bkg_type = "background"
    else:
        back_som = ds_som2
        bkg_type = "dsbackground"
    d_som2 = dr_lib.subtract_bkg_from_data(d_som1,
                                           back_som,
                                           verbose=config.verbose,
                                           timer=tim,
                                           dataset1="data",
                                           dataset2=bkg_type,
                                           scale=config.scale_bs)

    if config.dsback is not None:
        del ds_som2

    # Step 19: Zero region outside TOF elastic for background for empty can
    if config.dsback is None:
        bcs_som = b_som1
        cs_som = e_som1
    else:
        if config.verbose and b_som1 is not None:
            print "Zeroing background spectra"

        if tim is not None and b_som1 is not None:
            tim.getTime(False)

        bcs_som = dr_lib.zero_spectra(b_som1, ctof_elastic_range)

        if tim is not None and b_som1 is not None:
            tim.getTime(msg="After zeroing background spectra")

        if config.verbose and e_som1 is not None:
            print "Zeroing empty can spectra"

        if tim is not None and e_som1 is not None:
            tim.getTime(False)

        cs_som = dr_lib.zero_spectra(e_som1, ctof_elastic_range)

        if tim is not None and e_som1 is not None:
            tim.getTime(msg="After zeroing empty can spectra")

        del ctof_elastic_range

    # Steps 20-21: Subtract background spectrum from empty can spectrum
    e_som2 = dr_lib.subtract_bkg_from_data(cs_som,
                                           bcs_som,
                                           verbose=config.verbose,
                                           timer=tim,
                                           dataset1="data-empty_can",
                                           dataset2="background",
                                           scale=config.scale_bcs)

    # Steps 22-23: Subtract background spectrum from empty can spectrum for
    #              normalization

    try:
        config.pre_norm
    except AttributeError:
        config.pre_norm = False

    if not config.pre_norm:
        e_som3 = dr_lib.subtract_bkg_from_data(e_som1,
                                               b_som1,
                                               verbose=config.verbose,
                                               timer=tim,
                                               dataset1="norm-empty_can",
                                               dataset2="background",
                                               scale=config.scale_bcn)
    else:
        e_som3 = None

    # Steps 24-25: Subtract background spectrum from normalization spectrum
    if not config.pre_norm:
        n_som2 = dr_lib.subtract_bkg_from_data(n_som1,
                                               b_som1,
                                               verbose=config.verbose,
                                               timer=tim,
                                               dataset1="normalization",
                                               dataset2="background",
                                               scale=config.scale_bn)
    else:
        n_som2 = n_som1

    del b_som1, e_som1, bcs_som, cs_som

    # Steps 26-27: Subtract empty can spectrum from sample spectrum
    d_som3 = dr_lib.subtract_bkg_from_data(d_som2,
                                           e_som2,
                                           verbose=config.verbose,
                                           timer=tim,
                                           dataset1="data",
                                           dataset2="empty_can",
                                           scale=config.scale_cs)

    del d_som2, e_som2

    # Steps 28-29: Subtract empty can spectrum from normalization spectrum
    if not config.pre_norm:
        n_som3 = dr_lib.subtract_bkg_from_data(n_som2,
                                               e_som3,
                                               verbose=config.verbose,
                                               timer=tim,
                                               dataset1="normalization",
                                               dataset2="empty_can",
                                               scale=config.scale_cn)
    else:
        n_som3 = n_som2

    del n_som2, e_som3

    # Step 30-31: Integrate normalization spectra
    if config.verbose and n_som3 is not None and not config.pre_norm:
        print "Integrating normalization spectra"

    if not config.pre_norm:
        norm_int = dr_lib.integrate_spectra(n_som3,
                                            start=config.norm_start,
                                            end=config.norm_end,
                                            norm=True)
    else:
        norm_int = n_som3

    del n_som3

    # Step 32: Normalize data by integrated values
    if config.verbose and norm_int is not None:
        print "Normalizing data by normalization data"

    if norm_int is not None:
        d_som4 = common_lib.div_ncerr(d_som3, norm_int)
    else:
        d_som4 = d_som3

    if norm_int is not None:
        if tim is not None:
            tim.getTime(msg="After normalizing data ")

    del d_som3, norm_int

    if config.dump_norm:
        if tim is not None:
            tim.getTime(False)

        hlr_utils.write_file(config.output,
                             "text/Spec",
                             d_som4,
                             output_ext="wvn",
                             data_ext=config.ext_replacement,
                             path_replacement=config.path_replacement,
                             verbose=config.verbose,
                             message="wavelength (vanadium norm) information")

        if tim is not None:
            tim.getTime(msg="After writing wavelength (vanadium norm) info ")

    # Steps 33 to end: Creating S(Q,E)
    if config.Q_bins is not None:
        if config.verbose:
            print "Creating 2D spectrum"

        if tim is not None:
            tim.getTime(False)

        d_som5 = dr_lib.create_E_vs_Q_igs(
            d_som4,
            config.E_bins.toNessiList(),
            config.Q_bins.toNessiList(),
            so_id="Full Detector",
            y_label="counts",
            y_units="counts / (ueV * A^-1)",
            x_labels=["Q transfer", "energy transfer"],
            x_units=["1/Angstroms", "ueV"],
            split=config.split,
            Q_filter=False,
            configure=config)
        if tim is not None:
            tim.getTime(msg="After creation of final spectrum ")

        del d_som4

    # Steps 33 to 36: Create S(-cos(polar), E)
    elif config.ncospol_bins is not None:
        if config.verbose:
            print "Convert wavelength to energy transfer"

        if tim is not None:
            tim.getTime(False)

        d_som4a = dr_lib.energy_transfer(d_som4,
                                         "IGS",
                                         "Wavelength_final",
                                         sa_norm=True,
                                         scale=True,
                                         change_units=True)

        if tim is not None:
            tim.getTime(msg="After wavelength to energy transfer conversion ")

        del d_som4

        if config.verbose:
            print "Creating 2D spectrum"

        if tim is not None:
            tim.getTime(False)

        d_som5 = dr_lib.create_param_vs_Y(
            d_som4a,
            "polar",
            "negcos_param_array",
            config.ncospol_bins.toNessiList(),
            rebin_axis=config.E_bins.toNessiList(),
            y_label="counts",
            y_units="counts / ueV",
            x_labels=["-cos(polar)", "Energy Transfer"],
            x_units=["", "ueV"])

        if tim is not None:
            tim.getTime(msg="After creation of final spectrum ")

    # If rescaling factor present, rescale the data
    if config.rescale_final is not None and not config.split:
        d_som6 = common_lib.mult_ncerr(d_som5, (config.rescale_final, 0.0))
    else:
        d_som6 = d_som5

    if tim is None:
        old_time = None

    if not __name__ == "amorphous_reduction_sqe":
        del d_som5
        __write_output(d_som6, config, tim, old_time)
    else:
        if config.create_output:
            del d_som5
            __write_output(d_som6, config, tim, old_time)
        else:
            return d_som6
Exemplo n.º 7
0
def scaled_summed_data(datalist, conf, **kwargs):
    """
    This function takes a list of TOF datafiles, creates the dataset
    representation, integrates each pixel spectrum and then scales those
    integrations with the acquisition time.

    @param datalist: A list containing the filenames of the data to be
                     processed.
    @type datalist: C{list} of C{string}s
    
    @param conf: Object that contains the current setup of the driver.
    @type conf: L{hlr_utils.Configure}

    @param kwargs: A list of keyword arguments that the function accepts:

    @keyword dataset_type: The practical name of the dataset being processed.
                           The default value is I{data}.
    @type dataset_type: C{string}

    @keyword timer: Timing object so the function can perform timing estimates.
    @type timer: C{sns_timer.DiffTime}

    
    @return: Object that has undergone all requested processing steps
    @rtype: C{SOM.SOM}
    """
    # Kick-out is no data list is present
    if datalist is None:
        return None

    import common_lib
    import dr_lib

    # Check keywords
    try:
        dataset_type = kwargs["dataset_type"]
    except KeyError:
        dataset_type = "data"
    
    try:
        t = kwargs["timer"]
    except KeyError:
        t = None

    # Open the appropriate datafiles
    if conf.verbose:
        print "Reading %s file" % dataset_type

    dst_type = "application/x-NeXus"
    data_paths = conf.data_paths.toPath()

    dp_som0 = dr_lib.add_files(datalist, Data_Paths=data_paths,
                               SO_Axis=conf.so_axis, Signal_ROI=conf.roi_file,
                               Signal_MASK=conf.mask_file,
                               dataset_type=dataset_type,
                               dst_type=dst_type,
                               Verbose=conf.verbose, Timer=t)

    if t is not None:
        t.getTime(msg="After reading %s " % dataset_type)

    dp_som1 = dr_lib.fix_bin_contents(dp_som0)

    del dp_som0    

    if conf.verbose:
        print "Integrating %s data" % dataset_type
        
    if t is not None:
        t.getTime(False)

    dp_som2 = dr_lib.integrate_spectra(dp_som1, width=True)

    if t is not None:
        t.getTime(msg="After integrating %s data " % dataset_type)

    del dp_som1

    # Make dataset duration tag
    duration_tag = dataset_type+"-duration"
    duration = dp_som2.attr_list[duration_tag]

    if conf.verbose:
        print "Scaling %s integration by acquisition duration " % dataset_type

    if t is not None:
        t.getTime(False)
 
    dp_som3 = common_lib.div_ncerr(dp_som2, (duration.getValue(), 0.0))

    if t is not None:
        t.getTime("After scaling %s integration by acquisition duration " \
                  % dataset_type)

    del dp_som2

    return dp_som3
Exemplo n.º 8
0
def run(config, tim=None):
    """
    This method is where the data reduction process gets done.

    @param config: Object containing the data reduction configuration
                   information.
    @type config: L{hlr_utils.Configure}

    @param tim: (OPTIONAL) Object that will allow the method to perform
                           timing evaluations.
    @type tim: C{sns_time.DiffTime}
    """
    import common_lib
    import dr_lib
    import DST

    if tim is not None:
        tim.getTime(False)
        old_time = tim.getOldTime()

    if config.data is None:
        raise RuntimeError("Need to pass a data filename to the driver " + "script.")

    # Read in geometry if one is provided
    if config.inst_geom is not None:
        if config.verbose:
            print "Reading in instrument geometry file"

        inst_geom_dst = DST.getInstance("application/x-NxsGeom", config.inst_geom)
    else:
        inst_geom_dst = None

    config.so_axis = "time_of_flight"

    # Steps 1-3: Produce a scaled summed dark current dataset
    dc_som = dr_lib.scaled_summed_data(config.dkcur, config, dataset_type="dark_current", timer=tim)

    # Perform Steps 3-6 on black can data
    if config.bcan is not None:
        b_som1 = dr_lib.calibrate_dgs_data(
            config.bcan,
            config,
            dc_som,
            dataset_type="black_can",
            inst_geom_dst=inst_geom_dst,
            tib_const=config.tib_const,
            cwp=config.cwp_bcan,
            timer=tim,
        )
    else:
        b_som1 = None

    # Perform Steps 3-6 on empty can data
    if config.ecan is not None:
        e_som1 = dr_lib.calibrate_dgs_data(
            config.ecan,
            config,
            dc_som,
            dataset_type="empty_can",
            inst_geom_dst=inst_geom_dst,
            tib_const=config.tib_const,
            cwp=config.cwp_ecan,
            timer=tim,
        )
    else:
        e_som1 = None

    # Perform Steps 3-6 on normalization data
    n_som1 = dr_lib.calibrate_dgs_data(
        config.data,
        config,
        dc_som,
        dataset_type="normalization",
        inst_geom_dst=inst_geom_dst,
        tib_const=config.tib_const,
        cwp=config.cwp_data,
        timer=tim,
    )

    # Perform Steps 7-16 on normalization data
    if config.norm_trans_coeff is None:
        norm_trans_coeff = None
    else:
        norm_trans_coeff = config.norm_trans_coeff.toValErrTuple()

    # Determine if we need to rebin the empty or black can data
    if config.ecan is not None and e_som1 is not None:
        ecan_cwp = True
    else:
        ecan_cwp = False

    if config.bcan is not None and b_som1 is not None:
        bcan_cwp = True
    else:
        bcan_cwp = False

    cwp_used = ecan_cwp or bcan_cwp

    n_som2 = dr_lib.process_dgs_data(
        n_som1, config, b_som1, e_som1, norm_trans_coeff, dataset_type="normalization", cwp_used=cwp_used, timer=tim
    )

    del n_som1, b_som1, e_som1

    # Step 17: Integrate normalization spectra
    if config.verbose:
        print "Integrating normalization spectra"

    if tim is not None:
        tim.getTime(False)

    if config.norm_int_range is None:
        start_val = float("inf")
        end_val = float("inf")
    else:
        if not config.wb_norm:
            # Translate energy transfer to final energy
            ef_start = config.initial_energy.getValue() - config.norm_int_range[0]
            ef_end = config.initial_energy.getValue() - config.norm_int_range[1]
            # Convert final energy to final wavelength
            start_val = common_lib.energy_to_wavelength((ef_start, 0.0))[0]
            end_val = common_lib.energy_to_wavelength((ef_end, 0.0))[0]
        else:
            start_val = config.norm_int_range[0]
            end_val = config.norm_int_range[1]

    n_som3 = dr_lib.integrate_spectra(n_som2, start=start_val, end=end_val, width=True)

    del n_som2

    if tim is not None:
        tim.getTime(msg="After integrating normalization spectra ")

    file_comment = "Normalization Integration range: %0.3fA, %0.3fA" % (start_val, end_val)

    hlr_utils.write_file(
        config.output,
        "text/num-info",
        n_som3,
        output_ext="norm",
        data_ext=config.ext_replacement,
        path_replacement=config.path_replacement,
        verbose=config.verbose,
        message="normalization values",
        comments=[file_comment],
        tag="Integral",
        units="counts",
    )

    if tim is not None:
        tim.getTime(False)

    if config.verbose:
        print "Making mask file"

    # Make mask file from threshold
    dr_lib.filter_normalization(n_som3, config.lo_threshold, config.hi_threshold, config)

    if tim is not None:
        tim.getTime(msg="After making mask file ")

    # Write out RMD file
    n_som3.attr_list["config"] = config

    hlr_utils.write_file(
        config.output,
        "text/rmd",
        n_som3,
        output_ext="rmd",
        data_ext=config.ext_replacement,
        path_replacement=config.path_replacement,
        verbose=config.verbose,
        message="metadata",
    )

    if tim is not None:
        tim.setOldTime(old_time)
        tim.getTime(msg="Total Running Time")
Exemplo n.º 9
0
def scaled_summed_data(datalist, conf, **kwargs):
    """
    This function takes a list of TOF datafiles, creates the dataset
    representation, integrates each pixel spectrum and then scales those
    integrations with the acquisition time.

    @param datalist: A list containing the filenames of the data to be
                     processed.
    @type datalist: C{list} of C{string}s
    
    @param conf: Object that contains the current setup of the driver.
    @type conf: L{hlr_utils.Configure}

    @param kwargs: A list of keyword arguments that the function accepts:

    @keyword dataset_type: The practical name of the dataset being processed.
                           The default value is I{data}.
    @type dataset_type: C{string}

    @keyword timer: Timing object so the function can perform timing estimates.
    @type timer: C{sns_timer.DiffTime}

    
    @return: Object that has undergone all requested processing steps
    @rtype: C{SOM.SOM}
    """
    # Kick-out is no data list is present
    if datalist is None:
        return None

    import common_lib
    import dr_lib

    # Check keywords
    try:
        dataset_type = kwargs["dataset_type"]
    except KeyError:
        dataset_type = "data"

    try:
        t = kwargs["timer"]
    except KeyError:
        t = None

    # Open the appropriate datafiles
    if conf.verbose:
        print "Reading %s file" % dataset_type

    dst_type = "application/x-NeXus"
    data_paths = conf.data_paths.toPath()

    dp_som0 = dr_lib.add_files(datalist,
                               Data_Paths=data_paths,
                               SO_Axis=conf.so_axis,
                               Signal_ROI=conf.roi_file,
                               Signal_MASK=conf.mask_file,
                               dataset_type=dataset_type,
                               dst_type=dst_type,
                               Verbose=conf.verbose,
                               Timer=t)

    if t is not None:
        t.getTime(msg="After reading %s " % dataset_type)

    dp_som1 = dr_lib.fix_bin_contents(dp_som0)

    del dp_som0

    if conf.verbose:
        print "Integrating %s data" % dataset_type

    if t is not None:
        t.getTime(False)

    dp_som2 = dr_lib.integrate_spectra(dp_som1, width=True)

    if t is not None:
        t.getTime(msg="After integrating %s data " % dataset_type)

    del dp_som1

    # Make dataset duration tag
    duration_tag = dataset_type + "-duration"
    duration = dp_som2.attr_list[duration_tag]

    if conf.verbose:
        print "Scaling %s integration by acquisition duration " % dataset_type

    if t is not None:
        t.getTime(False)

    dp_som3 = common_lib.div_ncerr(dp_som2, (duration.getValue(), 0.0))

    if t is not None:
        t.getTime("After scaling %s integration by acquisition duration " \
                  % dataset_type)

    del dp_som2

    return dp_som3