def l5qc(cf, ds4): ds5 = qcio.copy_datastructure(cf, ds4) # ds4 will be empty (logical false) if an error occurs in copy_datastructure # return from this routine if this is the case if not ds5: return ds5 # set some attributes for this level qcutils.UpdateGlobalAttributes(cf, ds5, "L5") ds5.cf = cf # create a dictionary to hold the gap filling data ds_alt = {} # check to see if we have any imports qcgf.ImportSeries(cf, ds5) # re-apply the quality control checks (range, diurnal and rules) qcck.do_qcchecks(cf, ds5) # now do the flux gap filling methods label_list = qcutils.get_label_list_from_cf(cf) for label in label_list: # parse the control file for information on how the user wants to do the gap filling qcgf.GapFillParseControlFile(cf, ds5, label, ds_alt) # *** start of the section that does the gap filling of the fluxes *** # apply the turbulence filter (if requested) qcck.ApplyTurbulenceFilter(cf, ds5) # fill short gaps using interpolation qcgf.GapFillUsingInterpolation(cf, ds5) # do the gap filling using SOLO qcgfSOLO.GapFillUsingSOLO(cf, ds4, ds5) if ds5.returncodes["solo"] == "quit": return ds5 # gap fill using marginal distribution sampling qcgfMDS.GapFillFluxUsingMDS(cf, ds5) # gap fill using climatology qcgf.GapFillFromClimatology(ds5) # merge the gap filled drivers into a single series qcts.MergeSeriesUsingDict(ds5, merge_order="standard") # calculate Monin-Obukhov length qcts.CalculateMoninObukhovLength(ds5) # write the percentage of good data as a variable attribute qcutils.get_coverage_individual(ds5) # write the percentage of good data for groups qcutils.get_coverage_groups(ds5) return ds5
def l4qc(cf, ds3): # !!! code here to use existing L4 file # logic # if the L4 doesn't exist # - create ds4 by using copy.deepcopy(ds3) # if the L4 does exist and the "UseExistingL4File" option is False # - create ds4 by using copy.deepcopy(ds3) # if the L4 does exist and the "UseExistingL4File" option is True # - read the contents of the L4 netCDF file # - check the start and end dates of the L3 and L4 data # - if these are the same then tell the user there is nothing to do # - copy the L3 data to the L4 data structure # - replace the L3 data with the L4 data #ds4 = copy.deepcopy(ds3) ds4 = qcio.copy_datastructure(cf, ds3) # ds4 will be empty (logical false) if an error occurs in copy_datastructure # return from this routine if this is the case if not ds4: return ds4 # set some attributes for this level qcutils.UpdateGlobalAttributes(cf, ds4, "L4") ds4.cf = cf # calculate the available energy if "Fa" not in ds4.series.keys(): qcts.CalculateAvailableEnergy(ds4, Fa_out='Fa', Fn_in='Fn', Fg_in='Fg') # create a dictionary to hold the gap filling data ds_alt = {} # check to see if we have any imports qcgf.ImportSeries(cf, ds4) # re-apply the quality control checks (range, diurnal and rules) qcck.do_qcchecks(cf, ds4) # now do the meteorological driver gap filling for ThisOne in cf["Drivers"].keys(): if ThisOne not in ds4.series.keys(): log.error("Series " + ThisOne + " not in data structure") continue # parse the control file for information on how the user wants to do the gap filling qcgf.GapFillParseControlFile(cf, ds4, ThisOne, ds_alt) # *** start of the section that does the gap filling of the drivers *** # fill short gaps using interpolation qcgf.GapFillUsingInterpolation(cf, ds4) # gap fill using climatology qcgf.GapFillFromClimatology(ds4) # do the gap filling using the ACCESS output qcgf.GapFillFromAlternate(cf, ds4, ds_alt) if ds4.returncodes["alternate"] == "quit": return ds4 # gap fill using SOLO qcgf.GapFillUsingSOLO(cf, ds3, ds4) if ds4.returncodes["solo"] == "quit": return ds4 # merge the first group of gap filled drivers into a single series qcts.MergeSeriesUsingDict(ds4, merge_order="prerequisite") # re-calculate the ground heat flux but only if requested in control file opt = qcutils.get_keyvaluefromcf(cf, ["Options"], "CorrectFgForStorage", default="No", mode="quiet") if opt.lower() != "no": qcts.CorrectFgForStorage(cf, ds4, Fg_out='Fg', Fg_in='Fg_Av', Ts_in='Ts', Sws_in='Sws') # re-calculate the net radiation qcts.CalculateNetRadiation(cf, ds4, Fn_out='Fn', Fsd_in='Fsd', Fsu_in='Fsu', Fld_in='Fld', Flu_in='Flu') # re-calculate the available energy qcts.CalculateAvailableEnergy(ds4, Fa_out='Fa', Fn_in='Fn', Fg_in='Fg') # merge the second group of gap filled drivers into a single series qcts.MergeSeriesUsingDict(ds4, merge_order="standard") # re-calculate the water vapour concentrations qcts.CalculateHumiditiesAfterGapFill(ds4) # re-calculate the meteorological variables qcts.CalculateMeteorologicalVariables(ds4) # the Tumba rhumba qcts.CalculateComponentsFromWsWd(ds4) # check for any missing data qcutils.get_missingingapfilledseries(ds4) # write the percentage of good data as a variable attribute qcutils.get_coverage_individual(ds4) # write the percentage of good data for groups qcutils.get_coverage_groups(ds4) return ds4