コード例 #1
0
        protected Section ConstructReportSection(INCCTestDataSection section, MeasOptionSelector moskey, Detector det)
        {
            INCCTestDataStyle sec = null;

            try
            {
                switch (section)
                {
                case INCCTestDataSection.CyclesWithMultiplicityDistributions:
                    sec = new INCCTestDataStyle(null, 0, INCCStyleSection.ReportSection.MultiColumn);
                    //Singles 1st Scaler 2nd Scaler Reals + Accidentals Accidentals
                    int[] crdwidths = new int[] { 10, 10, 10, 10, 10 };
                    int[] srawidths = new int[] { 12, 12 };
                    foreach (Cycle cyc in meas.Cycles)
                    {
                        // if no results on the cycle, these map indexers throw
                        if (cyc.CountingAnalysisResults.GetResultsCount(typeof(Multiplicity)) > 0)                                // if no results on the cycle, these map indexers throw
                        {
                            MultiplicityCountingRes mcr = (MultiplicityCountingRes)cyc.CountingAnalysisResults[moskey.MultiplicityParams];
                            sec.AddColumnRow(
                                new ulong[] { (ulong)mcr.Totals, (ulong)mcr.Scaler1.v, (ulong)mcr.Scaler2.v, (ulong)mcr.RASum, (ulong)mcr.ASum },
                                crdwidths);
                            int minbin, maxbin;
                            minbin = Math.Min(mcr.RAMult.Length, mcr.NormedAMult.Length);
                            maxbin = Math.Max(mcr.RAMult.Length, mcr.NormedAMult.Length);
                            sec.AddOne(maxbin);
                            for (int i = 0; i < minbin; i++)
                            {
                                sec.AddColumnRow(new ulong[] { mcr.RAMult[i], mcr.NormedAMult[i] }, srawidths);
                            }
                            for (int i = minbin; i < maxbin; i++)      // check for uneven column
                            {
                                ulong[] potential = new ulong[2];
                                if (i < mcr.RAMult.Length)
                                {
                                    potential[0] = mcr.RAMult[i];
                                }
                                if (i < mcr.NormedAMult.Length)
                                {
                                    potential[1] = mcr.NormedAMult[i];
                                }
                                sec.AddColumnRow(potential, srawidths);
                            }
                        }
                    }
                    break;

                default:
                    break;
                }
            }
            catch (Exception e)
            {
                ctrllog.TraceException(e);
            }
            return(sec);
        }
コード例 #2
0
        public void GenerateReport(Measurement m)
        {
            if (N.App.Opstate.IsAbortRequested) // handle stop, cancel, abort here, for stop does it roll back all report gen from here?
            {
                return;
            }
            IEnumerator iter = m.INCCAnalysisResults.GetMeasSelectorResultsEnumerator();

            while (iter.MoveNext())
            {
                MeasOptionSelector moskey = (MeasOptionSelector)iter.Current;
                // create one results for each SR key
                StartReportGeneration(m, m.MeasOption.PrintName() + " INCC " +
                                      (m.INCCAnalysisResults.Count > 1 ? "[" + moskey.MultiplicityParams.ShortName() + "] " : ""), // add an identifying signature to each file name if more than one active virtual SR
                                      ' ', "dat");                                                                                 // make these text files with .dat suffix

                //Detector det = meas.Detectors.GetIt(moskey.SRParams);
                // now assuming only one detector on the list, so can use [0]
                Detector det = meas.Detectors[0];
                try
                {
                    sections.Add(ConstructReportSection(INCCTestDataSection.CycleSummary, det, moskey));

                    sections.Add(ConstructReportSection(INCCTestDataSection.CyclesWithMultiplicityDistributions, moskey, det));

                    sections.RemoveAll(s => (s == null));

                    // copy all section rows to the report row list (t.rows)
                    int rowcount = 0;
                    foreach (Section sec in sections)
                    {
                        rowcount += sec.Count;
                    }
                    Array.Resize(ref t.rows, rowcount);

                    int idx = 0;
                    foreach (Section sec in sections)
                    {
                        Array.Copy(sec.ToArray(), 0, t.rows, idx, sec.Count); idx += sec.Count;
                    }
                }
                catch (Exception e)
                {
                    ctrllog.TraceException(e);
                }

                FinishReportGeneration();
            }
        }
コード例 #3
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
 internal static unsafe iresultsbase MovePrecision(INCCResults ir, MeasOptionSelector mos)
 {
     results_precision_rec res = new results_precision_rec();
     INCCResult results;
     bool found = ir.TryGetValue(mos, out results);
     if (found)
     {
         INCCResults.results_precision_rec t = (INCCResults.results_precision_rec)results;
         StatePack(t.pass, res.prec_pass_fail);
         res.chi_sq_lower_limit = t.chiSqLowerLimit;
         res.chi_sq_upper_limit = t.chiSqUpperLimit;
         res.prec_chi_sq = t.precChiSq;
         res.prec_sample_var = t.precSampleVar;
         res.prec_theoretical_var = t.precTheoreticalVar;
     }
     return res;
 }
コード例 #4
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
 internal static unsafe iresultsbase MoveKnownM(INCCAnalysisState ias, MeasOptionSelector mos)
 {
     results_known_m_rec res = new results_known_m_rec();
     INCCMethodResult result;
     bool found = ias.Results.TryGetMethodResults(mos.MultiplicityParams, ias.Methods.selector, AnalysisMethod.KnownM, out result);
     if (found)
     {
         INCCMethodResults.results_known_m_rec m = (INCCMethodResults.results_known_m_rec)result;
         res.km_mult = m.mult;
         res.km_alpha = m.alpha;
         res.km_pu239e_mass = m.pu239e_mass;
         res.km_pu240e_mass = m.pu240e_mass.v;
         res.km_pu240e_mass_err = m.pu240e_mass.err;
         res.km_pu_mass = m.pu_mass.v;
         res.km_pu_mass_err = m.pu_mass.err;
         res.km_dcl_pu240e_mass = m.dcl_pu240e_mass;
         res.km_dcl_minus_asy_pu_mass = m.dcl_minus_asy_pu_mass.v;
         res.km_dcl_minus_asy_pu_mass_err = m.dcl_minus_asy_pu_mass.err;
         res.km_dcl_minus_asy_pu_mass_pct = m.dcl_minus_asy_pu_mass_pct;
         StatePack(m.pass, res.km_pass_fail);
         res.km_sf_rate_res = m.methodParams.sf_rate;
         res.km_vs1_res = m.methodParams.vs1;
         res.km_vs2_res = m.methodParams.vs2;
         res.km_vi1_res = m.methodParams.vi1;
         res.km_vi2_res = m.methodParams.vi2;
         res.km_b_res = m.methodParams.b;
         res.km_c_res = m.methodParams.c;
         res.km_sigma_x_res = m.methodParams.sigma_x;
         StrToBytes(INCC.MAX_DETECTOR_ID_LENGTH, ias.Methods.selector.detectorid, res.km_known_m_detector_id);
         StrToBytes(INCC.MAX_ITEM_TYPE_LENGTH, ias.Methods.selector.material, res.km_known_m_item_type);
     }
     return res;
 }
コード例 #5
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
 internal static unsafe iresultsbase MoveInitSrc(INCCResults ir, MeasOptionSelector mos)
 {
     results_init_src_rec res = new results_init_src_rec();
     INCCResult results;
     bool found = ir.TryGetValue(mos, out results);
     if (found)
     {
         INCCResults.results_init_src_rec t = (INCCResults.results_init_src_rec)results;
         res.init_src_mode = NewToOldBiasTestId(t.mode);
         StatePack(t.pass, res.init_src_pass_fail);
         StrToBytes(INCC.SOURCE_ID_LENGTH,t.init_src_id, res.init_src_id);
     }
     return res;
 }
コード例 #6
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
            internal static unsafe iresultsbase MoveCurium(INCCAnalysisState ias, MeasOptionSelector mos)
            {
                results_curium_ratio_rec res = new results_curium_ratio_rec();
                INCCMethodResult result;
                bool found = ias.Results.TryGetMethodResults(mos.MultiplicityParams, ias.Methods.selector, AnalysisMethod.CuriumRatio, out result);
                if (found)
                {
                    INCCMethodResults.results_curium_ratio_rec m = (INCCMethodResults.results_curium_ratio_rec)result;

                    res.cr_pu240e_mass = m.pu.pu240e_mass.v;
                    res.cr_pu240e_mass_err = m.pu.pu240e_mass.err;
                    res.cr_cm_mass = m.cm_mass.v;
                    res.cr_cm_mass_err = m.cm_mass.err;
                    res.cr_pu_mass = m.pu.mass.v;
                    res.cr_pu_mass_err = m.pu.mass.err;
                    res.cr_u_mass = m.u.mass.v;
                    res.cr_u_mass_err = m.u.mass.err;
                    res.cr_u235_mass = m.u235.mass.v;
                    res.cr_u235_mass_err = m.u235.mass.err;
                    res.cr_dcl_pu_mass = m.pu.dcl_mass;
                    res.cr_dcl_minus_asy_pu_mass = m.pu.dcl_minus_asy_mass.v;
                    res.cr_dcl_minus_asy_pu_mass_err = m.pu.dcl_minus_asy_mass.err;
                    res.cr_dcl_minus_asy_pu_mass_pct = m.pu.dcl_minus_asy_mass_pct;
                    res.cr_dcl_minus_asy_u_mass = m.u235.dcl_minus_asy_mass.v;
                    res.cr_dcl_minus_asy_u_mass_err = m.u235.dcl_minus_asy_mass.err;
                    res.cr_dcl_minus_asy_u_mass_pct = m.u235.dcl_minus_asy_mass_pct;
                    res.cr_dcl_minus_asy_u235_mass = m.u235.dcl_minus_asy_mass.v;
                    res.cr_dcl_minus_asy_u235_mass_err = m.u235.dcl_minus_asy_mass.err;
                    res.cr_dcl_minus_asy_u235_mass_pct = m.u235.dcl_minus_asy_mass_pct;
                    StatePack(m.pu.pass, res.cr_pu_pass_fail);
                    StatePack(m.u.pass, res.cr_u_pass_fail);

                    res.cr_cm_pu_ratio = m.methodParams2.cm_pu_ratio.v;
                    res.cr_cm_pu_ratio_err = m.methodParams2.cm_pu_ratio.err;
                    res.cr_pu_half_life = m.methodParams2.pu_half_life;
                    byte[] b = new byte[INCC.DATE_TIME_LENGTH];
                    char[] a = m.methodParams2.cm_pu_ratio_date.ToString("yy.MM.dd").ToCharArray();
                    Encoding.ASCII.GetBytes(a, 0, a.Length, b, 0);
                    TransferUtils.Copy(b, res.cr_cm_pu_ratio_date);
                    res.cr_cm_u_ratio = m.methodParams2.cm_u_ratio.v;
                    res.cr_cm_u_ratio = m.methodParams2.cm_u_ratio.err;
                    a = m.methodParams2.cm_u_ratio_date.ToString("yy.MM.dd").ToCharArray();
                    Encoding.ASCII.GetBytes(a, 0, a.Length, b, 0);
                    TransferUtils.Copy(b, res.cr_cm_u_ratio_date);
                    StrToBytes(INCC.MAX_ITEM_ID_LENGTH, m.methodParams2.cm_id_label, res.cr_cm_id_label);
                    StrToBytes(INCC.MAX_ITEM_ID_LENGTH, m.methodParams2.cm_id, res.cr_cm_id);
                    StrToBytes(INCC.MAX_ITEM_ID_LENGTH, m.methodParams2.cm_input_batch_id, res.cr_cm_input_batch_id);
                    res.cr_dcl_u_mass_res = m.methodParams2.cm_dcl_u_mass;
                    res.cr_dcl_u235_mass_res = m.methodParams2.cm_dcl_u_mass;

                    res.cr_cm_pu_ratio_decay_corr = m.cm_pu_ratio_decay_corr.v;
                    res.cr_cm_pu_ratio_decay_corr_err = m.cm_pu_ratio_decay_corr.err;
                    res.cr_cm_u_ratio_decay_corr = m.cm_u_ratio_decay_corr.v;
                    res.cr_cm_u_ratio_decay_corr_err = m.cm_u_ratio_decay_corr.err;

                    res.cr_curium_ratio_equation = (byte)m.methodParams.cev.cal_curve_equation;
                    res.cr_a_res = m.methodParams.cev.a;
                    res.cr_b_res = m.methodParams.cev.b;
                    res.cr_c_res = m.methodParams.cev.c;
                    res.cr_d_res = m.methodParams.cev.d;
                    res.cr_covar_ab_res = m.methodParams.cev.covar(Coeff.a, Coeff.b);
                    res.cr_covar_ac_res = m.methodParams.cev.covar(Coeff.a, Coeff.c);
                    res.cr_covar_ad_res = m.methodParams.cev.covar(Coeff.a, Coeff.d);
                    res.cr_covar_bc_res = m.methodParams.cev.covar(Coeff.b, Coeff.c);
                    res.cr_covar_bd_res = m.methodParams.cev.covar(Coeff.b, Coeff.d);
                    res.cr_covar_cd_res = m.methodParams.cev.covar(Coeff.c, Coeff.d);
                    res.cr_var_a_res = m.methodParams.cev.var_a;
                    res.cr_var_b_res = m.methodParams.cev.var_b;
                    res.cr_var_c_res = m.methodParams.cev.var_c;
                    res.cr_var_d_res = m.methodParams.cev.var_d;
                    res.cr_sigma_x_res = m.methodParams.cev.sigma_x;
                    res.curium_ratio_type_res = NewToOldCRVariants(m.methodParams.curium_ratio_type);
                    StrToBytes(INCC.MAX_DETECTOR_ID_LENGTH, ias.Methods.selector.detectorid, res.cr_curium_ratio_detector_id);
                    StrToBytes(INCC.MAX_ITEM_TYPE_LENGTH, ias.Methods.selector.material, res.cr_curium_ratio_item_type);
                }
                return res;
            }
コード例 #7
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
 internal static unsafe iresultsbase MoveCalCurve(INCCAnalysisState ias, MeasOptionSelector mos)
 {
     results_cal_curve_rec res = new results_cal_curve_rec();
     INCCMethodResult result;
     bool found = ias.Results.TryGetMethodResults(mos.MultiplicityParams, ias.Methods.selector, AnalysisMethod.CalibrationCurve, out result);
     if (found)
     {
         INCCMethodResults.results_cal_curve_rec m = (INCCMethodResults.results_cal_curve_rec)result;
         res.cc_pu240e_mass = m.pu240e_mass.v;
         res.cc_pu240e_mass_err = m.pu240e_mass.err;
         res.cc_pu_mass = m.pu_mass.v;
         res.cc_pu_mass_err = m.pu_mass.err;
         res.cc_dcl_pu240e_mass = m.dcl_pu240e_mass;
         res.cc_dcl_pu_mass = m.dcl_pu_mass;
         res.cc_dcl_minus_asy_pu_mass = m.dcl_minus_asy_pu_mass.v;
         res.cc_dcl_minus_asy_pu_mass_err = m.dcl_minus_asy_pu_mass.err;
         res.cc_dcl_minus_asy_pu_mass_pct = m.dcl_minus_asy_pu_mass_pct;
         StatePack(m.pass, res.cc_pass_fail);
         res.cc_dcl_u_mass = m.dcl_u_mass;
         res.cc_length = m.length;
         res.cc_heavy_metal_content = m.heavy_metal_content;
         res.cc_heavy_metal_correction = m.heavy_metal_correction;
         res.cc_heavy_metal_corr_singles = m.heavy_metal_corr_singles.v;
         res.cc_heavy_metal_corr_singles_err = m.heavy_metal_corr_singles.err;
         res.cc_heavy_metal_corr_doubles = m.heavy_metal_corr_doubles.v;
         res.cc_heavy_metal_corr_doubles_err = m.heavy_metal_corr_doubles.err;
         StrToBytes(INCC.MAX_DETECTOR_ID_LENGTH, ias.Methods.selector.detectorid, res.cc_cal_curve_detector_id);
         StrToBytes(INCC.MAX_ITEM_TYPE_LENGTH, ias.Methods.selector.material, res.cc_cal_curve_item_type);
         res.cc_a_res = m.methodParams.cev.a;
         res.cc_b_res = m.methodParams.cev.b;
         res.cc_c_res = m.methodParams.cev.c;
         res.cc_d_res = m.methodParams.cev.d;
         res.cc_cal_curve_type_res = (double)m.methodParams.CalCurveType;
         res.cc_covar_ab_res = m.methodParams.cev.covar(Coeff.a, Coeff.b);
         res.cc_covar_ac_res = m.methodParams.cev.covar(Coeff.a, Coeff.c);
         res.cc_covar_ad_res = m.methodParams.cev.covar(Coeff.a, Coeff.d);
         res.cc_covar_bc_res = m.methodParams.cev.covar(Coeff.b, Coeff.c);
         res.cc_covar_bd_res = m.methodParams.cev.covar(Coeff.b, Coeff.d);
         res.cc_covar_cd_res = m.methodParams.cev.covar(Coeff.c, Coeff.d);
         res.cc_var_a_res = m.methodParams.cev.var_a;
         res.cc_var_b_res = m.methodParams.cev.var_b;
         res.cc_var_c_res = m.methodParams.cev.var_c;
         res.cc_var_d_res = m.methodParams.cev.var_d;
         res.cc_sigma_x_res = m.methodParams.cev.sigma_x;
         res.cc_heavy_metal_corr_factor_res = m.methodParams.heavy_metal_corr_factor;
         res.cc_heavy_metal_reference_res = m.methodParams.heavy_metal_reference;
         res.cc_percent_u235_res = m.methodParams.percent_u235;
     }
     return res;
 }
コード例 #8
0
        protected Section ConstructReportSection(INCCReportSection section, Detector det, MeasOptionSelector moskey = null)
        {
            INCCStyleSection sec = null;

            try
            {
                switch (section)
                {
                case INCCReportSection.Header:
                    sec = new INCCStyleSection(null, 1);
                    sec.AddHeader(N.App.Name + " " + N.App.Config.VersionString);      // section header
                    break;

                case INCCReportSection.Context:
                    sec = new INCCStyleSection(null, 1);
                    ConstructContextContent(sec, det);
                    break;

                case INCCReportSection.Isotopics:
                    if (AssaySelector.ForMass(meas.MeasOption))
                    {
                        sec = new INCCStyleSection(null, 1);
                        sec.SetFPCurrentFormatPrecision(4);
                        Isotopics curiso = Isotopics.update_isotopics(1.0, meas.MeasDate, meas.Isotopics, meas.logger, N.App.AppContext.INCCParity);
                        if (curiso == null)
                        {
                            curiso = new Isotopics();
                            meas.Isotopics.CopyTo(curiso);
                            ctrllog.TraceEvent(LogLevels.Warning, 82034, "Using incorrect updated defaults for " + meas.Isotopics.id);
                        }
                        sec.AddTwo("Isotopics id:", meas.Isotopics.id);
                        sec.AddTwo("Isotopics source code:", meas.Isotopics.source_code.ToString());
                        sec.AddDualNumericRow("Pu238:", meas.Isotopics[Isotope.pu238], curiso[Isotope.pu238]);
                        sec.AddDualNumericRow("Pu239:", meas.Isotopics[Isotope.pu239], curiso[Isotope.pu239]);
                        sec.AddDualNumericRow("Pu240:", meas.Isotopics[Isotope.pu240], curiso[Isotope.pu240]);
                        sec.AddDualNumericRow("Pu241:", meas.Isotopics[Isotope.pu241], curiso[Isotope.pu241]);
                        sec.AddDualNumericRow("Pu242:", meas.Isotopics[Isotope.pu242], curiso[Isotope.pu242]);
                        sec.AddDualDateOnlyRow("Pu date:", meas.Isotopics.pu_date, curiso.pu_date);
                        sec.AddDualNumericRow("Am241:", meas.Isotopics[Isotope.am241], curiso[Isotope.am241]);
                        sec.AddDualDateOnlyRow("Am date:", meas.Isotopics.am_date, curiso.am_date);
                        // dev note: here is where the alternative K vals are added in the Euratom version
                    }
                    break;

                case INCCReportSection.ShiftRegister:
                    sec = new INCCStyleSection(null, 1);
                    ConstructSRSection(sec, moskey.MultiplicityParams, det);
                    break;

                case INCCReportSection.Adjustments:
                    sec = new INCCStyleSection(null, 1);
                    if (AssaySelector.ForMass(meas.MeasOption) || meas.MeasOption == AssaySelector.MeasurementOption.rates)
                    {
                        ushort push = sec.FPFormatPrecision;
                        sec.SetFPCurrentFormatPrecision(4);
                        sec.AddNumericRow("Normalization constant:", meas.Norm.currNormalizationConstant);
                        sec.SetFPCurrentFormatPrecision(push);
                    }
                    if (AssaySelector.UsesBackground(meas.MeasOption))
                    {
                        sec.AddNumericRow("Passive singles bkgrnd:", meas.Background.DeadtimeCorrectedSinglesRate);
                        sec.AddNumericRow("Passive doubles bkgrnd:", meas.Background.DeadtimeCorrectedDoublesRate);
                        sec.AddNumericRow("Passive triples bkgrnd:", meas.Background.DeadtimeCorrectedTriplesRate);

                        if (det.Id.SRType <= InstrType.AMSR)
                        {
                            sec.AddNumericRow("Passive scaler1 bkgrnd:", meas.Background.Scaler1.v);
                            sec.AddNumericRow("Passive scaler2 bkgrnd:", meas.Background.Scaler2.v);
                        }

                        sec.AddNumericRow("Active singles bkgrnd:", meas.Background.INCCActive.Singles);
                        sec.AddNumericRow("Active doubles bkgrnd:", meas.Background.INCCActive.Doubles);
                        sec.AddNumericRow("Active triples bkgrnd:", meas.Background.INCCActive.Triples);
                        if (det.Id.SRType <= InstrType.AMSR)
                        {
                            sec.AddNumericRow("Passive scaler1 bkgrnd:", meas.Background.INCCActive.Scaler1Rate);
                            sec.AddNumericRow("Passive scaler2 bkgrnd:", meas.Background.INCCActive.Scaler2Rate);
                        }
                    }
                    break;

                case INCCReportSection.CycleSummary:
                    sec = new INCCStyleSection(null, 1);
                    sec.AddIntegerRow(String.Format("Number {0} cycles:", meas.INCCAnalysisState.Methods.HasActiveSelected() || meas.INCCAnalysisState.Methods.HasActiveMultSelected()?"Active":"Passive"), (int)meas.Cycles.GetValidCycleCountForThisKey(moskey.MultiplicityParams));    //det.MultiplicityParams)); // could also use CycleList length but CycleList can be longer when a reanalysis occurs and the analysis processing stops short of the end of the list due to modified termination conditions
                    sec.AddNumericRow("Count time (sec):", (meas.Cycles.Count > 0 ? meas.Cycles[0].TS.TotalSeconds : 0.0));
                    break;

                case INCCReportSection.Messages:
                    List <MeasurementMsg> sl = null;
                    bool found = meas.Messages.TryGetValue(moskey.MultiplicityParams, out sl);
                    if (found)
                    {
                        sec = new INCCStyleSection(null, 1);
                        sec.AddHeader(String.Format("{0} messages", meas.INCCAnalysisState.Methods.HasActiveSelected() || meas.INCCAnalysisState.Methods.HasActiveMultSelected() ? "Active" : "Passive"));      /// todo: is there an active messages section header analog?
                        foreach (MeasurementMsg m in sl)
                        {
                            Row r = new Row();
                            r.Add(0, m.text);      // expand to log style with toString?
                            sec.Add(r);
                        }
                    }
                    break;

                case INCCReportSection.Reference:
                    sec = new INCCStyleSection(null, 1);
                    sec.AddHeader("Counting results, summaries and cycle counts file name");      // section header
                    Row resline = new Row(); resline.Add(0, "  " + meas.ResultsFileName);
                    sec.Add(resline);
                    break;

                default:
                    break;
                }
            }
            catch (Exception e)
            {
                ctrllog.TraceException(e);
            }
            return(sec);
        }
コード例 #9
0
        protected Section ConstructReportSection(INCCReportSection section, Detector det, MeasOptionSelector moskey = null)
        {
            INCCStyleSection sec = null;
            try
            {
                switch (section)
                {
                    case INCCReportSection.Header:
                        sec = new INCCStyleSection(null, 1);
                        sec.AddHeader(N.App.Name + " " + N.App.Config.VersionString);  // section header
                        break;
                    case INCCReportSection.Context:
                        sec = new INCCStyleSection(null, 1);
                        ConstructContextContent(sec, det);
                        break;
                    case INCCReportSection.Isotopics:
                        if (AssaySelector.ForMass(meas.MeasOption))
                        {
                            sec = new INCCStyleSection(null, 1);
                            sec.SetFPCurrentFormatPrecision(4);
                            Isotopics curiso = Isotopics.update_isotopics(1.0, meas.MeasDate, meas.Isotopics, meas.logger, N.App.AppContext.INCCParity);
                            if (curiso == null)
                            {
                                curiso = new Isotopics();
                                meas.Isotopics.CopyTo(curiso);
                                ctrllog.TraceEvent(LogLevels.Warning, 82034,  "Using incorrect updated defaults for " + meas.Isotopics.id);
                            }
                            sec.AddTwo("Isotopics id:", meas.Isotopics.id);
                            sec.AddTwo("Isotopics source code:", meas.Isotopics.source_code.ToString());
                            sec.AddDualNumericRow("Pu238:", meas.Isotopics[Isotope.pu238], curiso[Isotope.pu238]);
                            sec.AddDualNumericRow("Pu239:", meas.Isotopics[Isotope.pu239], curiso[Isotope.pu239]);
                            sec.AddDualNumericRow("Pu240:", meas.Isotopics[Isotope.pu240], curiso[Isotope.pu240]);
                            sec.AddDualNumericRow("Pu241:", meas.Isotopics[Isotope.pu241], curiso[Isotope.pu241]);
                            sec.AddDualNumericRow("Pu242:", meas.Isotopics[Isotope.pu242], curiso[Isotope.pu242]);
                            sec.AddDualDateOnlyRow("Pu date:", meas.Isotopics.pu_date, curiso.pu_date);
                            sec.AddDualNumericRow("Am241:", meas.Isotopics[Isotope.am241], curiso[Isotope.am241]);
                            sec.AddDualDateOnlyRow("Am date:", meas.Isotopics.am_date, curiso.am_date);
                            // dev note: here is where the alternative K vals are added in the Euratom version
                        }
                        break;
                    case INCCReportSection.ShiftRegister:
                        sec = new INCCStyleSection(null, 1);
                        ConstructSRSection(sec, moskey.MultiplicityParams, det);
                        break;
                    case INCCReportSection.Adjustments:
                        sec = new INCCStyleSection(null, 1);
                        if (AssaySelector.ForMass(meas.MeasOption) || meas.MeasOption == AssaySelector.MeasurementOption.rates)
                        {
                            ushort push = sec.FPFormatPrecision;
                            sec.SetFPCurrentFormatPrecision(4);
                            sec.AddNumericRow("Normalization constant:", meas.Norm.currNormalizationConstant);
                            sec.SetFPCurrentFormatPrecision(push);
                        }
                        if (AssaySelector.UsesBackground(meas.MeasOption))
                        {
                            sec.AddNumericRow("Passive singles bkgrnd:", meas.Background.DeadtimeCorrectedSinglesRate);
                            sec.AddNumericRow("Passive doubles bkgrnd:", meas.Background.DeadtimeCorrectedDoublesRate);
                            sec.AddNumericRow("Passive triples bkgrnd:", meas.Background.DeadtimeCorrectedTriplesRate);

                            if (det.Id.SRType <= InstrType.AMSR)
                            {
                                sec.AddNumericRow("Passive scaler1 bkgrnd:", meas.Background.Scaler1.v);
                                sec.AddNumericRow("Passive scaler2 bkgrnd:", meas.Background.Scaler2.v);
                            }

                            sec.AddNumericRow("Active singles bkgrnd:", meas.Background.INCCActive.Singles);
                            sec.AddNumericRow("Active doubles bkgrnd:", meas.Background.INCCActive.Doubles);
                            sec.AddNumericRow("Active triples bkgrnd:", meas.Background.INCCActive.Triples);
                            if (det.Id.SRType <= InstrType.AMSR)
                            {
                                sec.AddNumericRow("Passive scaler1 bkgrnd:", meas.Background.INCCActive.Scaler1Rate);
                                sec.AddNumericRow("Passive scaler2 bkgrnd:", meas.Background.INCCActive.Scaler2Rate);
                            }
                        }
                        break;
                    case INCCReportSection.CycleSummary:
                        sec = new INCCStyleSection(null, 1);
                        sec.AddIntegerRow(String.Format("Number {0} cycles:",meas.INCCAnalysisState.Methods.HasActiveSelected() || meas.INCCAnalysisState.Methods.HasActiveMultSelected()?"Active":"Passive"), (int)meas.Cycles.GetValidCycleCountForThisKey(moskey.MultiplicityParams)); //det.MultiplicityParams)); // could also use CycleList length but CycleList can be longer when a reanalysis occurs and the analysis processing stops short of the end of the list due to modified termination conditions
                        sec.AddNumericRow("Count time (sec):", (meas.Cycles.Count > 0 ? meas.Cycles[0].TS.TotalSeconds : 0.0));
                        break;

                    case INCCReportSection.Messages:
                        List<MeasurementMsg> sl = null;
                        bool found = meas.Messages.TryGetValue(moskey.MultiplicityParams, out sl);
                        if (found)
                        {
                            sec = new INCCStyleSection(null, 1);
                            sec.AddHeader(String.Format("{0} messages", meas.INCCAnalysisState.Methods.HasActiveSelected() || meas.INCCAnalysisState.Methods.HasActiveMultSelected() ? "Active" : "Passive"));  /// todo: is there an active messages section header analog?
                            foreach (MeasurementMsg m in sl)
                            {
                                Row r = new Row();
                                r.Add(0, m.text);  // expand to log style with toString?
                                sec.Add(r);
                            }
                        }
                        break;
                    case INCCReportSection.Reference:
                        sec = new INCCStyleSection(null, 1);
                        sec.AddHeader("Counting results, summaries and cycle counts file name");  // section header
                        Row resline = new Row(); resline.Add(0, "  " + meas.ResultsFileName);
                        sec.Add(resline);
                        break;
                    default:
                        break;
                }
            }
            catch (Exception e)
            {
                ctrllog.TraceException(e);
            }
            return sec;
        }
コード例 #10
0
ファイル: INCCMeasurement.cs プロジェクト: tempbottle/INCC6
        /// <summary>
        /// Save in the database the summary <see cref="INCCResults.results_rec"/> results for every type of INCC measurement.
        /// </summary>
        /// <param name="m">The measurement to preserve</param>
        /// <param name="moskey">The option selector+multiplicity key for the method results map</param> 
        static void SaveSummaryResultsForThisMeasurement(this Measurement m, MeasOptionSelector moskey)
        {
            DB.Measurements ms = new DB.Measurements();
            long mid = ms.Lookup(m.Detectors[0].Id.DetectorName, m.MeasDate, m.MeasOption.PrintName());

            DB.Results dbres = new DB.Results(ms.db);
            // save results with mid as foreign key
            bool b = dbres.Update(mid, m.INCCAnalysisResults.TradResultsRec.ToDBElementList());
            m.Logger.TraceEvent(NCCReporter.LogLevels.Info, 34045, (b ? "Preserved " : "Failed to save ") + "summary results");

        }
コード例 #11
0
ファイル: INCCMeasurement.cs プロジェクト: tempbottle/INCC6
		/// <summary>
		/// Save all updated and new results in the database
		/// </summary>
		public static void SaveMeasurementResults(this Measurement meas)
		{
            SaveMeasurementCycles(meas);

			IEnumerator iter = meas.CountingAnalysisResults.GetMultiplicityEnumerator();
			while (iter.MoveNext())
			{
				Multiplicity mkey = (Multiplicity)((KeyValuePair<SpecificCountingAnalyzerParams, object>)(iter.Current)).Key;
                if (NC.App.Opstate.IsAbortRequested)
					return;

				INCCResult results;
				MeasOptionSelector moskey = new MeasOptionSelector(meas.MeasOption, mkey);
				bool found = meas.INCCAnalysisResults.TryGetValue(moskey, out results);

				try
				{
					switch (meas.MeasOption)
					{
                        case AssaySelector.MeasurementOption.background: // calculated in CalculateResults, update bkg and save the result to the DB
							// save the background result to the bkg_parms_rec table under the current SR key
							BackgroundParameters c = NC.App.DB.BackgroundParameters.Get(meas.Detectors[0]);
							if (c != null)
								c.Copy(meas.Background);  // copy changes back to original on user affirmation
							else
							{
								c = meas.Background;
								NC.App.DB.BackgroundParameters.GetMap().Add(meas.Detectors[0], c);
							}
							NC.App.DB.BackgroundParameters.Set(meas.Detectors[0], c);
							break;
                        case AssaySelector.MeasurementOption.initial: // calculated in CalculateResults, update norm and save the norm and init_src result to the DB
                            INCCResults.results_init_src_rec results_init_src = (INCCResults.results_init_src_rec)results;
                            // on fail, only the relevant results_init_src_rec is saved
                            // on pass, the normalization parameters are modified with the results_init_src_rec results, and so both are updated.
                            if (results_init_src.pass)
                            {
                                NormParameters np = NC.App.DB.NormParameters.Get(meas.Detectors[0]);
                                if (np != null)
                                    np.Copy(meas.Norm);  // copy any changes made to Norm as defined for the current detector
                                else
                                {
                                    np = meas.Norm;
                                    NC.App.DB.NormParameters.GetMap().Add(meas.Detectors[0], np);
                                }
                                NC.App.DB.NormParameters.Set(meas.Detectors[0], np);
                            }
                            SaveSpecificResultsForThisMeasurement(meas, results);
							break;
						case AssaySelector.MeasurementOption.normalization:  // calculated in CalculateResults, now save the result to the DB
                        case AssaySelector.MeasurementOption.precision:      // ditto
                            SaveSpecificResultsForThisMeasurement(meas, results);
							break;
						case AssaySelector.MeasurementOption.calibration: // ditto with the method analyses results, but they're a bit different
                        case AssaySelector.MeasurementOption.verification:
                            SaveMethodResultsForThisMeasurement(meas, moskey);
                            break;
                        case AssaySelector.MeasurementOption.holdup: // NEXT: Hold-up held up, implement it #102  
							break;
					}
				}
				catch (Exception e)
				{
					meas.Logger.TraceException(e);
				}

                SaveSummaryResultsForThisMeasurement(meas, moskey);

            }

            meas.PersistFileNames();

        }
コード例 #12
0
        protected Section ConstructReportSection(INCCTestDataSection section, Detector det, MeasOptionSelector moskey = null)
        {
            INCCTestDataStyle sec = null;

            try
            {
                switch (section)
                {
                case INCCTestDataSection.CycleSummary:
                    sec = new INCCTestDataStyle(null, 0);
                    sec.AddOne((Int32)meas.Cycles.GetValidCycleCountForThisKey(moskey.MultiplicityParams));      // could also use CycleList length but CycleList can be longer when a reanalysis occurs and the analysis processing stops short of the end of the list due to modified termination conditions
                    sec.AddOne((Int32)(meas.Cycles.Count > 0 ? meas.Cycles[0].TS.TotalSeconds : 0.0));
                    break;

                default:
                    break;
                }
            }
            catch (Exception e)
            {
                ctrllog.TraceException(e);
            }
            return(sec);
        }
コード例 #13
0
        protected Section ConstructReportSection(INCCReportSection section, MeasOptionSelector moskey, INCCResult ir, Detector det)
        {
            INCCStyleSection sec = null;

            try
            {
                switch (section)
                {
                // NEXT: in progress, an identical copy of full INCC report sections
                case INCCReportSection.SummedRawData:
                    sec = new INCCStyleSection(null, 1, INCCStyleSection.ReportSection.Summary);
                    sec.SetFPCurrentFormatPrecision(0);
                    sec.AddHeader(String.Format("{0} summed raw data", meas.INCCAnalysisState.Methods.HasActiveSelected() || meas.INCCAnalysisState.Methods.HasActiveMultSelected()?"Active":"Passive"));     // section header
                    sec.AddNumericRow("Shift register singles sum:", meas.SinglesSum);
                    sec.AddNumericRow("Shift register reals + accidentals sum:", ir.RASum);
                    sec.AddNumericRow("Shift register accidentals sum:", ir.ASum);
                    if (!det.Id.source.UsingVirtualSRCounting(det.Id.SRType))
                    {
                        sec.AddNumericRow("Shift register 1st scaler sum:", ir.S1Sum);
                        sec.AddNumericRow("Shift register 2nd scaler sum:", ir.S2Sum);
                    }
                    break;

                case INCCReportSection.SummedRA:
                    sec = new INCCStyleSection(null, 1, INCCStyleSection.ReportSection.MultiColumn);
                    sec.AddHeader(String.Format("{0} summed multiplicity distributions", meas.INCCAnalysisState.Methods.HasActiveSelected() || meas.INCCAnalysisState.Methods.HasActiveMultSelected()?"Active":"Passive"));     // section header
                    int[] srawidths = new int[] { 5, 12, 12 };
                    int   minbin, maxbin;
                    minbin = Math.Min(ir.RAMult.Length, ir.NormedAMult.Length);
                    maxbin = Math.Max(ir.RAMult.Length, ir.NormedAMult.Length);
                    sec.AddColumnRowHeader(new string[] { " ", "R+A sums", "A sums" }, srawidths);
                    for (int i = 0; i < minbin; i++)
                    {
                        sec.AddColumnRow(new ulong[] { (ulong)i, ir.RAMult[i], ir.NormedAMult[i] }, srawidths);
                    }
                    for (int i = minbin; i < maxbin; i++)      // check for uneven column
                    {
                        ulong[] potential = new ulong[3];
                        potential[0] = (ulong)i;
                        if (i < ir.RAMult.Length)
                        {
                            potential[1] = ir.RAMult[i];
                        }
                        if (i < ir.NormedAMult.Length)
                        {
                            potential[2] = ir.NormedAMult[i];
                        }
                        sec.AddColumnRow(potential, srawidths);
                    }
                    break;

                case INCCReportSection.MassResults:
                    sec = new INCCStyleSection(null, 1, INCCStyleSection.ReportSection.MethodResults);
                    //Results are not always passive. Boo.
                    sec.AddHeader(String.Format("{0} Results", meas.INCCAnalysisState.Methods.HasActiveSelected() || meas.INCCAnalysisState.Methods.HasActiveMultSelected()?"Active":"Passive"));     // section header
                    sec.AddNumericRow("Singles:", ir.DeadtimeCorrectedSinglesRate);
                    sec.AddNumericRow("Doubles:", ir.DeadtimeCorrectedDoublesRate);
                    sec.AddNumericRow("Triples:", ir.DeadtimeCorrectedTriplesRate);
                    //changed to DTC rates.  Raw rates meaningless here hn 11.5.2014
                    //sec.AddNumericRow("Quads:", mcr.DeadtimeCorrectedQuadsRate); // todo: quads delayed until pents are ready per DN
                    if (!det.Id.source.UsingVirtualSRCounting(det.Id.SRType))
                    {
                        sec.AddNumericRow("Scaler 1:", ir.Scaler1);
                        sec.AddNumericRow("Scaler 2:", ir.Scaler2);
                    }

                    //if (det.Id.SRType >= LMDAQ.InstrType.NPOD)
                    //{
                    //    sec.Add(new Row()); // blank line
                    //    sec.AddNumericRow("Dyt. Singles:", ir.DytlewskiCorrectedSinglesRate);
                    //    sec.AddNumericRow("Dyt. Doubles:", ir.DytlewskiCorrectedDoublesRate);
                    //    sec.AddNumericRow("Dyt. Triples:", ir.DytlewskiCorrectedTriplesRate);
                    //}
                    break;

                case INCCReportSection.MethodResultsAndParams:
                    // ir contains the measurement option-specific results: empty for rates and holdup, and also empty for calib and verif, the method-focused analyses,
                    // but values are present for initial, normalization, precision, and should be present for background for the tm bkg results
                    List <Row> rl = ir.ToLines(meas);
                    sec = new INCCStyleSection(null, 0, INCCStyleSection.ReportSection.MethodResults);
                    sec.AddRange(rl);

                    switch (meas.MeasOption)
                    {
                    case AssaySelector.MeasurementOption.background:
                        if (meas.Background.TMBkgParams.ComputeTMBkg)
                        {
                            ctrllog.TraceEvent(LogLevels.Warning, 82010, "Background truncated multiplicity");         // todo: present the tm bkg results on m.Background
                        }
                        break;

                    case AssaySelector.MeasurementOption.initial:
                    case AssaySelector.MeasurementOption.normalization:
                    case AssaySelector.MeasurementOption.precision:
                        break;

                    case AssaySelector.MeasurementOption.verification:
                    case AssaySelector.MeasurementOption.calibration:
                    {
                        INCCMethodResults imrs;
                        bool beendonegot = meas.INCCAnalysisResults.TryGetINCCResults(moskey.MultiplicityParams, out imrs);
                        if (beendonegot && imrs.Count > 0)             // should be true for verification and calibration
                        {
                            // we've got a distinct detector id and material type on the methods, so that is the indexer here
                            Dictionary <AnalysisMethod, INCCMethodResult> amimr = imrs[meas.INCCAnalysisState.Methods.selector];

                            // now get an enumerator over the map of method results
                            Dictionary <AnalysisMethod, INCCMethodResult> .Enumerator ai = amimr.GetEnumerator();
                            while (ai.MoveNext())
                            {
                                INCCMethodResult imr = ai.Current.Value;
                                // show the primaryMethod
                                if (ai.Current.Key.Equals(imrs.primaryMethod))
                                {
                                    sec.Add(new Row());
                                    Row rh = new Row();
                                    rh.Add(0, "            PRIMARY RESULT");
                                    sec.Add(rh);
                                }
                                rl = imr.ToLines(meas);
                                sec.AddRange(rl);
                                // todo: optional use of END_PRIMARY_RESULT as in some INCC report formats, but not others
                            }
                        }
                    }
                    break;

                    case AssaySelector.MeasurementOption.rates:
                    case AssaySelector.MeasurementOption.holdup:
                    case AssaySelector.MeasurementOption.unspecified:
                    default:         // nothing new to present with these
                        break;
                    }
                    break;

                case INCCReportSection.RawCycles:
                    sec = new INCCStyleSection(null, 1, INCCStyleSection.ReportSection.MultiColumn);
                    sec.AddHeader(String.Format("{0} cycle raw data", meas.INCCAnalysisState.Methods.HasActiveSelected() || meas.INCCAnalysisState.Methods.HasActiveMultSelected()?"Active":"Passive"));     // section header
                    int[] crdwidths = new int[] { 5, 10, 10, 10, 10, 10, 10 };
                    sec.AddColumnRowHeader(new string[] { "Cycle", "Singles", "R+A  ", "A    ", "Scaler1", "Scaler2", "QC Tests" }, crdwidths);
                    foreach (Cycle cyc in meas.Cycles)
                    {
                        // if no results on the cycle, these map indexers throw
                        if (cyc.CountingAnalysisResults.GetResultsCount(typeof(Multiplicity)) > 0)                                // if no results on the cycle, these map indexers throw
                        {
                            MultiplicityCountingRes mcr = (MultiplicityCountingRes)cyc.CountingAnalysisResults[moskey.MultiplicityParams];
                            sec.AddCycleColumnRow(cyc.seq,
                                                  new ulong[] { (ulong)mcr.Totals, (ulong)mcr.RASum, (ulong)mcr.ASum, (ulong)mcr.Scaler1.v, (ulong)mcr.Scaler2.v },
                                                  meas.AcquireState.qc_tests?cyc.QCStatus(moskey.MultiplicityParams).INCCString():"Off", crdwidths);
                        }
                    }
                    break;

                case INCCReportSection.DTCRateCycles:

                    sec = new INCCStyleSection(null, 1, INCCStyleSection.ReportSection.MultiColumn);
                    sec.AddHeader(String.Format("{0} cycle DTC rate data", meas.AcquireState.well_config == WellConfiguration.Active?"Active":"Passive"));     // section header
                    int[] crawidths = new int[] { 5, 13, 13, 13, 13, 10 };
                    sec.AddColumnRowHeader(new string[] { "Cycle", "Singles", "Doubles", "Triples", "Mass", "QC Tests" }, crawidths);

                    foreach (Cycle cyc in meas.Cycles)
                    {
                        if (cyc.CountingAnalysisResults.GetResultsCount(typeof(Multiplicity)) > 0)                                // if no results on the cycle, these map indexers throw
                        {
                            MultiplicityCountingRes mcr = (MultiplicityCountingRes)cyc.CountingAnalysisResults[moskey.MultiplicityParams];
                            //These debug rows show raw rates for comparison hn 10.30
                            //sec.AddCycleColumnRow(cyc.seq,
                            //Again, could be wrong.
                            //    new double[] { mcr.RawSinglesRate.v, mcr.RawDoublesRate.v, -1, -1 },
                            //     cyc.QCStatus(moskey.MultiplicityParams).INCCString(), crawidths);
                            //Again, could be wrong.
                            // TODO: Am actually printing out the DTC rates per cycle.  This seems to work in all cases EXCEPT "precision" hn 11.5
                            sec.AddCycleColumnRow(cyc.seq,
                                                  // Using the corrected rates!
                                                  new double[] { mcr.DeadtimeCorrectedSinglesRate.v, mcr.DeadtimeCorrectedDoublesRate.v, mcr.DeadtimeCorrectedTriplesRate.v, mcr.mass /*Mass*/ },
                                                  meas.AcquireState.qc_tests?cyc.QCStatus(moskey.MultiplicityParams).INCCString():"Off", crawidths);
                        }
                    }
                    break;

                case INCCReportSection.MultiplicityDistributions:
                    sec = new INCCStyleSection(null, 1, INCCStyleSection.ReportSection.MultiColumn);
                    sec.AddHeader(String.Format("{0} multiplicity distributions for each cycle", meas.INCCAnalysisState.Methods.HasActiveSelected() || meas.INCCAnalysisState.Methods.HasActiveMultSelected()?"Active":"Passive"));     // section header
                    int[] csrawidths = new int[] { 6, 12, 12 };
                    foreach (Cycle cyc in meas.Cycles)
                    {
                        if (cyc.CountingAnalysisResults.GetResultsCount(typeof(Multiplicity)) > 0)                                // if no results on the cycle, these map indexers throw
                        {
                            MultiplicityCountingRes mcr = (MultiplicityCountingRes)cyc.CountingAnalysisResults[moskey.MultiplicityParams];
                            minbin = Math.Min(mcr.RAMult.Length, mcr.NormedAMult.Length);
                            maxbin = Math.Max(mcr.RAMult.Length, mcr.NormedAMult.Length);
                            sec.AddColumnRowHeader(new string[] { "Cycle " + cyc.seq, "R+A ", "A   " }, csrawidths);
                            for (int i = 0; i < minbin; i++)
                            {
                                sec.AddColumnRow(new ulong[] { (ulong)i, mcr.RAMult[i], mcr.NormedAMult[i] }, csrawidths);
                            }
                            for (int i = minbin; i < maxbin; i++)      // check for uneven column
                            {
                                ulong[] potential = new ulong[3];
                                potential[0] = (ulong)i;
                                if (i < mcr.RAMult.Length)
                                {
                                    potential[1] = mcr.RAMult[i];
                                }
                                if (i < mcr.NormedAMult.Length)
                                {
                                    potential[2] = mcr.NormedAMult[i];
                                }
                                sec.AddColumnRow(potential, csrawidths);
                            }
                        }
                        sec.Add(new Row());    // blank
                    }
                    break;

                default:
                    break;
                }
            }
            catch (Exception e)
            {
                ctrllog.TraceException(e);
            }
            return(sec);
        }
コード例 #14
0
        public void GenerateReport(Measurement m)
        {
            if (N.App.Opstate.IsAbortRequested) // handle stop, cancel, abort here, for stop does it roll back all report gen from here?
            {
                return;
            }
            IEnumerator iter = m.INCCAnalysisResults.GetMeasSelectorResultsEnumerator();

            while (iter.MoveNext())
            {
                MeasOptionSelector moskey = (MeasOptionSelector)iter.Current;
                INCCResult         ir     = m.INCCAnalysisResults[moskey];
                // create one results for each SR key
                StartReportGeneration(m, m.MeasOption.PrintName() + " INCC " +
                                      (m.INCCAnalysisResults.Count > 1 ? "[" + moskey.MultiplicityParams.ShortName() + "] " : ""), // add an identifying signature to each file name if more than one active virtual SR
                                      ' ');                                                                                        // make these text files
                //Detector det = meas.Detectors.GetIt(moskey.SRParams);
                // now assuming only one detector on the list, so can use [0], the mos keys have specific values for virtual SR counting, overiding the detector
                Detector det = meas.Detectors[0];
                try
                {
                    sections.Add(ConstructReportSection(INCCReportSection.Header, det));
                    sections.Add(ConstructReportSection(INCCReportSection.Context, det));
                    sections.Add(ConstructReportSection(INCCReportSection.Isotopics, det));
                    sections.Add(ConstructReportSection(INCCReportSection.ShiftRegister, det, moskey));
                    sections.Add(ConstructReportSection(INCCReportSection.Adjustments, det));
                    sections.Add(ConstructReportSection(INCCReportSection.CycleSummary, det, moskey));
                    sections.Add(ConstructReportSection(INCCReportSection.Messages, det, moskey));

                    sections.Add(ConstructReportSection(INCCReportSection.SummedRawData, moskey, ir, det));
                    sections.Add(ConstructReportSection(INCCReportSection.SummedRA, moskey, ir, det));

                    sections.Add(ConstructReportSection(INCCReportSection.MassResults, moskey, ir, det));
                    sections.Add(ConstructReportSection(INCCReportSection.MethodResultsAndParams, moskey, ir, det));
                    sections.Add(ConstructReportSection(INCCReportSection.RawCycles, moskey, ir, det));
                    sections.Add(ConstructReportSection(INCCReportSection.DTCRateCycles, moskey, ir, det));
                    sections.Add(ConstructReportSection(INCCReportSection.MultiplicityDistributions, moskey, ir, det));
                    sections.Add(ConstructReportSection(INCCReportSection.Reference, det));
                    sections.RemoveAll(s => (s == null));

                    // copy all section rows to the report row list (t.rows)
                    int rowcount = 0;
                    foreach (Section sec in sections)
                    {
                        rowcount += sec.Count;
                    }
                    Array.Resize(ref t.rows, rowcount);

                    int idx = 0;
                    foreach (Section sec in sections)
                    {
                        Array.Copy(sec.ToArray(), 0, t.rows, idx, sec.Count); idx += sec.Count;
                    }
                }
                catch (Exception e)
                {
                    ctrllog.TraceException(e);
                }

                FinishReportGeneration();
            }
        }
コード例 #15
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
 internal static unsafe iresultsbase MoveTruncMult(INCCAnalysisState ias, MeasOptionSelector mos)
 {
     results_truncated_mult_rec res = new results_truncated_mult_rec();
     INCCMethodResult result;
     bool found = ias.Results.TryGetMethodResults(mos.MultiplicityParams, ias.Methods.selector, AnalysisMethod.TruncatedMultiplicity, out result);
     if (found)
     {
         INCCMethodResults.results_truncated_mult_rec m = (INCCMethodResults.results_truncated_mult_rec)result;
         res.tm_bkg_singles = m.bkg.Singles.v;
         res.tm_bkg_singles_err = m.bkg.Singles.err;
         res.tm_bkg_zeros = m.bkg.Zeros.v;
         res.tm_bkg_zeros_err = m.bkg.Zeros.err;
         res.tm_bkg_ones = m.bkg.Ones.v;
         res.tm_bkg_ones_err = m.bkg.Ones.err;
         res.tm_bkg_twos = m.bkg.Twos.v;
         res.tm_bkg_twos_err = m.bkg.Twos.err;
         res.tm_net_singles = m.net.Singles.v;
         res.tm_net_singles_err = m.net.Singles.err;
         res.tm_net_zeros = m.net.Zeros.v;
         res.tm_net_zeros_err = m.net.Zeros.err;
         res.tm_net_ones = m.net.Ones.v;
         res.tm_net_ones_err = m.net.Ones.err;
         res.tm_net_twos = m.net.Twos.v;
         res.tm_net_twos_err = m.net.Twos.err;
         res.tm_k_alpha = m.k.alpha.v;
         res.tm_k_alpha_err = m.k.alpha.err;
         res.tm_k_pu240e_mass = m.k.pu240e_mass.v;
         res.tm_k_pu240e_mass_err = m.k.pu240e_mass.err;
         res.tm_k_pu_mass = m.k.pu_mass.v;
         res.tm_k_pu_mass_err = m.k.pu_mass.err;
         res.tm_k_dcl_pu240e_mass = m.k.dcl_pu240e_mass;
         res.tm_k_dcl_pu_mass = m.k.dcl_pu_mass;
         res.tm_k_dcl_minus_asy_pu_mass = m.k.dcl_minus_asy_pu_mass.v;
         res.tm_k_dcl_minus_asy_pu_mass_err = m.k.dcl_minus_asy_pu_mass.err;
         res.tm_k_dcl_minus_asy_pu_mass_pct = m.k.dcl_minus_asy_pu_mass_pct;
         StatePack(m.k.pass, res.tm_k_pass_fail);
         res.tm_s_eff = m.s.eff.v;
         res.tm_s_eff_err = m.s.eff.err;
         res.tm_s_alpha = m.s.alpha.v;
         res.tm_s_alpha_err = m.s.alpha.err;
         res.tm_s_pu240e_mass = m.s.pu240e_mass.v;
         res.tm_s_pu240e_mass_err = m.s.pu240e_mass.err;
         res.tm_s_pu_mass = m.s.pu_mass.v;
         res.tm_s_pu_mass_err = m.s.pu_mass.err;
         res.tm_s_dcl_pu240e_mass = m.s.dcl_pu240e_mass;
         res.tm_s_dcl_pu_mass = m.s.dcl_pu_mass;
         res.tm_s_dcl_minus_asy_pu_mass = m.s.dcl_minus_asy_pu_mass.v;
         res.tm_s_dcl_minus_asy_pu_mass_err = m.s.dcl_minus_asy_pu_mass.err;
         res.tm_s_dcl_minus_asy_pu_mass_pct = m.s.dcl_minus_asy_pu_mass_pct;
         StatePack(m.s.pass, res.tm_s_pass_fail);
         res.tm_a_res = m.methodParams.a;
         res.tm_b_res = m.methodParams.b;
         res.tm_known_eff_res = (byte)(m.methodParams.known_eff ? 1 : 0);
         res.tm_solve_eff_res = (byte)(m.methodParams.known_eff ? 1 : 0);
     }
     return res;
 }
コード例 #16
0
        /// <summary>
        /// Imprint a new measurement with as much information as possible from a results_rec.
        /// </summary>
        /// <param name="rec">The results_rec with the measurement details</param>
        /// <param name="meaId">Unique id for the measurement, from the results_rec fields</param>
        /// <param name="logger">logger handle</param>
        /// <returns>A new measurement</returns>
        public Measurement(INCCResults.results_rec rec, MeasId meaId, LMLoggers.LognLM logger)
        {
            HVCalibrationParameters hv = NCC.IntegrationHelpers.GetCurrentHVCalibrationParams(rec.det);
            MeasurementTuple        mt = new MeasurementTuple(new DetectorList(rec.det), rec.tests, rec.norm, rec.bkg, rec.iso, rec.acq, hv);

            this.mt     = mt;
            this.logger = logger;
            mid         = meaId;
            InitMisc();

            if (rec.det.ListMode)
            {
                AnalysisParams = NC.App.LMBD.CountingParameters(rec.det, applySRFromDetector: true);
                if (meaId.MeasOption.IsListMode()) // pure List Mode, not INCC5
                {
                    // for a list-mode-only measurement with a multiplicity analyzer the detector SR params must match at least one of the multiplicity analyzer SR params
                    NCC.IntegrationHelpers.ApplyVSRChangesToDefaultDetector(this);
                }
                else // it is an INCC5 analysis driven with LM data
                {
                    // prepare or identify an active CA entry with matching CA gatewidth and FA, with remaining SR params as the detector
                    AnalysisParams.PrepareMatchingVSR(rec.det.MultiplicityParams);
                }
            }
            else
            {
                // prepare analyzer params from detector SR params
                AnalysisParams = NC.App.LMBD.CountingParameters(rec.det, applySRFromDetector: false);
                if (!AnalysisParams.Exists(w => { return((w is Multiplicity) && (w as Multiplicity).Equals(rec.det.MultiplicityParams)); }))
                {
                    AnalysisParams.Add(rec.det.MultiplicityParams);
                }
            }

            // get the INCC5 analysis methods
            INCCAnalysisState = new INCCAnalysisState();
            INCCSelector    sel = new INCCSelector(rec.acq.detector_id, rec.acq.item_type);
            AnalysisMethods am;
            bool            found = NC.App.DB.DetectorMaterialAnalysisMethods.TryGetValue(sel, out am);

            if (found)
            {
                am.selector = sel; // gotta do this so that the equality operator is correct
                INCCAnalysisState.Methods = am;
            }
            else
            {
                INCCAnalysisState.Methods = new AnalysisMethods(sel);
            }
            InitializeContext(clearCounterResults: true);
            PrepareINCCResults();
            // a list mode measurement may not have a multiplicity analyzer at all, create on results, copying the current values
            if (CountingAnalysisResults.ContainsKey(rec.det.MultiplicityParams))
            {
                MultiplicityCountingRes mcr = (MultiplicityCountingRes)CountingAnalysisResults[rec.det.MultiplicityParams];
                if (rec.mcr.AB.Unset)
                {
                    SDTMultiplicityCalculator.SetAlphaBeta(rec.det.MultiplicityParams, rec.mcr); // works only if MaxBins is set
                }
                mcr.CopyFrom(rec.mcr);                                                           // copy the mcr results onto the first moskey entry
                // the same results are copied to the full results structure
                MeasOptionSelector mos    = new MeasOptionSelector(MeasOption, rec.det.MultiplicityParams);
                INCCResult         result = INCCAnalysisState.Lookup(mos);
                result.CopyFrom(rec.mcr);
            }

            Stratum = new Stratum(rec.st);             // the stratum from the results rec
        }
コード例 #17
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
        public unsafe bool BuildMeasurement(INCCTransferFile itf, int num)
        {
            bool overwrite = NC.App.AppContext.OverwriteImportedDefs;
            results_rec results = itf.results_rec_list[0];
            meas_id id;

            TransferUtils.Copy(results.meas_date, 0, id.meas_date, 0, INCC.DATE_TIME_LENGTH);
            TransferUtils.Copy(results.meas_time, 0, id.meas_time, 0, INCC.DATE_TIME_LENGTH);
            TransferUtils.Copy(results.filename, 0, id.filename, 0, INCC.FILE_NAME_LENGTH);
            TransferUtils.Copy(results.results_detector_id, 0, id.results_detector_id, 0, INCC.MAX_DETECTOR_ID_LENGTH);
            DateTime dt = INCC.DateTimeFrom(TransferUtils.str(id.meas_date, INCC.DATE_TIME_LENGTH), TransferUtils.str(id.meas_time, INCC.DATE_TIME_LENGTH));

            // do not use content from last BuildDetector call, instead look up the detector on the pre-existing list
            string detname = TransferUtils.str(id.results_detector_id, INCC.MAX_DETECTOR_ID_LENGTH);
            Detector det = NC.App.DB.Detectors.GetItByDetectorId(detname);
            if (det == null)
            {
                mlogger.TraceEvent(LogLevels.Error, 34087, "Unknown detector '{0}', not importing this measurement {1}", detname, dt.ToString("s"));
                return false;
            }

            meas = new Measurement((AssaySelector.MeasurementOption)results.meas_option, mlogger);

            // TODO: update detector details from this meas result, since there could be a difference
            meas.MeasurementId.MeasDateTime = dt;
            meas.MeasurementId.FileName = TransferUtils.str(id.filename, INCC.FILE_NAME_LENGTH);

            meas.Detectors.Add(det);  // in practice this is a list with one element, e.g. meas.Detector

            TestParameters t = new TestParameters();
            t.accSnglTestRateLimit = results.r_acc_sngl_test_rate_limit;
            t.accSnglTestPrecisionLimit = results.r_acc_sngl_test_precision_limit;
            t.accSnglTestOutlierLimit = results.r_acc_sngl_test_outlier_limit;
            t.outlierTestLimit = results.r_outlier_test_limit;
            t.bkgDoublesRateLimit = results.r_bkg_doubles_rate_limit;
            t.bkgTriplesRateLimit = results.r_bkg_triples_rate_limit;
            t.chiSquaredLimit = results.r_chisq_limit;
            t.maxNumFailures = results.r_max_num_failures;
            t.highVoltageTestLimit = results.r_high_voltage_test_limit;
            t.normalBackupAssayTestLimit = results.r_normal_backup_assay_test_lim;
            t.maxCyclesForOutlierTest = (uint)results.r_max_runs_for_outlier_test;
            t.checksum = (results.r_checksum_test == 0.0 ? false : true);
            t.accidentalsMethod = INCCAccidentalsMethod((int)results.results_accidentals_method);
            meas.Tests.Copy(t);

            NormParameters n = NC.App.DB.NormParameters.Get(detname);
            meas.Norm.Copy(n);
            BackgroundParameters b = NC.App.DB.BackgroundParameters.Get(detname);
            meas.Background.Copy(b);
            // DB write for these occurs at end of processing here

            // Isotopics handled in this block
            if (itf.isotopics_table.Count > 0)
            {
                string isoname = TransferUtils.str(results.item_isotopics_id, INCC.MAX_ISOTOPICS_ID_LENGTH);
                NCCTransfer.isotopics_rec isotopics = itf.isotopics_table[0];
                //bool first = true; // forgot why the code does this, to put the default in the map?
                // foreach (LMTransfer.isotopics_rec ir in itf.istopics_table)
                // {
                AnalysisDefs.Isotopics iso;
                //       if (first)
                iso = meas.Isotopics;
                //        else
                //            iso = new Isotopics();
                //         first = false;
                iso.am_date = INCC.DateFrom(TransferUtils.str(isotopics.am_date, INCC.DATE_TIME_LENGTH));
                iso.pu_date = INCC.DateFrom(TransferUtils.str(isotopics.pu_date, INCC.DATE_TIME_LENGTH));
                iso.id = TransferUtils.str(isotopics.isotopics_id, INCC.MAX_ISOTOPICS_ID_LENGTH);
                AnalysisDefs.Isotopics.SourceCode checksc = AnalysisDefs.Isotopics.SourceCode.OD;
                string check = TransferUtils.str(isotopics.isotopics_source_code, INCC.ISO_SOURCE_CODE_LENGTH);
                bool okparse = Enum.TryParse(check, true, out checksc);
                iso.source_code = checksc;
                iso.SetValueError(Isotope.am241, isotopics.am241, isotopics.am241_err);
                iso.SetValueError(Isotope.pu238, isotopics.pu238, isotopics.pu238_err);
                iso.SetValueError(Isotope.pu239, isotopics.pu239, isotopics.pu239_err);
                iso.SetValueError(Isotope.pu240, isotopics.pu240, isotopics.pu240_err);
                iso.SetValueError(Isotope.pu241, isotopics.pu241, isotopics.pu241_err);
                iso.SetValueError(Isotope.pu242, isotopics.pu242, isotopics.pu242_err);

                if (!NC.App.DB.Isotopics.Has(iso.id))
                {
                    NC.App.DB.Isotopics.GetList().Add(iso);
                    mlogger.TraceEvent(LogLevels.Info, 34021, "Identified new isotopics {0}", iso.id);
                }
                else
                {
                    if (overwrite)
                    {
                        NC.App.DB.Isotopics.Replace(iso);
                        mlogger.TraceEvent(LogLevels.Warning, 34022, "Replaced existing isotopics {0}", iso.id);
                    }
                    else
                    {
                        mlogger.TraceEvent(LogLevels.Warning, 34022, "Not replacing existing isotopics {0}", iso.id);
                    }
                }
                iso.modified = true;
            }

            AcquireParameters acq = meas.AcquireState;
            acq.detector_id = det.Id.DetectorId;
            acq.meas_detector_id = string.Copy(det.Id.DetectorId);  // probably incorrect usage, but differnce is ambiguous in INCC5
            acq.item_type = TransferUtils.str(results.results_item_type, INCC.MAX_ITEM_TYPE_LENGTH);
            acq.qc_tests = TransferUtils.ByteBool(results.results_qc_tests);
            acq.user_id = TransferUtils.str(results.user_id, INCC.CHAR_FIELD_LENGTH);
            acq.num_runs = results.total_number_runs;
            if (results.number_good_runs > 0)
                acq.run_count_time = results.total_good_count_time / results.number_good_runs;
            else
                acq.run_count_time = results.total_good_count_time; // should be 0.0 by default for this special case
            acq.MeasDateTime = meas.MeasurementId.MeasDateTime;
            acq.error_calc_method = INCCErrorCalculationTechnique(results.error_calc_method);
            acq.campaign_id = TransferUtils.str(results.results_campaign_id, INCC.MAX_CAMPAIGN_ID_LENGTH);
            if (string.IsNullOrEmpty(acq.campaign_id))
                acq.campaign_id = TransferUtils.str(results.results_inspection_number, INCC.MAX_CAMPAIGN_ID_LENGTH);
            acq.comment = TransferUtils.str(results.comment, INCC.MAX_COMMENT_LENGTH);//"Original file name " + meas.MeasurementId.FileName;
            string ending_comment_str = TransferUtils.str(results.ending_comment, INCC.MAX_COMMENT_LENGTH);
            acq.ending_comment = !string.IsNullOrEmpty(acq.ending_comment_str);

            acq.data_src = (ConstructedSource)results.data_source;
            acq.well_config = (WellConfiguration)results.well_config;
            acq.print = TransferUtils.ByteBool(results.results_print);

            mlogger.TraceEvent(LogLevels.Verbose, 34000, "Building {0} measurement {1} '{2},{3}' from {2}", meas.MeasOption.PrintName(), num, acq.detector_id, acq.item_type, itf.Path);

            if (itf.facility_table.Count > 0)
                meas.AcquireState.facility = new INCCDB.Descriptor(string.Copy(itf.facility_table[0].id), string.Copy(itf.facility_table[0].desc));
            if (itf.mba_table.Count > 0)
                meas.AcquireState.mba = new INCCDB.Descriptor(string.Copy(itf.mba_table[0].id), string.Copy(itf.mba_table[0].desc));
            if (itf.stratum_id_names_rec_table.Count > 0)
                meas.AcquireState.stratum_id = new INCCDB.Descriptor(string.Copy(itf.stratum_id_names_rec_table[0].id), string.Copy(itf.stratum_id_names_rec_table[0].desc));

            // stratum values
            meas.Stratum = new Stratum();
            meas.Stratum.bias_uncertainty = results.bias_uncertainty;
            meas.Stratum.random_uncertainty = results.random_uncertainty;
            meas.Stratum.relative_std_dev = results.relative_std_dev;
            meas.Stratum.systematic_uncertainty = results.systematic_uncertainty;

            INCCDB.Descriptor mtdesc = new INCCDB.Descriptor(string.Copy(acq.item_type), string.Empty);
            if (!NC.App.DB.Materials.Has(mtdesc) || overwrite)
            {
                NC.App.DB.Materials.Update(mtdesc);
            }

            // prepare norm parms, should be done with a prior pass with the detector file, then this code looks it up in the collection set at this point in the processing
            meas.Norm.currNormalizationConstant.v = results.normalization_constant;
            meas.Norm.currNormalizationConstant.err = results.normalization_constant_err;

            foreach (DescriptorPair dp in itf.facility_table)
            {
                INCCDB.Descriptor idesc = new INCCDB.Descriptor(string.Copy(dp.id), string.Copy(dp.desc));
                if (!NC.App.DB.Facilities.Has(idesc) || overwrite)
                {
                    idesc.modified = true;
                    NC.App.DB.Facilities.Update(idesc);
                }
            }
            foreach (DescriptorPair dp in itf.mba_table)
            {
                INCCDB.Descriptor idesc = new INCCDB.Descriptor(string.Copy(dp.id), string.Copy(dp.desc));
                if (!NC.App.DB.MBAs.Has(idesc) || overwrite)
                {
                    idesc.modified = true;
                    NC.App.DB.MBAs.Update(idesc);
                }
            }
            foreach (DescriptorPair dp in itf.stratum_id_names_rec_table)
            {
                INCCDB.Descriptor idesc = new INCCDB.Descriptor(string.Copy(dp.id), string.Copy(dp.desc));
                if (meas.Stratum != null)
                {
                   idesc.modified = true;
                   NC.App.DB.UpdateStratum(idesc, meas.Stratum);  // creates it
                   NC.App.DB.AssociateStratum(det, idesc, meas.Stratum); // associates it with the detector
                }
            }

            if (itf.item_id_table.Count > 0)  // devnote: there should be only one item entry
            {
                ItemId item = new ItemId();
                item.declaredMass = results.declared_mass;
                item.declaredUMass = results.declared_u_mass;
                item.length = results.length;
                item.IOCode = TransferUtils.str(results.io_code, INCC.IO_CODE_LENGTH);
                item.inventoryChangeCode = TransferUtils.str(results.inventory_change_code, INCC.INVENTORY_CHG_LENGTH);
                item.isotopics = TransferUtils.str(results.item_isotopics_id, INCC.MAX_ISOTOPICS_ID_LENGTH);
                item.stratum = TransferUtils.str(results.stratum_id, INCC.MAX_STRATUM_ID_LENGTH);
                item.item = TransferUtils.str(results.item_id, INCC.MAX_ITEM_ID_LENGTH);
                item.material = TransferUtils.str(results.results_item_type, INCC.MAX_ITEM_TYPE_LENGTH);
                //copy measurement dates to item
                item.pu_date = new DateTime(meas.Isotopics.pu_date.Ticks);
                item.am_date = new DateTime(meas.Isotopics.am_date.Ticks);
                item.modified = true;

                List<ItemId> list = NC.App.DB.ItemIds.GetList();
                bool flump = list.Exists(i => { return string.Compare(item.item, i.item, true) == 0; });
                if (flump && overwrite)
                {
                    list.Remove(item);
                    list.Add(item);
                }
                else
                    list.Add(item);

                // fill in the acquire record from the item id
                acq.ApplyItemId(item);

                meas.MeasurementId.Item = new ItemId(item);
            }

            meas.INCCAnalysisState = new INCCAnalysisState();

            INCCSelector sel = new INCCSelector(acq.detector_id, acq.item_type);
            AnalysisMethods am;
            bool found = NC.App.DB.DetectorMaterialAnalysisMethods.TryGetValue(sel, out am);
            if (found)
            {
                meas.INCCAnalysisState.Methods = am;
                meas.INCCAnalysisState.Methods.selector = sel;
            }
            else
            {
                mlogger.TraceEvent(LogLevels.Error, 34063, "No analysis methods for {0}, (calibration information is missing), creating placeholders", sel.ToString()); // devnote: can get missing paramters from the meas results for calib and verif below, so need to visit this condition after results processing below (newres.methodParams!) and reconstruct the calib parameters.
                meas.INCCAnalysisState.Methods = new AnalysisMethods(mlogger);
                meas.INCCAnalysisState.Methods.selector = sel;
            }
            // prepare analyzer params from sr params above
            meas.AnalysisParams = new AnalysisDefs.CountingAnalysisParameters();
            meas.AnalysisParams.Add(det.MultiplicityParams);

            mlogger.TraceEvent(LogLevels.Verbose, 34030, "Transferring the {0} cycles", itf.run_rec_list.Count);
            meas.InitializeContext();
            meas.PrepareINCCResults(); // prepares INCCResults objects
            ulong MaxBins = 0;
            foreach (run_rec r in itf.run_rec_list)
            {
                ulong x= AddToCycleList(r, det);
                if (x > MaxBins)
                    MaxBins = x;
            }
            for (int cf = 1; (itf.CFrun_rec_list != null) && (cf < itf.CFrun_rec_list.Length); cf++)
            {
                foreach (run_rec r in itf.CFrun_rec_list[cf])
                {
                    AddToCycleList(r, det, cf);
                }
            }

            // summarize the result in the result, if you know what I mean
            MultiplicityCountingRes mcr = (MultiplicityCountingRes)meas.CountingAnalysisResults[det.MultiplicityParams];
            for (int i = 0; i < 9; i++)
                mcr.covariance_matrix[i] = results.covariance_matrix[i];
            mcr.DeadtimeCorrectedRates.Singles.err = results.singles_err;
            mcr.DeadtimeCorrectedRates.Doubles.err = results.doubles_err;
            mcr.DeadtimeCorrectedRates.Triples.err = results.triples_err;
            mcr.DeadtimeCorrectedRates.Singles.v = results.singles;
            mcr.DeadtimeCorrectedRates.Doubles.v = results.doubles;
            mcr.DeadtimeCorrectedRates.Triples.v = results.triples;
            mcr.Scaler1Rate.v = results.scaler1;
            mcr.Scaler2Rate.v = results.scaler2;
            mcr.Scaler1Rate.err = results.scaler1_err;
            mcr.Scaler2Rate.err = results.scaler2_err;
            mcr.Scaler1.v = results.scaler1;
            mcr.Scaler2.v = results.scaler2;
            mcr.Scaler1.err = results.scaler1_err;
            mcr.Scaler2.err = results.scaler2_err;
            mcr.ASum = results.acc_sum;
            mcr.RASum = results.reals_plus_acc_sum;
            mcr.S1Sum = results.scaler1_sum;
            mcr.S2Sum = results.scaler2_sum;
            mcr.mass = results.declared_mass;
            mcr.FA = det.MultiplicityParams.FA;
            mcr.RAMult = TransferUtils.multarrayxfer(results.mult_reals_plus_acc_sum, INCC.MULTI_ARRAY_SIZE);
            mcr.NormedAMult = TransferUtils.multarrayxfer(results.mult_acc_sum, INCC.MULTI_ARRAY_SIZE);
            mcr.MaxBins = (ulong)Math.Max(mcr.RAMult.Length, mcr.NormedAMult.Length);
            mcr.MinBins = (ulong)Math.Min(mcr.RAMult.Length, mcr.NormedAMult.Length);
            mcr.RawDoublesRate.v = results.uncorrected_doubles;
            mcr.RawDoublesRate.err = results.uncorrected_doubles_err;
            mcr.singles_multi = results.singles_multi;
            mcr.doubles_multi = results.doubles_multi;
            mcr.triples_multi = results.triples_multi;

            INCCResult result;
            MeasOptionSelector mos = new MeasOptionSelector(meas.MeasOption, det.MultiplicityParams);
            result = meas.INCCAnalysisState.Lookup(mos);
            result.DeadtimeCorrectedRates.Singles.err = results.singles_err;
            result.DeadtimeCorrectedRates.Doubles.err = results.doubles_err;
            result.DeadtimeCorrectedRates.Triples.err = results.triples_err;
            result.DeadtimeCorrectedRates.Singles.v = results.singles;
            result.DeadtimeCorrectedRates.Doubles.v = results.doubles;
            result.DeadtimeCorrectedRates.Triples.v = results.triples;
            result.rates.RawRates.Scaler1s.v = results.scaler1;
            result.rates.RawRates.Scaler2s.v = results.scaler2;
            result.rates.RawRates.Scaler1s.err = results.scaler1_err;
            result.rates.RawRates.Scaler2s.err = results.scaler2_err;
            result.S1Sum = results.scaler1_sum;
            result.S2Sum = results.scaler2_sum;
            result.ASum = results.acc_sum;
            result.RASum = results.reals_plus_acc_sum;
            result.RAMult = TransferUtils.multarrayxfer(results.mult_reals_plus_acc_sum, INCC.MULTI_ARRAY_SIZE);
            result.NormedAMult = TransferUtils.multarrayxfer(results.mult_acc_sum, INCC.MULTI_ARRAY_SIZE);
            result.MaxBins = (ulong)Math.Max(result.RAMult.Length, result.NormedAMult.Length);
            result.MinBins = (ulong)Math.Min(result.RAMult.Length, result.NormedAMult.Length);
            mcr.RawDoublesRate.v = results.uncorrected_doubles;
            mcr.RawDoublesRate.err = results.uncorrected_doubles_err;
            result.singles_multi = results.singles_multi;
            result.doubles_multi = results.doubles_multi;
            result.triples_multi = results.triples_multi;

            // hack expansion of Normed mult array to same length as Acc mult array on each cycle to accomodate TheoreticalOutlier calc array length bug
            ExpandMaxBins(MaxBins, meas.Cycles, det.MultiplicityParams);
            Bloat(MaxBins, mcr);

            List<MeasurementMsg> msgs = meas.GetMessageList(det.MultiplicityParams);

            // move the error messages
            for (int i = 0; i < INCC.NUM_ERROR_MSG_CODES; i++)
            {
                int index = i * INCC.ERR_MSG_LENGTH;
                string e = TransferUtils.str(results.error_msg_codes + index, INCC.ERR_MSG_LENGTH);
                if (e.Length > 0)
                    meas.AddMessage(msgs, LogLevels.Error, 911, e, meas.MeasurementId.MeasDateTime);
            }
            // move the warning messages
            for (int i = 0; i < INCC.NUM_WARNING_MSG_CODES; i++)
            {
                int index = i * INCC.ERR_MSG_LENGTH;
                string w = TransferUtils.str(results.warning_msg_codes + index, INCC.ERR_MSG_LENGTH);
                if (w.Length > 0)
                    meas.AddMessage(msgs, LogLevels.Warning, 411, w, meas.MeasurementId.MeasDateTime);
            }

            #region results transfer
            INCCMethodResults imr;
            bool got = meas.INCCAnalysisResults.TryGetINCCResults(det.MultiplicityParams, out imr); // only ever this single mkey for INCC5-style transfer import, (thankfully)
            if (got)
                imr.primaryMethod = OldToNewMethodId(results.primary_analysis_method);
            // check these results against the meas.MeasOption expectation => seems to always be 1 - 1 with (opt, sr) -> results, and subresults only for verif and calib choice
            //         rates -> none,
            //         bkg -> bkg, norm -> bias, init src -> init src, prec ->  prec,
            //         calib -> calib, 1 or more INCC methods on the methods submap
            //         verif -> 1 or more INCC methods on the methods submap
            foreach (iresultsbase r in itf.method_results_list)
            {
                if (r is results_init_src_rec)
                {
                    mlogger.TraceEvent(LogLevels.Verbose, 34041, ("Transferring initial source results"));

                    results_init_src_rec oldres = (results_init_src_rec)r;

                    INCCResults.results_init_src_rec newres = (INCCResults.results_init_src_rec)
                    meas.INCCAnalysisState.Lookup(new MeasOptionSelector(meas.MeasOption, det.MultiplicityParams), typeof(INCCResults.results_init_src_rec));

                    newres.mode = OldToNewBiasTestId(oldres.init_src_mode);
                    newres.pass = TransferUtils.PassCheck(oldres.init_src_pass_fail);
                    newres.init_src_id = TransferUtils.str(oldres.init_src_id, INCC.SOURCE_ID_LENGTH);
                }
                else if (r is results_bias_rec)
                {
                    mlogger.TraceEvent(LogLevels.Verbose, 34042, ("Transferring normalization results"));

                    results_bias_rec oldres = (results_bias_rec)r;
                    INCCResults.results_bias_rec newres = (INCCResults.results_bias_rec)meas.INCCAnalysisState.Lookup(new MeasOptionSelector(meas.MeasOption, det.MultiplicityParams), typeof(INCCResults.results_bias_rec));

                    newres.pass = TransferUtils.PassCheck(oldres.bias_pass_fail);
                    newres.biasDblsRateExpect.v = oldres.bias_dbls_rate_expect;
                    newres.biasDblsRateExpectMeas.v = oldres.bias_dbls_rate_expect_meas;
                    newres.biasSnglsRateExpect.v = oldres.bias_sngls_rate_expect;
                    newres.biasSnglsRateExpectMeas.v = oldres.bias_sngls_rate_expect_meas;
                    newres.biasDblsRateExpect.err = oldres.bias_dbls_rate_expect_err;
                    newres.biasDblsRateExpectMeas.err = oldres.bias_dbls_rate_expect_meas_err;
                    newres.biasSnglsRateExpect.err = oldres.bias_sngls_rate_expect_err;
                    newres.biasSnglsRateExpectMeas.err = oldres.bias_sngls_rate_expect_meas_err;
                    newres.newNormConstant.v = oldres.new_norm_constant;
                    newres.newNormConstant.err = oldres.new_norm_constant_err;
                    newres.measPrecision = oldres.meas_precision;
                    newres.requiredMeasSeconds = oldres.required_meas_seconds;
                    newres.requiredPrecision = oldres.required_precision;
                    newres.mode = OldToNewBiasTestId(oldres.results_bias_mode);
                    newres.sourceId = TransferUtils.str(oldres.bias_source_id, INCC.SOURCE_ID_LENGTH);
                      // NEXT: for init src and bias, results norm values transferred to meas.norm

                }
                else if (r is results_precision_rec)
                {
                    mlogger.TraceEvent(LogLevels.Verbose, 34043, ("Transferring precision results"));

                    results_precision_rec oldres = (results_precision_rec)r;
                    INCCResults.results_precision_rec newres =
                        (INCCResults.results_precision_rec)meas.INCCAnalysisState.Lookup(new MeasOptionSelector(meas.MeasOption, det.MultiplicityParams), typeof(INCCResults.results_precision_rec));

                    newres.chiSqLowerLimit = oldres.chi_sq_lower_limit;
                    newres.chiSqUpperLimit = oldres.chi_sq_upper_limit;
                    newres.precChiSq = oldres.prec_chi_sq;
                    newres.precSampleVar = oldres.prec_sample_var;
                    newres.precTheoreticalVar = oldres.prec_theoretical_var;
                    newres.pass = TransferUtils.PassCheck(oldres.prec_pass_fail);
                }
                else
                {
                    if (r is results_cal_curve_rec)
                    {
                        // need to look up in existing map and see if it is there and then create and load it if not
                        mlogger.TraceEvent(LogLevels.Verbose, 34050, ("Transferring method results for " + r.GetType().ToString()));
                        results_cal_curve_rec oldres = (results_cal_curve_rec)r;
                        INCCMethodResults.results_cal_curve_rec newres =
                            (INCCMethodResults.results_cal_curve_rec)meas.INCCAnalysisResults.LookupMethodResults(det.MultiplicityParams, meas.INCCAnalysisState.Methods.selector, AnalysisMethod.CalibrationCurve, true);

                        newres.pu240e_mass = new Tuple(oldres.cc_pu240e_mass, oldres.cc_pu240e_mass_err);
                        newres.pu_mass = new Tuple(oldres.cc_pu_mass, oldres.cc_pu_mass_err);
                        newres.dcl_pu240e_mass = oldres.cc_dcl_pu240e_mass;
                        newres.dcl_pu_mass = oldres.cc_dcl_pu_mass;
                        newres.dcl_minus_asy_pu_mass = new Tuple(oldres.cc_dcl_minus_asy_pu_mass, oldres.cc_dcl_minus_asy_pu_mass_err);
                        newres.dcl_minus_asy_pu_mass_pct = oldres.cc_dcl_minus_asy_pu_mass_pct;
                        newres.pass = TransferUtils.PassCheck(oldres.cc_pass_fail);
                        newres.dcl_u_mass = oldres.cc_dcl_u_mass;
                        newres.length = oldres.cc_length;
                        newres.heavy_metal_content = oldres.cc_heavy_metal_content;
                        newres.heavy_metal_correction = oldres.cc_heavy_metal_correction;
                        newres.heavy_metal_corr_singles = new Tuple(oldres.cc_heavy_metal_corr_singles, oldres.cc_heavy_metal_corr_singles_err);
                        newres.heavy_metal_corr_doubles = new Tuple(oldres.cc_heavy_metal_corr_doubles, oldres.cc_heavy_metal_corr_doubles_err);
                        newres.methodParams.heavy_metal_corr_factor = oldres.cc_heavy_metal_corr_factor_res;
                        newres.methodParams.heavy_metal_reference = oldres.cc_heavy_metal_reference_res;
                        // newres.methodParams.cev.lower_mass_limit = oldres.cc_lower_mass_limit_res;
                        // newres.methodParams.cev.upper_mass_limit = oldres.cc_upper_mass_limit_res;
                        newres.methodParams.percent_u235 = oldres.cc_percent_u235_res;

                        newres.methodParams.cev.a = oldres.cc_a_res; newres.methodParams.cev.b = oldres.cc_b_res;
                        newres.methodParams.cev.c = oldres.cc_c_res; newres.methodParams.cev.d = oldres.cc_d_res;
                        newres.methodParams.cev.var_a = oldres.cc_var_a_res; newres.methodParams.cev.var_b = oldres.cc_var_b_res;
                        newres.methodParams.cev.var_c = oldres.cc_var_c_res; newres.methodParams.cev.var_d = oldres.cc_var_d_res;
                        newres.methodParams.cev.setcovar(Coeff.a,Coeff.b,oldres.cc_covar_ab_res);
                        newres.methodParams.cev._covar[0, 2] = oldres.cc_covar_ac_res;
                        newres.methodParams.cev._covar[0, 3] = oldres.cc_covar_ad_res;
                        newres.methodParams.cev._covar[1, 2] = oldres.cc_covar_bc_res;
                        newres.methodParams.cev._covar[1, 3] = oldres.cc_covar_bd_res;
                        newres.methodParams.cev._covar[2, 3] = oldres.cc_covar_cd_res;
                        newres.methodParams.cev.cal_curve_equation = (INCCAnalysisParams.CurveEquation)oldres.cc_cal_curve_equation;
                        newres.methodParams.CalCurveType = (INCCAnalysisParams.CalCurveType)oldres.cc_cal_curve_type_res;
                        newres.methodParams.cev.sigma_x = oldres.cc_sigma_x_res;
                    }
                    else if (r is results_known_alpha_rec)
                    {
                        //  need to look up in existing map and see if it is there and then create and load it if not
                        mlogger.TraceEvent(LogLevels.Verbose, 34051, ("Transferring method results for " + r.GetType().ToString()));
                        results_known_alpha_rec oldres = (results_known_alpha_rec)r;
                        INCCMethodResults.results_known_alpha_rec newres =
                            (INCCMethodResults.results_known_alpha_rec)meas.INCCAnalysisResults.LookupMethodResults(det.MultiplicityParams, meas.INCCAnalysisState.Methods.selector, AnalysisMethod.KnownA, true);
                        newres.corr_doubles.v = oldres.ka_corr_doubles;
                        newres.corr_doubles.err = oldres.ka_corr_doubles_err;
                        newres.mult = oldres.ka_mult;
                        newres.alphaK = oldres.ka_alpha;
                        newres.mult_corr_doubles = new Tuple(oldres.ka_mult_corr_doubles, oldres.ka_mult_corr_doubles_err);
                        newres.pu240e_mass = new Tuple(oldres.ka_pu240e_mass, oldres.ka_pu240e_mass_err);
                        newres.pu_mass = new Tuple(oldres.ka_pu_mass, oldres.ka_pu_mass_err);
                        newres.dcl_pu240e_mass = oldres.ka_dcl_pu240e_mass;
                        newres.dcl_pu_mass = oldres.ka_dcl_pu_mass;
                        newres.dcl_minus_asy_pu_mass = new Tuple(oldres.ka_dcl_minus_asy_pu_mass, oldres.ka_dcl_minus_asy_pu_mass_err);
                        newres.dcl_minus_asy_pu_mass_pct = oldres.ka_dcl_minus_asy_pu_mass_pct;
                        newres.pass = TransferUtils.PassCheck(oldres.ka_pass_fail);
                        newres.dcl_u_mass = oldres.ka_dcl_u_mass;
                        newres.length = oldres.ka_length;
                        newres.heavy_metal_content = oldres.ka_heavy_metal_content;
                        newres.heavy_metal_correction = oldres.ka_heavy_metal_correction;
                        newres.corr_singles = new Tuple(oldres.ka_corr_singles, oldres.ka_corr_singles_err);
                        newres.corr_doubles = new Tuple(oldres.ka_corr_doubles, oldres.ka_corr_doubles_err);
                        newres.corr_factor = oldres.ka_corr_factor;
                        newres.dry_alpha_or_mult_dbls = oldres.ka_dry_alpha_or_mult_dbls;
                        newres.upper_corr_factor_limit = oldres.ka_upper_corr_factor_limit_res;
                        newres.lower_corr_factor_limit = oldres.ka_lower_corr_factor_limit_res;

                        newres.methodParams = new INCCAnalysisParams.known_alpha_rec();
                        newres.methodParams.alpha_wt = oldres.ka_alpha_wt_res;
                        newres.methodParams.heavy_metal_corr_factor = oldres.ka_heavy_metal_corr_factor_res;
                        newres.methodParams.heavy_metal_reference = oldres.ka_heavy_metal_reference_res;
                        newres.methodParams.k = oldres.ka_k_res;
                        newres.methodParams.known_alpha_type = (INCCAnalysisParams.KnownAlphaVariant)oldres.ka_known_alpha_type_res;
                        newres.methodParams.lower_corr_factor_limit = oldres.ka_lower_corr_factor_limit_res;
                        newres.methodParams.upper_corr_factor_limit = oldres.ka_upper_corr_factor_limit_res;
                        newres.methodParams.rho_zero = oldres.ka_rho_zero_res;

                        newres.methodParams.ring_ratio.cal_curve_equation = (INCCAnalysisParams.CurveEquation)oldres.ka_ring_ratio_equation_res;
                        newres.methodParams.ring_ratio.a = oldres.ka_ring_ratio_a_res;
                        newres.methodParams.ring_ratio.b = oldres.ka_ring_ratio_b_res;
                        newres.methodParams.ring_ratio.c = oldres.ka_ring_ratio_c_res;
                        newres.methodParams.ring_ratio.d = oldres.ka_ring_ratio_d_res;

                        newres.methodParams.cev.a = oldres.ka_a_res;
                        newres.methodParams.cev.b = oldres.ka_b_res;
                        newres.methodParams.cev.var_a = oldres.ka_var_a_res;
                        newres.methodParams.cev.var_b= oldres.ka_var_b_res;
                        newres.methodParams.cev.sigma_x = oldres.ka_sigma_x_res;
                        newres.methodParams.cev.setcovar(Coeff.a, Coeff.b, oldres.ka_covar_ab_res);
                        newres.methodParams.cev.lower_mass_limit = oldres.ka_lower_corr_factor_limit_res;
                        newres.methodParams.cev.upper_mass_limit = oldres.ka_upper_corr_factor_limit_res;
                    }
                    else if (r is results_multiplicity_rec)
                    {
                        mlogger.TraceEvent(LogLevels.Verbose, 34052, ("Transferring method results for " + r.GetType().ToString()));
                        results_multiplicity_rec oldres = (results_multiplicity_rec)r;
                        INCCMethodResults.results_multiplicity_rec newres =
                            (INCCMethodResults.results_multiplicity_rec)meas.INCCAnalysisResults.LookupMethodResults(det.MultiplicityParams, meas.INCCAnalysisState.Methods.selector, AnalysisMethod.Multiplicity, true);

                        newres.solve_efficiency_choice = (INCCAnalysisParams.MultChoice)oldres.mul_solve_efficiency_res;
                        newres.pass = TransferUtils.PassCheck(oldres.mul_pass_fail);
                        newres.efficiencyComputed.v = oldres.mul_efficiency; newres.efficiencyComputed.err = oldres.mul_efficiency_err;
                        newres.mult.v = oldres.mul_mult; newres.mult.err = oldres.mul_mult_err;
                        newres.alphaK.v = oldres.mul_alpha; newres.alphaK.err = oldres.mul_alpha_err;
                        newres.corr_factor.v = oldres.mul_corr_factor; newres.corr_factor.err = oldres.mul_corr_factor_err;
                        newres.pu240e_mass.v = oldres.mul_pu240e_mass; newres.pu240e_mass.err = oldres.mul_pu240e_mass_err;
                        newres.pu_mass.v = oldres.mul_pu_mass; newres.pu_mass.err = oldres.mul_pu_mass_err;
                        newres.dcl_minus_asy_pu_mass.v = oldres.mul_dcl_minus_asy_pu_mass; newres.dcl_minus_asy_pu_mass.err = oldres.mul_dcl_minus_asy_pu_mass_err;
                        newres.dcl_pu240e_mass = oldres.mul_dcl_pu240e_mass;
                        newres.dcl_pu_mass = oldres.mul_dcl_pu_mass;
                        newres.dcl_minus_asy_pu_mass_pct = oldres.mul_dcl_minus_asy_pu_mass_pct;

                        newres.methodParams = new INCCAnalysisParams.multiplicity_rec();
                        newres.methodParams.sf_rate = oldres.mul_sf_rate_res;
                        newres.methodParams.vs1 = oldres.mul_vs1_res;
                        newres.methodParams.vs2 = oldres.mul_vs2_res;
                        newres.methodParams.vs3 = oldres.mul_vs3_res;
                        newres.methodParams.vi1 = oldres.mul_vi1_res;
                        newres.methodParams.vi2 = oldres.mul_vi2_res;
                        newres.methodParams.vi3 = oldres.mul_vi3_res;
                        newres.methodParams.a = oldres.mul_a_res;
                        newres.methodParams.b = oldres.mul_b_res;
                        newres.methodParams.c = oldres.mul_b_res;
                        newres.methodParams.sigma_x = oldres.mul_sigma_x_res;
                        newres.methodParams.alpha_weight = oldres.mul_alpha_weight_res;
                        newres.methodParams.multEffCorFactor = oldres.mul_corr_factor;
                    }
                    else if (r is results_truncated_mult_rec)
                    {
                        mlogger.TraceEvent(LogLevels.Verbose, 34053, ("Transferring method results for " + r.GetType().ToString()));
                        results_truncated_mult_rec oldres = (results_truncated_mult_rec)r;
                        INCCMethodResults.results_truncated_mult_rec newres =
                            (INCCMethodResults.results_truncated_mult_rec)meas.INCCAnalysisResults.LookupMethodResults(det.MultiplicityParams, meas.INCCAnalysisState.Methods.selector, AnalysisMethod.TruncatedMultiplicity, true);
                        newres.k.pass = TransferUtils.PassCheck(oldres.tm_k_pass_fail);
                        newres.bkg.Singles.v = oldres.tm_bkg_singles;
                        newres.bkg.Singles.err = oldres.tm_bkg_singles_err;
                        newres.bkg.Zeros.v = oldres.tm_bkg_zeros;
                        newres.bkg.Zeros.err = oldres.tm_bkg_zeros_err;
                        newres.bkg.Ones.v = oldres.tm_bkg_ones;
                        newres.bkg.Ones.err = oldres.tm_bkg_ones_err;
                        newres.bkg.Twos.v = oldres.tm_bkg_twos;
                        newres.bkg.Twos.err = oldres.tm_bkg_twos_err;
                        newres.net.Singles.v = oldres.tm_net_singles;
                        newres.net.Singles.err = oldres.tm_net_singles_err;
                        newres.net.Zeros.v = oldres.tm_net_zeros;
                        newres.net.Zeros.err = oldres.tm_net_zeros_err;
                        newres.net.Ones.v = oldres.tm_net_ones;
                        newres.net.Ones.err = oldres.tm_net_ones_err;
                        newres.net.Twos.v = oldres.tm_net_twos;
                        newres.net.Twos.err = oldres.tm_net_twos_err;
                        newres.k.alpha.v = oldres.tm_k_alpha;
                        newres.k.alpha.err = oldres.tm_k_alpha_err;
                        newres.k.pu_mass.v = oldres.tm_k_pu_mass;
                        newres.k.pu_mass.err = oldres.tm_k_pu_mass_err;
                        newres.k.pu240e_mass.v = oldres.tm_k_pu240e_mass;
                        newres.k.pu240e_mass.err = oldres.tm_k_pu240e_mass_err;
                        newres.k.dcl_minus_asy_pu_mass.v = oldres.tm_k_dcl_minus_asy_pu_mass;
                        newres.k.dcl_minus_asy_pu_mass.err = oldres.tm_k_dcl_minus_asy_pu_mass_err;
                        newres.s.alpha.v = oldres.tm_s_alpha;
                        newres.s.alpha.err = oldres.tm_s_alpha_err;
                        newres.s.pu_mass.v = oldres.tm_s_pu_mass;
                        newres.s.pu_mass.err = oldres.tm_s_pu_mass_err;
                        newres.s.pu240e_mass.v = oldres.tm_s_pu240e_mass;
                        newres.s.pu240e_mass.err = oldres.tm_s_pu240e_mass_err;
                        newres.s.dcl_minus_asy_pu_mass.v = oldres.tm_s_dcl_minus_asy_pu_mass;
                        newres.s.dcl_minus_asy_pu_mass.err = oldres.tm_s_dcl_minus_asy_pu_mass_err;
                        newres.methodParams.a = oldres.tm_a_res;
                        newres.methodParams.b = oldres.tm_b_res;
                        newres.methodParams.known_eff = (oldres.tm_known_eff_res == 0 ? false : true);
                        newres.methodParams.solve_eff = (oldres.tm_solve_eff_res == 0 ? false : true);
                    }
                    else if (r is results_known_m_rec)
                    {
                        // dev note: untested
                        mlogger.TraceEvent(LogLevels.Verbose, 34054, ("Transferring method results for " + r.GetType().ToString()));
                        results_known_m_rec oldres = (results_known_m_rec)r;
                        INCCMethodResults.results_known_m_rec newres =
                            (INCCMethodResults.results_known_m_rec)meas.INCCAnalysisResults.LookupMethodResults(det.MultiplicityParams, meas.INCCAnalysisState.Methods.selector, AnalysisMethod.KnownM, true);
                        newres.pu_mass = new Tuple(oldres.km_pu_mass, oldres.km_pu_mass_err);
                        newres.pu240e_mass = new Tuple(oldres.km_pu240e_mass, oldres.km_pu240e_mass);
                        newres.alpha = oldres.km_alpha;
                        newres.mult = oldres.km_mult;
                        newres.dcl_minus_asy_pu_mass = new Tuple(oldres.km_dcl_minus_asy_pu_mass, oldres.km_dcl_minus_asy_pu_mass_err);
                        newres.pu239e_mass = oldres.km_pu240e_mass;
                        newres.dcl_pu240e_mass = oldres.km_dcl_pu240e_mass;
                        newres.dcl_pu_mass = oldres.km_dcl_pu_mass;
                        newres.dcl_minus_asy_pu_mass_pct = oldres.km_dcl_minus_asy_pu_mass_pct;
                        newres.pass = TransferUtils.PassCheck(oldres.km_pass_fail);
                        newres.methodParams.b = oldres.km_b_res;
                        newres.methodParams.c = oldres.km_c_res;
                        newres.methodParams.sf_rate = oldres.km_sf_rate_res;
                        newres.methodParams.sigma_x = oldres.km_sigma_x_res;
                        newres.methodParams.vs1 = oldres.km_vs1_res;
                        newres.methodParams.vi1 = oldres.km_vi1_res;
                        newres.methodParams.vs2 = oldres.km_vs2_res;
                        newres.methodParams.vi2 = oldres.km_vi2_res;
                    }
                    else if (r is results_add_a_source_rec)
                    {
                        // dev note: untested
                        mlogger.TraceEvent(LogLevels.Verbose, 34055, ("Transferring method results for " + r.GetType().ToString()));
                        results_add_a_source_rec oldres = (results_add_a_source_rec)r;
                        INCCMethodResults.results_add_a_source_rec newres =
                            (INCCMethodResults.results_add_a_source_rec)meas.INCCAnalysisResults.LookupMethodResults(det.MultiplicityParams, meas.INCCAnalysisState.Methods.selector, AnalysisMethod.KnownM, true);
                        newres.pu_mass = new Tuple(oldres.ad_pu_mass, oldres.ad_pu_mass_err);
                        newres.pu240e_mass = new Tuple(oldres.ad_pu240e_mass, oldres.ad_pu240e_mass);
                        newres.dcl_minus_asy_pu_mass = new Tuple(oldres.ad_dcl_minus_asy_pu_mass, oldres.ad_dcl_minus_asy_pu_mass_err);
                        newres.dcl_pu240e_mass = oldres.ad_dcl_pu240e_mass;
                        newres.dcl_pu_mass = oldres.ad_dcl_pu_mass;
                        newres.dcl_minus_asy_pu_mass_pct = oldres.ad_dcl_minus_asy_pu_mass_pct;
                        newres.pass = TransferUtils.PassCheck(oldres.ad_pass_fail);

                        newres.dzero_cf252_doubles = oldres.ad_dzero_cf252_doubles;
                        newres.sample_avg_cf252_doubles.v = oldres.ad_sample_avg_cf252_doubles;
                        newres.sample_avg_cf252_doubles.err = oldres.ad_sample_avg_cf252_doubles_err;
                        newres.corr_doubles.v = oldres.ad_corr_doubles;
                        newres.corr_doubles.err = oldres.ad_corr_doubles_err;
                        newres.delta.v = oldres.ad_delta;
                        newres.delta.err = oldres.ad_delta_err;
                        newres.corr_factor.v = oldres.ad_corr_factor;
                        newres.corr_factor.err = oldres.ad_corr_factor_err;
                        newres.sample_cf252_ratio = TransferUtils.Copy(oldres.ad_sample_cf252_ratio, INCC.MAX_ADDASRC_POSITIONS);
                        newres.sample_cf252_doubles = Tuple.MakeArray(
                                vals: TransferUtils.Copy(oldres.ad_sample_cf252_doubles, INCC.MAX_ADDASRC_POSITIONS),
                                errs: TransferUtils.Copy(oldres.ad_sample_cf252_doubles_err, INCC.MAX_ADDASRC_POSITIONS));
                        newres.tm_doubles_bkg.v = oldres.ad_tm_doubles_bkg;
                        newres.tm_uncorr_doubles.v = oldres.ad_tm_uncorr_doubles;
                        newres.tm_corr_doubles.v = oldres.ad_corr_doubles;
                        newres.tm_doubles_bkg.err = oldres.ad_tm_doubles_bkg_err;
                        newres.tm_uncorr_doubles.err = oldres.ad_tm_uncorr_doubles_err;
                        newres.tm_corr_doubles.err = oldres.ad_corr_doubles_err;
                        newres.methodParams.cev.a = oldres.ad_a_res; newres.methodParams.cev.b = oldres.ad_b_res;
                        newres.methodParams.cev.c = oldres.ad_c_res; newres.methodParams.cev.d = oldres.ad_d_res;
                        newres.methodParams.cev.var_a = oldres.ad_var_a_res; newres.methodParams.cev.var_b = oldres.ad_var_b_res;
                        newres.methodParams.cev.var_c = oldres.ad_var_c_res; newres.methodParams.cev.var_d = oldres.ad_var_d_res;
                        newres.methodParams.cev.setcovar(Coeff.a, Coeff.b, oldres.ad_covar_ab_res);
                        newres.methodParams.cev._covar[0, 2] = oldres.ad_covar_ac_res;
                        newres.methodParams.cev._covar[0, 3] = oldres.ad_covar_ad_res;
                        newres.methodParams.cev._covar[1, 2] = oldres.ad_covar_bc_res;
                        newres.methodParams.cev._covar[1, 3] = oldres.ad_covar_bd_res;
                        newres.methodParams.cev._covar[2, 3] = oldres.ad_covar_cd_res;
                        newres.methodParams.cev.cal_curve_equation = (INCCAnalysisParams.CurveEquation)oldres.ad_add_a_source_equation;
                        newres.methodParams.cev.sigma_x = oldres.ad_sigma_x_res;

                        newres.methodParams.cf.a = oldres.ad_cf_a_res; newres.methodParams.cf.b = oldres.ad_cf_b_res;
                        newres.methodParams.cf.c = oldres.ad_cf_c_res; newres.methodParams.cf.d = oldres.ad_cf_d_res;
                        newres.methodParams.dzero_avg = oldres.ad_dzero_avg_res;
                        newres.methodParams.num_runs = oldres.ad_num_runs_res;
                        newres.methodParams.tm_dbls_rate_upper_limit = oldres.ad_tm_dbls_rate_upper_limit_res;
                        newres.methodParams.tm_weighting_factor = oldres.ad_tm_weighting_factor_res;
                        newres.methodParams.use_truncated_mult = (oldres.ad_use_truncated_mult_res == 0 ? false : true);
                        newres.methodParams.dzero_ref_date = INCC.DateFrom(TransferUtils.str(oldres.ad_dzero_ref_date_res, INCC.DATE_TIME_LENGTH));
                        newres.methodParams.position_dzero = TransferUtils.Copy(oldres.ad_position_dzero_res, INCC.MAX_ADDASRC_POSITIONS);
                        // devnote: the original methodParams dcl_mass, doubles, min, max not preserved in INCC5 aas result rec
                    }
                    else if (r is results_curium_ratio_rec)
                    {
                        // dev note: untested
                        mlogger.TraceEvent(LogLevels.Verbose, 34056, ("Transferring method results for " + r.GetType().ToString()));
                        results_curium_ratio_rec oldres = (results_curium_ratio_rec)r;
                        INCCMethodResults.results_curium_ratio_rec newres = (INCCMethodResults.results_curium_ratio_rec)
                        meas.INCCAnalysisResults.LookupMethodResults(det.MultiplicityParams, meas.INCCAnalysisState.Methods.selector, AnalysisMethod.CuriumRatio, true);
                        newres.pu.pu240e_mass = new Tuple(oldres.cr_pu240e_mass, oldres.cr_pu240e_mass_err);
                        newres.pu.mass = new Tuple(oldres.cr_pu_mass, oldres.cr_pu_mass_err);
                        newres.pu.dcl_mass = oldres.cr_dcl_pu_mass;
                        newres.pu.dcl_minus_asy_mass = new Tuple(oldres.cr_dcl_minus_asy_pu_mass, oldres.cr_dcl_minus_asy_pu_mass_err);
                        newres.pu.dcl_minus_asy_mass_pct = oldres.cr_dcl_minus_asy_pu_mass_pct;
                        newres.pu.dcl_minus_asy_pu_mass = new Tuple(oldres.cr_dcl_minus_asy_pu_mass, oldres.cr_dcl_minus_asy_pu_mass_err);
                        newres.pu.dcl_minus_asy_pu_mass_pct = oldres.cr_dcl_minus_asy_pu_mass_pct;
                        newres.pu.pass = TransferUtils.PassCheck(oldres.cr_pu_pass_fail);

                        newres.u.mass = new Tuple(oldres.cr_u_mass, oldres.cr_u_mass_err);
                        newres.u.dcl_mass = oldres.cr_dcl_u_mass_res;
                        newres.u.dcl_minus_asy_mass = new Tuple(oldres.cr_dcl_minus_asy_u_mass, oldres.cr_dcl_minus_asy_u_mass_err);
                        newres.u.dcl_minus_asy_mass_pct = oldres.cr_dcl_minus_asy_u_mass_pct;
                        newres.u.pass = TransferUtils.PassCheck(oldres.cr_u_pass_fail);

                        newres.u235.mass = new Tuple(oldres.cr_u235_mass, oldres.cr_u235_mass_err);
                        newres.u235.dcl_mass = oldres.cr_dcl_u235_mass_res;
                        newres.u235.dcl_minus_asy_mass = new Tuple(oldres.cr_dcl_minus_asy_u235_mass, oldres.cr_dcl_minus_asy_u235_mass_err);
                        newres.u235.dcl_minus_asy_mass_pct = oldres.cr_dcl_minus_asy_u235_mass_pct;

                        newres.cm_mass = new Tuple(oldres.cr_cm_mass, oldres.cr_cm_mass_err);
                        newres.methodParams2.cm_pu_ratio = new Tuple(oldres.cr_cm_pu_ratio, oldres.cr_cm_pu_ratio_err);
                        newres.cm_pu_ratio_decay_corr = new Tuple(oldres.cr_cm_pu_ratio_decay_corr, oldres.cr_cm_pu_ratio_decay_corr_err);
                        newres.methodParams2.cm_pu_ratio_date = INCC.DateFrom(TransferUtils.str(oldres.cr_cm_pu_ratio_date, INCC.DATE_TIME_LENGTH));
                        newres.cm_u_ratio_decay_corr = new Tuple(oldres.cr_cm_u_ratio_decay_corr, oldres.cr_cm_u_ratio_decay_corr_err);
                        newres.methodParams2.cm_u_ratio_date = INCC.DateFrom(TransferUtils.str(oldres.cr_cm_pu_ratio_date, INCC.DATE_TIME_LENGTH));
                        newres.methodParams2.pu_half_life = oldres.cr_pu_half_life;

                        newres.methodParams2.cm_id_label = TransferUtils.str(oldres.cr_cm_id_label, INCC.MAX_ITEM_ID_LENGTH);
                        newres.methodParams2.cm_id = TransferUtils.str(oldres.cr_cm_id, INCC.MAX_ITEM_ID_LENGTH);
                        newres.methodParams2.cm_input_batch_id = TransferUtils.str(oldres.cr_cm_input_batch_id, INCC.MAX_ITEM_ID_LENGTH);

                        newres.methodParams.cev.a = oldres.cr_a_res; newres.methodParams.cev.b = oldres.cr_b_res;
                        newres.methodParams.cev.c = oldres.cr_c_res; newres.methodParams.cev.d = oldres.cr_d_res;
                        newres.methodParams.cev.var_a = oldres.cr_var_a_res; newres.methodParams.cev.var_b = oldres.cr_var_b_res;
                        newres.methodParams.cev.var_c = oldres.cr_var_c_res; newres.methodParams.cev.var_d = oldres.cr_var_d_res;
                        newres.methodParams.cev.setcovar(Coeff.a,Coeff.b,oldres.cr_covar_ab_res);
                        newres.methodParams.cev._covar[0, 2] = oldres.cr_covar_ac_res;
                        newres.methodParams.cev._covar[0, 3] = oldres.cr_covar_ad_res;
                        newres.methodParams.cev._covar[1, 2] = oldres.cr_covar_bc_res;
                        newres.methodParams.cev._covar[1, 3] = oldres.cr_covar_bd_res;
                        newres.methodParams.cev._covar[2, 3] = oldres.cr_covar_cd_res;
                        newres.methodParams.cev.cal_curve_equation = (INCCAnalysisParams.CurveEquation)oldres.cr_curium_ratio_equation;
                        newres.methodParams.cev.sigma_x = oldres.cr_sigma_x_res;
                        newres.methodParams.curium_ratio_type = OldToNewCRVariants(oldres.curium_ratio_type_res);
                    }
                    else if (r is results_active_passive_rec) // NEXT: confusion with combined, it's the same as Active internally? expand and study
                    {
                        mlogger.TraceEvent(LogLevels.Verbose, 34057, ("Transferring method results for " + r.GetType().ToString()));
                        results_active_passive_rec oldres = (results_active_passive_rec)r;
                        INCCMethodResults.results_active_passive_rec newres =
                            (INCCMethodResults.results_active_passive_rec)meas.INCCAnalysisResults.LookupMethodResults(det.MultiplicityParams, meas.INCCAnalysisState.Methods.selector, AnalysisMethod.ActivePassive, true);

                        newres.pass = TransferUtils.PassCheck(oldres.ap_pass_fail);
                        newres.k.v = oldres.ap_k; newres.k.err = oldres.ap_k_err;
                        newres.k0.v = oldres.ap_k0;
                        newres.k1.v = oldres.ap_k1; newres.k1.err = oldres.ap_k1_err;
                        newres.u235_mass.v = oldres.ap_u235_mass; newres.u235_mass.err = oldres.ap_u235_mass_err;
                        newres.dcl_minus_asy_u235_mass.v = oldres.ap_dcl_minus_asy_u235_mass; newres.dcl_minus_asy_u235_mass.err = oldres.ap_dcl_minus_asy_u235_mass_err;

                        newres.dcl_u235_mass = oldres.ap_dcl_u235_mass;
                        newres.dcl_minus_asy_u235_mass_pct = oldres.ap_dcl_minus_asy_u235_mass_pct;

                        newres.methodParams = new INCCAnalysisParams.active_passive_rec();
                        newres.methodParams.cev.a = oldres.ap_a_res; newres.methodParams.cev.b = oldres.ap_b_res;
                        newres.methodParams.cev.c = oldres.ap_c_res; newres.methodParams.cev.d = oldres.ap_d_res;
                        newres.methodParams.cev.var_a = oldres.ap_var_a_res; newres.methodParams.cev.var_b = oldres.ap_var_b_res;
                        newres.methodParams.cev.var_c = oldres.ap_var_c_res; newres.methodParams.cev.var_d = oldres.ap_var_d_res;
                        newres.methodParams.cev.setcovar(Coeff.a, Coeff.b, oldres.ap_covar_ab_res);
                        newres.methodParams.cev._covar[0, 2] = oldres.ap_covar_ac_res;
                        newres.methodParams.cev._covar[0, 3] = oldres.ap_covar_ad_res;
                        newres.methodParams.cev._covar[1, 2] = oldres.ap_covar_bc_res;
                        newres.methodParams.cev._covar[1, 3] = oldres.ap_covar_bd_res;
                        newres.methodParams.cev._covar[2, 3] = oldres.ap_covar_cd_res;
                        newres.methodParams.cev.cal_curve_equation = (INCCAnalysisParams.CurveEquation)oldres.ap_active_passive_equation;
                        newres.methodParams.cev.sigma_x = oldres.ap_sigma_x_res;
                        newres.delta_doubles.v = oldres.ap_delta_doubles;
                        newres.delta_doubles.err = oldres.ap_delta_doubles_err;
                    }
                    else if (r is results_active_rec)
                    {
                        mlogger.TraceEvent(LogLevels.Verbose, 34058, ("Transferring method results for " + r.GetType().ToString()));
                        results_active_rec oldres = (results_active_rec)r;
                        INCCMethodResults.results_active_rec newres =
                            (INCCMethodResults.results_active_rec)meas.INCCAnalysisResults.LookupMethodResults(det.MultiplicityParams, meas.INCCAnalysisState.Methods.selector, AnalysisMethod.Active, true);
                        newres.pass = TransferUtils.PassCheck(oldres.act_pass_fail);
                        newres.k.v = oldres.act_k; newres.k.err = oldres.act_k_err;
                        newres.k0.v = oldres.act_k0;
                        newres.k1.v = oldres.act_k1; newres.k1.err = oldres.act_k1_err;
                        newres.u235_mass.v = oldres.act_u235_mass; newres.u235_mass.err = oldres.act_u235_mass_err;
                        newres.dcl_minus_asy_u235_mass.v = oldres.act_dcl_minus_asy_u235_mass; newres.dcl_minus_asy_u235_mass.err = oldres.act_dcl_minus_asy_u235_mass_err;

                        newres.dcl_u235_mass = oldres.act_dcl_u235_mass;
                        newres.dcl_minus_asy_u235_mass_pct = oldres.act_dcl_minus_asy_u235_mass_pct;

                        newres.methodParams = new INCCAnalysisParams.active_rec();
                        newres.methodParams.cev.a = oldres.act_a_res; newres.methodParams.cev.b = oldres.act_b_res;
                        newres.methodParams.cev.c = oldres.act_c_res; newres.methodParams.cev.d = oldres.act_d_res;
                        newres.methodParams.cev.var_a = oldres.act_var_a_res; newres.methodParams.cev.var_b = oldres.act_var_b_res;
                        newres.methodParams.cev.var_c = oldres.act_var_c_res; newres.methodParams.cev.var_d = oldres.act_var_d_res;
                        newres.methodParams.cev.setcovar(Coeff.a,Coeff.b,oldres.act_covar_ab_res);
                        newres.methodParams.cev._covar[0, 2] = oldres.act_covar_ac_res;
                        newres.methodParams.cev._covar[0, 3] = oldres.act_covar_ad_res;
                        newres.methodParams.cev._covar[1, 2] = oldres.act_covar_bc_res;
                        newres.methodParams.cev._covar[1, 3] = oldres.act_covar_bd_res;
                        newres.methodParams.cev._covar[2, 3] = oldres.act_covar_cd_res;
                        newres.methodParams.cev.cal_curve_equation = (INCCAnalysisParams.CurveEquation)oldres.act_active_equation;
                        newres.methodParams.cev.sigma_x = oldres.act_sigma_x_res;
                    }
                    else if (r is results_active_mult_rec)
                    {
                        mlogger.TraceEvent(LogLevels.Verbose, 34059, ("Transferring method results for " + r.GetType().ToString()));
                        results_active_mult_rec oldres = (results_active_mult_rec)r;
                        INCCMethodResults.results_active_mult_rec newres =
                            (INCCMethodResults.results_active_mult_rec)meas.INCCAnalysisResults.LookupMethodResults(det.MultiplicityParams, meas.INCCAnalysisState.Methods.selector, AnalysisMethod.ActiveMultiplicity, true);
                        newres.methodParams = new INCCAnalysisParams.active_mult_rec();
                        newres.methodParams.vf1 = oldres.am_vf1_res;
                        newres.methodParams.vf2 = oldres.am_vf2_res;
                        newres.methodParams.vf3 = oldres.am_vf3_res;
                        newres.methodParams.vt1 = oldres.am_vt1_res;
                        newres.methodParams.vt2 = oldres.am_vt2_res;
                        newres.methodParams.vt3 = oldres.am_vt2_res;
                        newres.mult.v = oldres.am_mult;
                        newres.mult.err = oldres.am_mult_err;
                     }
                    else if (r is results_collar_rec)
                    {
                        mlogger.TraceEvent(LogLevels.Verbose, 34060, ("Transferring method results for " + r.GetType().ToString()));
                        results_collar_rec oldres = (results_collar_rec)r;
                        INCCMethodResults.results_collar_rec newres =
                            (INCCMethodResults.results_collar_rec)meas.INCCAnalysisResults.LookupMethodResults(det.MultiplicityParams, meas.INCCAnalysisState.Methods.selector, AnalysisMethod.Collar, true);

                        newres.u235_mass.v = oldres.col_u235_mass; newres.u235_mass.err = oldres.col_u235_mass_err;
                        newres.percent_u235 = oldres.col_percent_u235;
                        newres.total_u_mass = oldres.col_total_u_mass;
                        newres.k0.v = oldres.col_k0; newres.k0.err = oldres.col_k0_err;
                        newres.k1.v = oldres.col_k1; newres.k1.err = oldres.col_k1_err;
                        newres.k2.v = oldres.col_k2; newres.k2.err = oldres.col_k2_err;
                        newres.k3.v = oldres.col_k3; newres.k3.err = oldres.col_k3_err;
                        newres.k4.v = oldres.col_k4; newres.k4.err = oldres.col_k4_err;
                        newres.k5.v = oldres.col_k5; newres.k5.err = oldres.col_k5_err;
                        newres.source_id = TransferUtils.str(oldres.col_source_id, INCC.SOURCE_ID_LENGTH);
                        newres.total_corr_fact.v = oldres.col_total_corr_fact; newres.total_corr_fact.err = oldres.col_total_corr_fact_err;
                        newres.corr_doubles.v = oldres.col_corr_doubles; newres.corr_doubles.err = oldres.col_corr_doubles_err;
                        newres.dcl_length.v = oldres.col_dcl_length; newres.dcl_length.err = oldres.col_dcl_length_err;
                        newres.dcl_total_u235.v = oldres.col_dcl_total_u235; newres.dcl_total_u235.err = oldres.col_dcl_total_u235_err;
                        newres.dcl_total_u238.v = oldres.col_dcl_total_u238; newres.dcl_total_u238.err = oldres.col_dcl_total_u238_err;
                        newres.dcl_total_rods = oldres.col_dcl_total_rods;
                        newres.dcl_total_poison_rods = oldres.col_dcl_total_poison_rods;

                        newres.dcl_poison_percent.v = oldres.col_dcl_poison_percent;
                        newres.dcl_poison_percent.err = oldres.col_dcl_poison_percent_err;
                        newres.dcl_minus_asy_u235_mass_pct = oldres.col_dcl_minus_asy_u235_mass_pct;
                        newres.dcl_minus_asy_u235_mass.v = oldres.col_dcl_minus_asy_u235_mass;
                        newres.dcl_minus_asy_u235_mass.err = oldres.col_dcl_minus_asy_u235_mass_err;

                        newres.methodParamsC.cev.a = oldres.col_a_res; newres.methodParamsC.cev.b = oldres.col_b_res;
                        newres.methodParamsC.cev.c = oldres.col_c_res; newres.methodParamsC.cev.d = oldres.col_d_res;
                        newres.methodParamsC.cev.var_a = oldres.col_var_a_res; newres.methodParamsC.cev.var_b = oldres.col_var_b_res;
                        newres.methodParamsC.cev.var_c = oldres.col_var_c_res; newres.methodParamsC.cev.var_d = oldres.col_var_d_res;
                        newres.methodParamsC.cev.setcovar(Coeff.a,Coeff.b,oldres.col_covar_ab_res);
                        newres.methodParamsC.cev._covar[0, 2] = oldres.col_covar_ac_res;
                        newres.methodParamsC.cev._covar[0, 3] = oldres.col_covar_ad_res;
                        newres.methodParamsC.cev._covar[1, 2] = oldres.col_covar_bc_res;
                        newres.methodParamsC.cev._covar[1, 3] = oldres.col_covar_bd_res;
                        newres.methodParamsC.cev._covar[2, 3] = oldres.col_covar_cd_res;
                        newres.methodParamsC.cev.cal_curve_equation = (INCCAnalysisParams.CurveEquation)oldres.col_collar_equation;
                        newres.methodParamsC.cev.sigma_x = oldres.col_sigma_x_res;
                        newres.methodParamsC.poison_absorption_fact[0] = oldres.col_poison_absorption_fact_res;
                        newres.methodParamsC.poison_rod_a[0] = new Tuple(oldres.col_poison_rod_a_res, oldres.col_poison_rod_a_err_res);
                        newres.methodParamsC.poison_rod_b[0] = new Tuple(oldres.col_poison_rod_b_res, oldres.col_poison_rod_b_err_res);
                        newres.methodParamsC.poison_rod_c[0] = new Tuple(oldres.col_poison_rod_c_res, oldres.col_poison_rod_c_err_res);
                        newres.methodParamsC.collar_mode = (oldres.col_collar_mode == 0 ? false : true);
                        newres.methodParamsC.number_calib_rods = (int)oldres.col_number_calib_rods_res;
                        newres.methodParamsC.poison_rod_type[0] = TransferUtils.str(oldres.col_poison_rod_type_res, INCC.MAX_ROD_TYPE_LENGTH);
                        newres.methodParamsC.u_mass_corr_fact_a.v = oldres.col_u_mass_corr_fact_a_res; newres.methodParamsC.u_mass_corr_fact_a.err = oldres.col_u_mass_corr_fact_a_err_res;
                        newres.methodParamsC.u_mass_corr_fact_b.v = oldres.col_u_mass_corr_fact_b_res; newres.methodParamsC.u_mass_corr_fact_b.err = oldres.col_u_mass_corr_fact_b_err_res;
                        newres.methodParamsC.sample_corr_fact.v = oldres.col_sample_corr_fact_res; newres.methodParamsC.sample_corr_fact.err = oldres.col_sample_corr_fact_err_res;

                        newres.methodParamsDetector.collar_mode = (oldres.col_collar_mode == 0 ? false : true);
                        newres.methodParamsDetector.reference_date = INCC.DateFrom(TransferUtils.str(oldres.col_reference_date_res, INCC.DATE_TIME_LENGTH));
                        newres.methodParamsDetector.relative_doubles_rate = oldres.col_relative_doubles_rate_res;

                        newres.methodParamsK5.k5_mode = (oldres.col_collar_mode == 0 ? false : true);
                        newres.methodParamsK5.k5_item_type = TransferUtils.str(oldres.col_collar_item_type, INCC.MAX_ITEM_TYPE_LENGTH);
                        newres.methodParamsK5.k5 = Copy(oldres.collar_k5_res, oldres.collar_k5_err_res, INCC.MAX_COLLAR_K5_PARAMETERS);
                        newres.methodParamsK5.k5_checkbox = TransferUtils.Copy(oldres.collar_k5_checkbox_res, INCC.MAX_COLLAR_K5_PARAMETERS);
                        for (int i = 0; i < INCC.MAX_COLLAR_K5_PARAMETERS; i++)
                        {
                            int index = i * INCC.MAX_K5_LABEL_LENGTH;
                            newres.methodParamsK5.k5_label[i] = TransferUtils.str(oldres.collar_k5_label_res + index, INCC.MAX_K5_LABEL_LENGTH);
                        }

                        CollarItemId cid = new CollarItemId(TransferUtils.str(results.item_id, INCC.MAX_ITEM_ID_LENGTH));
                        cid.length = new Tuple(newres.dcl_length);
                        cid.total_u235 = new Tuple(newres.dcl_total_u235);
                        cid.total_u238 = new Tuple(newres.dcl_total_u238);
                        cid.total_rods = newres.dcl_total_rods;
                        cid.total_poison_rods = newres.dcl_total_poison_rods;
                        cid.poison_percent = new Tuple(newres.dcl_poison_percent);
                        cid.rod_type = newres.methodParamsC.poison_rod_type[0];
                        cid.modified = true;

                        List<CollarItemId> list = NC.App.DB.CollarItemIds.GetList();
                        bool glump = list.Exists(i => { return string.Compare(cid.item_id, i.item_id, true) == 0; });
                        if (glump && overwrite)
                        {
                            list.Remove(cid);
                            list.Add(cid);
                        }
                        else list.Add(cid);
                    }
                    else if (r is results_de_mult_rec)
                    {
                        mlogger.TraceEvent(LogLevels.Verbose, 34061, ("Transferring method results for " + r.GetType().ToString()));
                        results_de_mult_rec oldres = (results_de_mult_rec)r;
                        INCCMethodResults.results_de_mult_rec newres =
                            (INCCMethodResults.results_de_mult_rec)meas.INCCAnalysisResults.LookupMethodResults(det.MultiplicityParams, meas.INCCAnalysisState.Methods.selector, AnalysisMethod.DUAL_ENERGY_MULT_SAVE_RESTORE, true);
                        newres.meas_ring_ratio = oldres.de_meas_ring_ratio;
                        newres.energy_corr_factor = oldres.de_energy_corr_factor;
                        newres.interpolated_neutron_energy = oldres.de_interpolated_neutron_energy;
                        newres.methodParams.detector_efficiency = TransferUtils.Copy(oldres.de_detector_efficiency_res, INCC.MAX_DUAL_ENERGY_ROWS);
                        newres.methodParams.inner_outer_ring_ratio = TransferUtils.Copy(oldres.de_inner_outer_ring_ratio_res, INCC.MAX_DUAL_ENERGY_ROWS);
                        newres.methodParams.neutron_energy = TransferUtils.Copy(oldres.de_neutron_energy_res, INCC.MAX_DUAL_ENERGY_ROWS);
                        newres.methodParams.relative_fission = TransferUtils.Copy(oldres.de_relative_fission_res, INCC.MAX_DUAL_ENERGY_ROWS);
                        newres.methodParams.inner_ring_efficiency = oldres.de_inner_ring_efficiency_res;
                        newres.methodParams.outer_ring_efficiency = oldres.de_outer_ring_efficiency_res;
                    }
                    else if (r is results_tm_bkg_rec)
                    {
                        mlogger.TraceEvent(LogLevels.Warning, 34062, ("Transferring method results for " + r.GetType().ToString()));
                        results_tm_bkg_rec oldres = (results_tm_bkg_rec)r;  // todo: tm bkg handling design incomplete, these values are attached to bkg measurements when the truncated flag is enabled
                        INCCMethodResults.results_tm_bkg_rec newres =
                            (INCCMethodResults.results_tm_bkg_rec)meas.INCCAnalysisResults.LookupMethodResults(det.MultiplicityParams, meas.INCCAnalysisState.Methods.selector, AnalysisMethod.None, true);
                        newres.methodParams.Singles.v = oldres.results_tm_singles_bkg;
                        newres.methodParams.Singles.err = oldres.results_tm_singles_bkg_err;
                        newres.methodParams.Zeros.v = oldres.results_tm_zeros_bkg;
                        newres.methodParams.Zeros.err = oldres.results_tm_zeros_bkg_err;
                        newres.methodParams.Ones.v = oldres.results_tm_ones_bkg;
                        newres.methodParams.Ones.err = oldres.results_tm_ones_bkg_err;
                        newres.methodParams.Twos.v = oldres.results_tm_twos_bkg;
                        newres.methodParams.Twos.err = oldres.results_tm_twos_bkg_err;
                    }
                    else
                    {
                        mlogger.TraceEvent(LogLevels.Warning, 34040, ("todo: Transferring method results for " + r.GetType().ToString())); // todo: complete the list
                    }
                }

            }
            #endregion results transfer
            // dev note: here is where the detector tree creation and replacement with restore_replace_detector_structs occurs in the original code
            // todo: based on overwrite flag, replace det-dependent classes, the analysis_methods: (none-map) and each (det,mat) -> calib from results class instances

            #region Meas&Results

            AnalysisDefs.holdup_config_rec hc = new AnalysisDefs.holdup_config_rec();
            hc.glovebox_id = TransferUtils.str(results.results_glovebox_id, INCC.MAX_GLOVEBOX_ID_LENGTH);
            hc.num_columns = results.results_num_columns;
            hc.num_rows = results.results_num_rows;
            hc.distance = results.results_distance;
            meas.AcquireState.glovebox_id = hc.glovebox_id;
            // this is a good place to create the general results_rec
            INCCResults.results_rec xres = new INCCResults.results_rec(meas);
            meas.INCCAnalysisResults.TradResultsRec = xres;
            // oddball entries in need of preservation
            xres.total_good_count_time = results.total_good_count_time;
            xres.total_number_runs = results.total_number_runs;
            xres.primary = imr.primaryMethod;
            xres.net_drum_weight = results.net_drum_weight;
            xres.completed = (results.completed != 0 ? true : false);
            xres.db_version = results.db_version;
            xres.hc = hc;
            xres.original_meas_date = INCC.DateFrom(TransferUtils.str(results.original_meas_date, INCC.DATE_TIME_LENGTH));
            // NEXT: copy move passive and active meas id's here

             long mid = meas.Persist();

            // save the warning and error messages from the results here, these rode on the results rec in INCC5
            NC.App.DB.AddAnalysisMessages(msgs, mid);

            // Store off Params

            NC.App.DB.UpdateDetector(det);
            NC.App.DB.NormParameters.Set(det, meas.Norm);  // might have been saved in earlier step already
            NC.App.DB.BackgroundParameters.Set(det, meas.Background);

            INCCDB.AcquireSelector acqsel = new INCCDB.AcquireSelector(det, acq.item_type, acq.MeasDateTime);
            if (overwrite)
            {
                NC.App.DB.ReplaceAcquireParams(acqsel, acq);
            }
            else
                NC.App.DB.AddAcquireParams(acqsel, acq); // gotta add it to the global map, then push it to the DB

            if (meas.Tests != null) // added only if not found on the list
                NC.App.DB.TestParameters.Set(meas.Tests);

            NC.App.DB.Isotopics.SetList();  // new style de 'mouser'!
            //NC.App.DB.CompositeIsotopics.SetList();// next:NYI
            NC.App.DB.ItemIds.SetList(); // This writes any new items ids to the DB
            NC.App.DB.CollarItemIds.SetList(); // so does this

            //Loop over measurement cycles
            NC.App.DB.AddCycles(meas.Cycles, det.MultiplicityParams, mid);

            //Store off Params

            // todo: complete table design and creation/update here, still have issues with collar and curium ratio results
            // get results based on meas option, (Calib and Verif have method results, others do not), update into DB here
            IEnumerator iter = meas.INCCAnalysisResults.GetMeasSelectorResultsEnumerator();
            while (iter.MoveNext())  // only one result indexer is present when doing an INCC5 transfer
            {
                MeasOptionSelector moskey = (MeasOptionSelector)iter.Current;
                INCCResult ir = meas.INCCAnalysisResults[moskey];
                // ir contains the measurement option-specific results: empty for rates and holdup, and also empty for calib and verif, the method-focused analyses,
                // but values are present for initial, normalization, precision, and should be present for background for the tm bkg results
                switch (meas.MeasOption)
                {
                    case AssaySelector.MeasurementOption.background:
                        if (meas.Background.TMBkgParams.ComputeTMBkg)
                            mlogger.TraceEvent(LogLevels.Warning, 82010, "Background truncated multiplicity"); // todo: present the tm bkg results on m.Background
                        break;
                    case AssaySelector.MeasurementOption.initial:
                    case AssaySelector.MeasurementOption.normalization:
                    case AssaySelector.MeasurementOption.precision:
                        {
                            ElementList els = ir.ToDBElementList();
                            ParamsRelatedBackToMeasurement ar = new ParamsRelatedBackToMeasurement(ir.Table);
                            long resid = ar.Create(mid, els);
                            mlogger.TraceEvent(LogLevels.Verbose, 34103, string.Format("Preserving {0} as {1}", ir.Table, resid));
                        }
                        break;
                    case AssaySelector.MeasurementOption.verification:
                    case AssaySelector.MeasurementOption.calibration:
                    {
                        INCCMethodResults imrs;
                        bool have = meas.INCCAnalysisResults.TryGetINCCResults(moskey.MultiplicityParams, out imrs);
                        if (have) // should be true for verification and calibration
                        {
                            if (imrs.ContainsKey(meas.INCCAnalysisState.Methods.selector))
                            {
                                // we've got a distinct detector id and material type on the methods, so that is the indexer here
                                Dictionary<AnalysisMethod, INCCMethodResult> amimr = imrs[meas.INCCAnalysisState.Methods.selector];

                                // now get an enumerator over the map of method results
                                Dictionary<AnalysisMethod, INCCMethodResult>.Enumerator ai = amimr.GetEnumerator();
                                while (ai.MoveNext())
                                {
                                    if (ai.Current.Key.IsNone())
                                        continue;
                                    INCCMethodResult _imr = ai.Current.Value;
                                    // insert this into the DB under the current meas key
                                    try
                                    {
                                        ElementList els = _imr.ToDBElementList(); // also sets table property, gotta do it first
                                        ParamsRelatedBackToMeasurement ar = new ParamsRelatedBackToMeasurement(_imr.Table);
                                        long resid = ar.Create(mid, els);
                                        do
                                        {
                                            long resmid = ar.CreateMethod(resid, mid, _imr.methodParams.ToDBElementList());
                                            mlogger.TraceEvent(LogLevels.Verbose, 34101, string.Format("Preserving {0} as {1},{2}", _imr.Table, resmid, resid));
                                        } while (_imr.methodParams.Pump > 0);
                                    }
                                    catch (Exception e)
                                    {
                                        mlogger.TraceEvent(LogLevels.Warning, 34102, "Results processing error {0} {1}", _imr.ToString(), e.Message);
                                    }
                                }
                            } else
                                mlogger.TraceEvent(LogLevels.Error, 34102, "Results missing for {0}", meas.INCCAnalysisState.Methods.selector.ToString());

                        }
                    }
                    break;
                    case AssaySelector.MeasurementOption.rates:
                    case AssaySelector.MeasurementOption.holdup:
                    case AssaySelector.MeasurementOption.unspecified:
                    default: // nothing new to present with these
                        break;
                }
            }
            #endregion Meas&Results

              // todo: handle well config setting with bkg here;

            return true;
        }
コード例 #18
0
ファイル: INCCMeasurement.cs プロジェクト: hnordquist/INCC6
        /// <summary>
        /// Do the third phase  . . .
        /// From calc_res.cpp,
        /// </summary>
        public static void CalculateResults(this Measurement meas)
        {
            IEnumerator iter = meas.CountingAnalysisResults.GetMultiplicityEnumerator();
            while (iter.MoveNext())
            {
                Multiplicity mkey = (Multiplicity)((KeyValuePair<SpecificCountingAnalyzerParams, object>)(iter.Current)).Key;
                if (NC.App.Opstate.IsAbortRequested)
                    return;

                INCCResult results;
                MeasOptionSelector ar = new MeasOptionSelector(meas.MeasOption, mkey);
                bool found = meas.INCCAnalysisResults.TryGetValue(ar, out results);
                if (!found)
                {
                    meas.AddErrorMessage("No results available", 10151, mkey);
                    return;
                }
                /* if using measure to precision, and max # runs reached, then add warning message indicating actual precision reached. */
                if (meas.AcquireState.acquire_type == AcquireConvergence.DoublesPrecision)
                {
                    if (results.rates.DTCRates.DoublesRate != 0.0)
                    {
                        double error = results.rates.DTCRates.Doubles.err / results.rates.DTCRates.DoublesRate * 100.0;
                        if (error > meas.AcquireState.meas_precision)
                        {
                            meas.AddWarningMessage("Measurement doubles error = " + error.ToString("F2"), 10126, mkey);
                        }
                    }
                }
                else if (meas.AcquireState.acquire_type == AcquireConvergence.TriplesPrecision)
                {
                    if (results.rates.DTCRates.TriplesRate != 0.0)
                    {
                        double error = results.rates.DTCRates.Triples.err / results.rates.DTCRates.TriplesRate * 100.0;
                        if (error > meas.AcquireState.meas_precision)
                        {
                            meas.AddWarningMessage("Measurement triples error = " + error.ToString("F2"), 10127, mkey);
                        }
                    }
                }

                if (meas.MeasOption == AssaySelector.MeasurementOption.rates)   // Doug  Requirement #2
                {
                    // for a rates only measurement, all done!
                    meas.Logger.TraceEvent(NCCReporter.LogLevels.Info, 10180, "Rates Only measurement complete");
                    continue;
                }

                try
                {
                    switch (meas.MeasOption)
                    {
                        case AssaySelector.MeasurementOption.background: // Doug  Requirement #3
                            // a bkg is an average over a bunch of cycles with only the deadtime correction applied,
                            // but note the variant for Truncated Mult background, where an additional calculation is made

                            if (results.rates.DTCRates.DoublesRate > meas.Tests.bkgDoublesRateLimit)
                                meas.AddWarningMessage("Background doubles rate " + results.rates.DTCRates.DoublesRate + " greater than " + meas.Tests.bkgDoublesRateLimit, 10141, mkey);
                            if (results.rates.DTCRates.TriplesRate > meas.Tests.bkgTriplesRateLimit)
                                meas.AddWarningMessage("Background triples rate " + results.rates.DTCRates.TriplesRate + " greater than " + meas.Tests.bkgTriplesRateLimit, 10142, mkey);

                            // dev note: this is a background measurement per se, so we copy the results to the Background class and store the entire thing that way
                            // NEXT: Need to account for Active bkg beginning here.

                            if (Integ.GetCurrentAcquireParams().well_config == WellConfiguration.Active)// Is an active acquisition.
                            {
                                meas.Background.INCCActive.CopyFrom(results.rates.DeadtimeCorrectedRates);
                            }
                            else
                                meas.Background.CopyFrom(results.rates);
                            //  maybe if (INCCAnalysisState.Methods.Has(AnalysisMethod.TruncatedMultiplicity))
                            if (meas.Background.TMBkgParams.ComputeTMBkg)
                                // Trunc Mult Bkg step, calc_tm_rates, sets TM bkg rates on Measurement.Background
                                INCCAnalysis.calc_tm_rates(mkey, results, meas, meas.Background.TMBkgParams, meas.Detector.Id.SRType);

                            meas.Logger.TraceEvent(NCCReporter.LogLevels.Info, 10181, "Background measurement complete");
                            break;
                        case AssaySelector.MeasurementOption.initial:

                            INCCResults.results_init_src_rec results_init_src = (INCCResults.results_init_src_rec)results;

                            meas.Logger.TraceEvent(NCCReporter.LogLevels.Info, 10182, "Calculating Initial source measurement results");
                            bool funhappy = INCCAnalysis.initial_source_meas(meas, mkey, RatesAdjustments.DeadtimeCorrected);
                            if (!funhappy || !results_init_src.pass)
                            {
                                meas.AddWarningMessage("Initial source measurement failed", 10123, mkey);
                            }
                            // on fail, only the relevant results_init_src_rec is saved
                            // on pass, the normalization parameters are modified with the results_init_src_rec results, and so both are udpated.
                            break;
                        case AssaySelector.MeasurementOption.normalization:

                            meas.Logger.TraceEvent(NCCReporter.LogLevels.Info, 10183, "Calculating Normalization measurement results");
                            bool happyfun = INCCAnalysis.bias_test(meas, mkey, RatesAdjustments.DeadtimeCorrected);
                            if (!happyfun)
                            {
                                meas.AddWarningMessage("Normalization test -- data quality is inadequate", 10124, mkey);
                            }
                            break;
                        case AssaySelector.MeasurementOption.precision:

                            meas.Logger.TraceEvent(NCCReporter.LogLevels.Info, 10184, "Calculating Precision measurement results");
                            bool charmyfun = INCCAnalysis.precision_test(meas, mkey, RatesAdjustments.DeadtimeCorrected);
                            if (!charmyfun)
                            {
                                meas.AddWarningMessage("Precision test failed", 10125, mkey);
                            }
                            break;
                        case AssaySelector.MeasurementOption.calibration: // from calc_res.cpp
                            if (meas.INCCAnalysisState.Methods.CalibrationAnalysisSelected())
                            {
                                meas.Logger.TraceEvent(NCCReporter.LogLevels.Info, 10185, "Calculating Calibration measurement results");
                                // dev note: since the analysis routines have similar signatures, design a class OK?
                                if (meas.INCCAnalysisState.Methods.Has(AnalysisMethod.CalibrationCurve))
                                {
                                    meas.Logger.TraceEvent(NCCReporter.LogLevels.Info, 10191, "Calculating " + AnalysisMethod.CalibrationCurve.FullName() + " measurement results");
                                    // get the current results_cal_curve_rec
                                    INCCMethodResults.results_cal_curve_rec ccres = (INCCMethodResults.results_cal_curve_rec)
                                        meas.INCCAnalysisResults.LookupMethodResults(mkey, meas.INCCAnalysisState.Methods.selector, AnalysisMethod.CalibrationCurve, true);

                                    INCCAnalysisParams.cal_curve_rec cal_curve = (INCCAnalysisParams.cal_curve_rec)meas.INCCAnalysisState.Methods.GetMethodParameters(AnalysisMethod.CalibrationCurve);
                                    ccres.methodParams = new INCCAnalysisParams.cal_curve_rec(cal_curve);

                                    double pu_mass = ccres.pu_mass.v;
                                    meas.Isotopics.UpdateDeclaredPuMass(meas.MeasDate, ref pu_mass, INCCAnalysis.INCCParity);
                                    ccres.pu_mass.v = pu_mass;
                                    ccres.pu_mass.err = 0.0;
                                    ccres.pu240e_mass.err = 0.0;

                                    double pu240e_mass = ccres.pu240e_mass.v;
                                    meas.Isotopics.calc_pu240e(pu_mass, out pu240e_mass, meas);
                                    ccres.pu240e_mass.v = pu240e_mass;

                                }
                                if (meas.INCCAnalysisState.Methods.Has(AnalysisMethod.KnownA))
                                {
                                    meas.Logger.TraceEvent(NCCReporter.LogLevels.Info, 10192, "Calculating " + AnalysisMethod.KnownA.FullName() + " calibration results");
                                    INCCMethodResults.results_known_alpha_rec kares = INCCAnalysis.CalculateKnownAlpha(mkey, results.rates, meas, RatesAdjustments.DeadtimeCorrected);
                                    if (kares == null)
                                    {
                                        meas.AddErrorMessage("Known alpha analysis error", 10153, mkey);
                                    }
                                    else
                                    {
                                        kares.pu_mass.v = meas.AcquireState.mass;
                                        double pu_mass = kares.pu_mass.v;
                                        meas.Isotopics.UpdateDeclaredPuMass(meas.MeasDate, ref pu_mass, INCCAnalysis.INCCParity);
                                        kares.pu_mass.v = pu_mass;
                                        kares.pu_mass.err = 0.0;
                                        kares.pu240e_mass.err = 0.0;

                                        double pu240e_mass = kares.pu240e_mass.v;
                                        meas.Isotopics.calc_pu240e(pu_mass, out pu240e_mass, meas);
                                        kares.pu240e_mass.v = pu240e_mass;
                                    }
                                }
                                if (meas.INCCAnalysisState.Methods.Has(AnalysisMethod.Active))
                                {
                                    meas.Logger.TraceEvent(NCCReporter.LogLevels.Info, 10192, "Arranging " + AnalysisMethod.Active.FullName() + " calibration results");

                                    INCCSelector sel = new INCCSelector(meas.INCCAnalysisState.Methods.selector);
                                    INCCAnalysisParams.active_rec act;
                                    INCCAnalysisParams.INCCMethodDescriptor surr = meas.INCCAnalysisState.Methods.GetMethodParameters(AnalysisMethod.Active);
                                    if (surr == null)
                                    {
                                        act = new INCCAnalysisParams.active_rec();
                                        meas.INCCAnalysisState.Methods.AddMethod(AnalysisMethod.Active, act);
                                    }
                                    else
                                    {
                                        act = (INCCAnalysisParams.active_rec)surr;
                                    }
                                    INCCMethodResults.results_active_rec res;
                                    res = (INCCMethodResults.results_active_rec)meas.INCCAnalysisResults.LookupMethodResults(mkey, sel, AnalysisMethod.Active, true);

                                    // all this does is copy the declared mass over to the results, WTF
                                    res.u235_mass.v = meas.AcquireState.mass;

                                }
                                if (meas.INCCAnalysisState.Methods.Has(AnalysisMethod.AddASource))
                                {
                                    meas.Logger.TraceEvent(NCCReporter.LogLevels.Info, 10152, "Calculating " + AnalysisMethod.AddASource.FullName() + " calibration results");
                                    INCCSelector sel = new INCCSelector(meas.INCCAnalysisState.Methods.selector);
                                    INCCAnalysisParams.add_a_source_rec aas;
                                    INCCMethodResults.results_add_a_source_rec acres;
                                    INCCAnalysisParams.INCCMethodDescriptor surr = meas.INCCAnalysisState.Methods.GetMethodParameters(AnalysisMethod.AddASource);
                                    if (surr == null)
                                    {
                                        aas = new INCCAnalysisParams.add_a_source_rec();
                                        meas.INCCAnalysisState.Methods.AddMethod(AnalysisMethod.AddASource, aas);
                                    }
                                    else
                                    {
                                        aas = (INCCAnalysisParams.add_a_source_rec)surr;
                                    }
                                    acres = (INCCMethodResults.results_add_a_source_rec)meas.INCCAnalysisResults.LookupMethodResults(mkey, sel, AnalysisMethod.AddASource, true);

                                    acres.pu_mass.v = meas.AcquireState.mass;
                                    // update_declared_pu_mass
                                    double pu_mass = acres.pu_mass.v;
                                    meas.Isotopics.UpdateDeclaredPuMass(meas.MeasDate, ref pu_mass, INCCAnalysis.INCCParity);
                                    acres.pu_mass.v = pu_mass;
                                    acres.pu_mass.err = 0.0;
                                    acres.pu240e_mass.err = 0.0;

                                    double pu240e_mass = acres.pu240e_mass.v;
                                    meas.Isotopics.calc_pu240e(pu_mass, out pu240e_mass, meas);
                                    acres.pu240e_mass.v = pu240e_mass;

                                }
                            }
                            else
                            {
                                meas.AddErrorMessage("No Calibration analysis methods selected", 10153, mkey);
                            }
                            break;
                        case AssaySelector.MeasurementOption.verification:
                            // see INCC calc_asy.cpp
                            // dev note: check for item in the item table, make sure to place this item id on the MeasurementId.item property
                            if (!string.IsNullOrEmpty(meas.AcquireState.item_id))
                            {
                                meas.Logger.TraceEvent(NCCReporter.LogLevels.Info, 10194, "Using item id '{0}'", meas.AcquireState.item_id);
                            }
                            else
                                meas.Logger.TraceEvent(NCCReporter.LogLevels.Verbose, 10194, "No item id");

                            if (meas.INCCAnalysisState.Methods.VerificationAnalysisSelected())
                            {
                                meas.Logger.TraceEvent(NCCReporter.LogLevels.Info, 10186, "Calculating {0} measurement results", meas.MeasOption.PrintName());

                                meas.CalculateVerificationResults(mkey, results);
                            }
                            else
                            {
                                meas.AddErrorMessage("No analysis methods selected", 10156, mkey);
                            }
                            break;
                        case AssaySelector.MeasurementOption.holdup:   // NEXT: Hold-up held up, implement it #35
                            meas.Logger.TraceEvent(NCCReporter.LogLevels.Error, 10187, "Holdup analysis unsupported");
                            break;
                    }
                }
                catch (Exception e)
                {
                    meas.Logger.TraceException(e);
                }
            }
        }
コード例 #19
0
        protected Section ConstructReportSection(INCCTestDataSection section, MeasOptionSelector moskey,  Detector det)
        {
            INCCTestDataStyle sec = null;
            try
            {
                switch (section)
                {

                    case INCCTestDataSection.CyclesWithMultiplicityDistributions:
                        sec = new INCCTestDataStyle(null, 0, INCCStyleSection.ReportSection.MultiColumn);
                        //Singles 1st Scaler 2nd Scaler Reals + Accidentals Accidentals
                        int[] crdwidths = new int[] {10, 10, 10, 10, 10 };
                        int[] srawidths = new int[] { 12, 12 };
                        foreach (Cycle cyc in meas.Cycles)
                        {
                            // if no results on the cycle, these map indexers throw
                            if (cyc.CountingAnalysisResults.GetResultsCount(typeof(Multiplicity)) > 0)                            // if no results on the cycle, these map indexers throw
                            {
                                MultiplicityCountingRes mcr = (MultiplicityCountingRes)cyc.CountingAnalysisResults[moskey.MultiplicityParams];
                                sec.AddColumnRow(
                                    new ulong[] { (ulong)mcr.Totals, (ulong)mcr.Scaler1.v, (ulong)mcr.Scaler2.v, (ulong)mcr.RASum, (ulong)mcr.ASum },
                                     crdwidths);
                                int minbin, maxbin;
                                minbin = Math.Min(mcr.RAMult.Length, mcr.NormedAMult.Length);
                                maxbin = Math.Max(mcr.RAMult.Length, mcr.NormedAMult.Length);
                                sec.AddOne(maxbin);
                                for (int i = 0; i < minbin; i++)
                                    sec.AddColumnRow(new ulong[] { mcr.RAMult[i], mcr.NormedAMult[i] }, srawidths);
                                for (int i = minbin; i < maxbin; i++)  // check for uneven column
                                {
                                    ulong[] potential = new ulong[2];
                                    if (i < mcr.RAMult.Length)
                                        potential[0] = mcr.RAMult[i];
                                    if (i < mcr.NormedAMult.Length)
                                        potential[1] = mcr.NormedAMult[i];
                                    sec.AddColumnRow(potential, srawidths);
                                }
                            }
                        }
                        break;

                    default:
                        break;
                }
            }
            catch (Exception e)
            {
                ctrllog.TraceException(e);
            }
            return sec;
        }
コード例 #20
0
ファイル: INCCMeasurement.cs プロジェクト: hnordquist/INCC6
        /// <summary>
        /// Save in the database the method results and copies of the current method parameters.
        /// The table entries are related back to the measurement.
        /// The method results are preserved in the results_\<method table name\> and \<method table name\>_m DB tables.
        /// </summary>
        /// <param name="m">The measurement to preserve</param>
        /// <param name="moskey">The option selector+multiplicity key for the method results map</param> 
        static void SaveMethodResultsForThisMeasurement(this Measurement m, MeasOptionSelector moskey)
        {
            // DB.Measurements ms = new DB.Measurements();
            long mid = m.MeasurementId.UniqueId;

            INCCMethodResults imrs;
            bool gotten = m.INCCAnalysisResults.TryGetINCCResults(moskey.MultiplicityParams, out imrs);
            if (gotten && imrs.Count > 0) // expected to be true for verification and calibration
            {
                //The distinct detector id and material type index the methods and the method results
                Dictionary<AnalysisMethod, INCCMethodResult> amimr = imrs[m.INCCAnalysisState.Methods.selector];
                // now get an enumerator over the map of method results
                Dictionary<AnalysisMethod, INCCMethodResult>.Enumerator ai = amimr.GetEnumerator();
                while (ai.MoveNext())
                {
                    INCCMethodResult imr = ai.Current.Value;
                    DB.ElementList els = imr.ToDBElementList(); // generates the Table property content too
                    DB.ParamsRelatedBackToMeasurement ar = new DB.ParamsRelatedBackToMeasurement(imr.Table);
                    long resid = ar.Create(mid, els);  // save the method results in the relevant results table
                    do
                    {
                        long mresid = ar.CreateMethod(resid, mid, imr.methodParams.ToDBElementList()); // save the initial method params (the copy rides on the results)
                        m.Logger.TraceEvent(NCCReporter.LogLevels.Verbose, 34104, string.Format("Method results {0} preserved ({1}, {2})", imr.Table, resid, mresid));
                    } while (imr.methodParams.Pump > 0);
                }
            }
        }
コード例 #21
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
 internal static unsafe iresultsbase MoveBias(INCCResults ir, MeasOptionSelector mos)
 {
     results_bias_rec res = new results_bias_rec();
     INCCResult results;
     bool found = ir.TryGetValue(mos, out results);
     if (found)
     {
         INCCResults.results_bias_rec t = (INCCResults.results_bias_rec)results;
         res.results_bias_mode = NewToOldBiasTestId(t.mode);
         StatePack(t.pass, res.bias_pass_fail);
         StrToBytes(INCC.SOURCE_ID_LENGTH, t.sourceId, res.bias_source_id);
         res.bias_sngls_rate_expect = t.biasSnglsRateExpect.v;
         res.bias_sngls_rate_expect_err = t.biasSnglsRateExpect.err;
         res.bias_sngls_rate_expect_meas = t.biasSnglsRateExpectMeas.v;
         res.bias_sngls_rate_expect_meas_err = t.biasSnglsRateExpectMeas.err;
         res.bias_dbls_rate_expect = t.biasDblsRateExpect.v;
         res.bias_dbls_rate_expect_err = t.biasDblsRateExpect.err;
         res.bias_dbls_rate_expect_meas = t.biasDblsRateExpectMeas.v;
         res.bias_dbls_rate_expect_meas_err = t.biasDblsRateExpectMeas.err;
         res.new_norm_constant = t.newNormConstant.v;
         res.new_norm_constant_err = t.newNormConstant.err;
         res.required_precision = t.requiredPrecision;
         res.required_meas_seconds = t.requiredMeasSeconds;
     }
     return res;
 }
コード例 #22
0
ファイル: INCCMeasurement.cs プロジェクト: hnordquist/INCC6
 /// <summary>
 /// Save in the database the summary <see cref="INCCResults.results_rec"/> results for every type of INCC measurement.
 /// </summary>
 /// <param name="m">The measurement to preserve</param>
 /// <param name="moskey">The option selector+multiplicity key for the method results map</param> 
 static void SaveSummaryResultsForThisMeasurement(this Measurement m, MeasOptionSelector moskey)
 {
     long mid = m.MeasurementId.UniqueId;
     DB.Results dbres = new DB.Results();
     // save results with mid as foreign key
     bool b = dbres.Update(mid, m.INCCAnalysisResults.TradResultsRec.ToDBElementList()); // APluralityOfMultiplicityAnalyzers: results rec needs to be fully populated before here, or it needs to be saved again at the end of the processing
     m.Logger.TraceEvent(NCCReporter.LogLevels.Info, 34045, (b ? "Preserved " : "Failed to save ") + "summary results");
 }
コード例 #23
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
            internal static unsafe iresultsbase MoveCollar(INCCAnalysisState ias, MeasOptionSelector mos)
            {
                results_collar_rec res = new results_collar_rec();
                INCCMethodResult result;
                bool found = ias.Results.TryGetMethodResults(mos.MultiplicityParams, ias.Methods.selector, AnalysisMethod.Collar, out result);
                if (found)
                {
                    INCCMethodResults.results_collar_rec m = (INCCMethodResults.results_collar_rec)result;
                    res.col_u235_mass = m.u235_mass.v;
                    res.col_u235_mass_err = m.u235_mass.err;
                    res.col_percent_u235 = m.percent_u235;
                    res.col_total_u_mass = m.total_u_mass;
                    res.col_k0 = m.k0.v;
                    res.col_k0_err = m.k0.err;
                    res.col_k1 = m.k1.v;
                    res.col_k1_err = m.k1.err;
                    res.col_k2 = m.k2.v;
                    res.col_k2_err = m.k2.err;
                    res.col_k3 = m.k3.v;
                    res.col_k3_err = m.k3.err;
                    res.col_k4 = m.k4.v;
                    res.col_k4_err = m.k4.err;
                    res.col_k5 = m.k5.v;
                    res.col_k5_err = m.k5.err;
                    res.col_total_corr_fact = m.total_corr_fact.v;
                    res.col_total_corr_fact_err = m.total_corr_fact.err;
                    StrToBytes(INCC.SOURCE_ID_LENGTH, m.source_id, res.col_source_id);
                    res.col_corr_doubles = m.corr_doubles.v;
                    res.col_corr_doubles_err = m.corr_doubles.err;
                    res.col_dcl_length = m.dcl_length.v;
                    res.col_dcl_length_err = m.dcl_length.err;
                    res.col_dcl_total_u235 = m.dcl_total_u235.v;
                    res.col_dcl_total_u235_err = m.dcl_total_u235.err;
                    res.col_dcl_total_u238 = m.dcl_total_u238.v;
                    res.col_dcl_total_u238_err = m.dcl_total_u238.err;
                    res.col_dcl_total_rods = m.dcl_total_rods;
                    res.col_dcl_total_poison_rods = m.dcl_total_poison_rods;
                    res.col_dcl_poison_percent = m.dcl_poison_percent.v;
                    res.col_dcl_poison_percent_err = m.dcl_poison_percent.err;
                    res.col_dcl_minus_asy_u235_mass = m.dcl_minus_asy_u235_mass.v;
                    res.col_dcl_minus_asy_u235_mass_err = m.dcl_minus_asy_u235_mass.err;
                    res.col_dcl_minus_asy_u235_mass_pct = m.dcl_minus_asy_u235_mass_pct;
                    StatePack(m.pass, res.col_pass_fail);
                    StrToBytes(INCC.MAX_DETECTOR_ID_LENGTH, ias.Methods.selector.detectorid, res.col_collar_detector_id);
                    StrToBytes(INCC.MAX_ITEM_TYPE_LENGTH, ias.Methods.selector.material, res.col_collar_item_type);
                    res.col_collar_mode = (byte)(m.methodParams.collar.collar_mode ? 1 : 0);
                    res.col_collar_equation = (byte)m.methodParamsC.cev.cal_curve_equation;
                    res.col_a_res = m.methodParamsC.cev.a;
                    res.col_b_res = m.methodParamsC.cev.b;
                    res.col_c_res = m.methodParamsC.cev.c;
                    res.col_d_res = m.methodParamsC.cev.d;
                    res.col_covar_ab_res = m.methodParamsC.cev.covar(Coeff.a, Coeff.b);
                    res.col_covar_ac_res = m.methodParamsC.cev.covar(Coeff.a, Coeff.c);
                    res.col_covar_ad_res = m.methodParamsC.cev.covar(Coeff.a, Coeff.d);
                    res.col_covar_bc_res = m.methodParamsC.cev.covar(Coeff.b, Coeff.c);
                    res.col_covar_bd_res = m.methodParamsC.cev.covar(Coeff.b, Coeff.d);
                    res.col_covar_cd_res = m.methodParamsC.cev.covar(Coeff.c, Coeff.d);
                    res.col_var_a_res = m.methodParamsC.cev.var_a;
                    res.col_var_b_res = m.methodParamsC.cev.var_b;
                    res.col_var_c_res = m.methodParamsC.cev.var_c;
                    res.col_var_d_res = m.methodParamsC.cev.var_d;
                    res.col_sigma_x_res = m.methodParamsC.cev.sigma_x;
                    res.col_number_calib_rods_res = m.methodParamsC.number_calib_rods;
                    StrToBytes(INCC.MAX_ROD_TYPE_LENGTH, m.methodParamsC.poison_rod_type[0], res.col_poison_rod_type_res);
                    res.col_poison_absorption_fact_res = m.methodParamsC.poison_absorption_fact[0];
                    res.col_poison_rod_a_res = m.methodParamsC.poison_rod_a[0].v;
                    res.col_poison_rod_a_err_res = m.methodParamsC.poison_rod_a[0].err;
                    res.col_poison_rod_b_res = m.methodParamsC.poison_rod_b[0].v;
                    res.col_poison_rod_b_err_res = m.methodParamsC.poison_rod_b[0].err;
                    res.col_poison_rod_c_res = m.methodParamsC.poison_rod_c[0].v;
                    res.col_poison_rod_c_err_res = m.methodParamsC.poison_rod_c[0].err;
                    res.col_u_mass_corr_fact_a_res =  m.methodParamsC.u_mass_corr_fact_a.v;
                    res.col_u_mass_corr_fact_a_err_res =  m.methodParamsC.u_mass_corr_fact_a.err;
                    res.col_u_mass_corr_fact_b_res =  m.methodParamsC.u_mass_corr_fact_b.v;
                    res.col_u_mass_corr_fact_b_err_res =  m.methodParamsC.u_mass_corr_fact_b.err;
                    res.col_sample_corr_fact_res =  m.methodParamsC.sample_corr_fact.v;
                    res.col_sample_corr_fact_err_res =  m.methodParamsC.sample_corr_fact.err;
                    byte[] b = new byte[INCC.DATE_TIME_LENGTH];
                    char[] a = m.methodParamsDetector.reference_date.ToString("yy.MM.dd").ToCharArray();
                    Encoding.ASCII.GetBytes(a, 0, a.Length, b, 0);
                    TransferUtils.Copy(b, res.col_reference_date_res);
                    res.col_relative_doubles_rate_res = m.methodParamsDetector.relative_doubles_rate;

                    byte[] bb = new byte[INCC.MAX_COLLAR_K5_PARAMETERS * INCC.MAX_K5_LABEL_LENGTH];
                    int indx = 0;
                    for (int i = 0; i < INCC.MAX_COLLAR_K5_PARAMETERS; i++)
                    {
                        char[] aa = m.methodParamsK5.k5_label[i].ToCharArray(0, Math.Min(m.methodParamsK5.k5_label[i].Length, INCC.MAX_K5_LABEL_LENGTH));
                        Encoding.ASCII.GetBytes(aa, 0, aa.Length, bb, indx);
                        indx += INCC.MAX_K5_LABEL_LENGTH;
                    }
                    TransferUtils.Copy(bb, 0, res.collar_k5_label_res, 0, INCC.MAX_COLLAR_K5_PARAMETERS * INCC.MAX_K5_LABEL_LENGTH);
                    TransferUtils.CopyBoolsToBytes(m.methodParamsK5.k5_checkbox, res.collar_k5_checkbox_res);
                    CopyTuples(m.methodParamsK5.k5, res.collar_k5_res, res.collar_k5_err_res, INCC.MAX_COLLAR_K5_PARAMETERS);
                }
                return res;
            }
コード例 #24
0
ファイル: INCCMeasurement.cs プロジェクト: hnordquist/INCC6
        /// <summary>
        /// after each cycle, run this cycle limit test and exit code
        /// </summary>
        /// <param name="seq"></param>
        /// <param name="mkey"></param>
        public static void CycleStatusTerminationCheck(this Measurement meas, Cycle cc)
        {
            bool stopAndComputeResults = meas.AcquireState.lm.SaveOnTerminate;
            IEnumerator iter = cc.CountingAnalysisResults.GetMultiplicityEnumerator();
            while (iter.MoveNext())
            {
                Multiplicity mkey = (Multiplicity)((KeyValuePair<SpecificCountingAnalyzerParams, object>)(iter.Current)).Key;
                MultiplicityCountingRes mcr = (MultiplicityCountingRes)((KeyValuePair<SpecificCountingAnalyzerParams, object>)(iter.Current)).Value;

                if (meas.MeasCycleStatus.num_checksum_failures > meas.Tests.maxNumFailures)
                {
                    meas.Logger.TraceEvent(NCCReporter.LogLevels.Warning, 7071, "Maximum checksum failure count met, cycle {0} {1}", cc.seq, mkey);
                    if (stopAndComputeResults)
                    {
                        // URGENT: set state to end of measurement so that state moves out of cycles and skips forward to CalculateMeasurementResults
                    }
                    else
                    {
                        // exit processing completely, do not compute or save results
                        NC.App.Opstate.Abort();
                    }
                }
                if (meas.MeasCycleStatus.num_acc_sngl_failures > meas.Tests.maxNumFailures)
                {
                    meas.Logger.TraceEvent(NCCReporter.LogLevels.Warning, 7072, "Maximum A/S failure count met, cycle {0} {1}", cc.seq, mkey);
                    // ditto above comment block
                }
                if (meas.MeasCycleStatus.num_high_voltage_failures > meas.Tests.maxNumFailures)
                {
                    meas.Logger.TraceEvent(NCCReporter.LogLevels.Warning, 7073, "Maximum checksum failure count met, cycle {0} {1}", cc.seq, mkey);
                    // ditto above comment block
                }
                if ((meas.MeasCycleStatus.num_acc_sngl_failures >= NUM_ACC_SNGL_WARNING) &&
                     (!meas.MeasCycleStatus.acc_sngl_warning_sent))
                {
                    meas.AddWarningMessage("At least " + meas.MeasCycleStatus.num_acc_sngl_failures + " A/S test failures", 7074, mkey);
                    meas.MeasCycleStatus.acc_sngl_warning_sent = true;
                }
                if ((meas.MeasCycleStatus.num_checksum_failures >= NUM_CHECKSUM_WARNING) &&
                    (!meas.MeasCycleStatus.checksum_warning_sent))
                {
                    meas.AddWarningMessage("At least " + meas.MeasCycleStatus.num_checksum_failures + " checksum failures", 7075, mkey);
                    meas.MeasCycleStatus.checksum_warning_sent = true;
                }
                if ((meas.MeasCycleStatus.num_high_voltage_failures >= NUM_HIGH_VOLTAGE_WARNING) &&
                    (!meas.MeasCycleStatus.high_voltage_warning_sent))
                {
                    meas.AddWarningMessage("At least " + meas.MeasCycleStatus.num_high_voltage_failures + " high voltage failures", 7076, mkey);
                    meas.MeasCycleStatus.high_voltage_warning_sent = true;
                }
                if (meas.AcquireState.acquire_type == AcquireConvergence.CycleCount)
                {
                    meas.MeasCycleStatus.acquire_num_runs = meas.MeasCycleStatus.initial_num_runs +
                        meas.MeasCycleStatus.num_outlier_failures + meas.MeasCycleStatus.num_acc_sngl_failures +
                        meas.MeasCycleStatus.num_checksum_failures;
                }
                else if (meas.Cycles.GetValidCycleCountForThisKey(mkey) < 100) // an arbitrary limit, make it a config item
                {
                    // URGENT: set state to end of measurement so that state moves out of cycles and skips forward to CalculateMeasurementResults
                    // todo: see take_data.cpp line 733 for mass check processing steps
                    if (meas.Cycles.GetValidCycleCountForThisKey(mkey) > 1)
                    {
                        INCCResult results;
                        MeasOptionSelector ar = new MeasOptionSelector(meas.MeasOption, mkey);
                        bool found = meas.INCCAnalysisResults.TryGetValue(ar, out results);
                        double error = 0;
                        if (meas.AcquireState.acquire_type == AcquireConvergence.DoublesPrecision)
                        {
                            if (results.rates.DTCRates.Doubles.v != 0.0)
                            {
                                error = results.rates.DTCRates.Doubles.err / results.rates.DTCRates.Doubles.v * 100.0;
                            }
                        }
                        else if (meas.AcquireState.acquire_type == AcquireConvergence.TriplesPrecision)
                        {
                            if (results.rates.DTCRates.Triples.v != 0.0)
                            {
                                error = results.rates.DTCRates.Triples.err / results.rates.DTCRates.Triples.v * 100.0;
                            }
                        }
                        else if (meas.AcquireState.acquire_type == AcquireConvergence.Pu240EffPrecision)
                        {
                            RatesAdjustments dtchoice = RatesAdjustments.Raw; // NEXT: design out this choice everywhere, it shoud be a flag on the current computational state somewhere
                            INCCMethodResults.results_multiplicity_rec res = INCCAnalysis.CalculateMultiplicity(mkey, results.covariance_matrix, results.rates.GetDTCRates(dtchoice), meas, dtchoice);
                            if (res != null)
                            {
                                // the results obtained within the method are already stored on the result and they do not need to be copied here (VERIFY THIS)
                                if (res.pu240e_mass.v != 0.0)
                                {
                                    error = res.pu240e_mass.err /
                                        res.pu240e_mass.v * 100.0;
                                }
                                else
                                    error = 0.0;
                            }
                        }

                        meas.MeasCycleStatus.acquire_num_runs = (uint)((double)cc.seq * (error / meas.AcquireState.meas_precision) * (error / meas.AcquireState.meas_precision)) + 1;
                        meas.MeasCycleStatus.acquire_num_runs += meas.MeasCycleStatus.num_outlier_failures +
                            meas.MeasCycleStatus.num_acc_sngl_failures + meas.MeasCycleStatus.num_checksum_failures;
                    }
                    else
                        meas.MeasCycleStatus.acquire_num_runs = meas.AcquireState.max_num_runs;
                    if (meas.MeasCycleStatus.acquire_num_runs > meas.AcquireState.max_num_runs)
                        meas.MeasCycleStatus.acquire_num_runs = meas.AcquireState.max_num_runs;
                    if (meas.MeasCycleStatus.acquire_num_runs < meas.AcquireState.min_num_runs)
                        meas.MeasCycleStatus.acquire_num_runs = meas.AcquireState.min_num_runs;
                }
            }
        }
コード例 #25
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
 internal static unsafe iresultsbase MoveDEMult(INCCAnalysisState ias, MeasOptionSelector mos)
 {
     results_de_mult_rec res = new results_de_mult_rec();
     INCCMethodResult result;
     bool found = ias.Results.TryGetMethodResults(mos.MultiplicityParams, ias.Methods.selector, AnalysisMethod.DUAL_ENERGY_MULT_SAVE_RESTORE, out result);
     if (found)
     {
         INCCMethodResults.results_de_mult_rec m = (INCCMethodResults.results_de_mult_rec)result;
         res.de_meas_ring_ratio = m.meas_ring_ratio;
         res.de_interpolated_neutron_energy = m.interpolated_neutron_energy;
         res.de_energy_corr_factor = m.energy_corr_factor;
         TransferUtils.CopyDbls(m.methodParams.neutron_energy, res.de_neutron_energy_res);
         TransferUtils.CopyDbls(m.methodParams.detector_efficiency, res.de_detector_efficiency_res);
         TransferUtils.CopyDbls(m.methodParams.inner_outer_ring_ratio, res.de_inner_outer_ring_ratio_res);
         TransferUtils.CopyDbls(m.methodParams.relative_fission, res.de_relative_fission_res);
         res.de_inner_ring_efficiency_res = m.methodParams.inner_ring_efficiency;
         res.de_outer_ring_efficiency_res = m.methodParams.outer_ring_efficiency;
         StrToBytes(INCC.MAX_DETECTOR_ID_LENGTH, ias.Methods.selector.detectorid, res.de_mult_detector_id);
         StrToBytes(INCC.MAX_ITEM_TYPE_LENGTH, ias.Methods.selector.material, res.de_mult_item_type);
     }
     return res;
 }
コード例 #26
0
ファイル: INCCMeasurement.cs プロジェクト: hnordquist/INCC6
        /// <summary>
        /// Calculate averages and sums for all cycles in a measurement that pass all tests
        /// Do processing for all the Multiplicity results across all the cycles of the current Measurement
        /// </summary>
        public static void CalcAvgAndSums(this Measurement meas)
        {
            RatesAdjustments dtchoice = RatesAdjustments.DeadtimeCorrected;

            if (NC.App.Opstate.IsAbortRequested)
                return;

            IEnumerator iter = meas.CountingAnalysisResults.GetMultiplicityEnumerator();
            while (iter.MoveNext())
            {
                Multiplicity mkey = (Multiplicity)((KeyValuePair<SpecificCountingAnalyzerParams, object>)(iter.Current)).Key;
                meas.Logger.TraceEvent(NCCReporter.LogLevels.Info, 7003, "Calculating averages and sums for valid cycles {0} {1}", dtchoice, mkey);
                MultiplicityCountingRes mcr = (MultiplicityCountingRes)meas.CountingAnalysisResults[mkey];
                mcr.ComputeHitSums();
                // APluralityOfMultiplicityAnalyzers: When a list mode sourced measurement is in use, and
                // cycle data comes from a prior analysis via a DB cycle source or Verification reanalysis,
                // doubles are computed using the LMSupport.SDTMultiplicityCalculator.
                // Note that DAQ LM sourced INCC5 analyses will have the unnormalized Acc distro.
                // The method INCCAnalysis.CalcAveragesAndSums uses the unnormalized
                // Acc distro (mcr.UnAMult), but in the two cases above there is only the normalized Acc and RealsAcc distros are present.
                // So the *unnormalized distro* must be computed and placed on each cycle, then and only then are doubles calculated correctly.
                INCCAnalysis.CalcAveragesAndSums(mkey, mcr, meas, dtchoice, meas.Detector.Id.SRType);
                mcr.Scaler1Rate.v = mcr.Scaler1.v;
                mcr.Scaler1Rate.err = mcr.Scaler1.err;
                mcr.Scaler2Rate.v = mcr.Scaler2.v;
                mcr.Scaler2Rate.err = mcr.Scaler2.err;
                MeasOptionSelector mos = new MeasOptionSelector(meas.MeasOption, mkey);
                INCCResult results = meas.INCCAnalysisState.Lookup(mos);
                if (results != null)
                {
                    results.Scaler1Rate.v = mcr.Scaler1.v;
                    results.Scaler1Rate.err = mcr.Scaler1.err;
                    results.Scaler2Rate.v = mcr.Scaler2.v;
                    results.Scaler2Rate.err = mcr.Scaler2.err;
                }
            }
        }
コード例 #27
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
 internal static unsafe iresultsbase MoveKnownA(INCCAnalysisState ias, MeasOptionSelector mos)
 {
     results_known_alpha_rec res = new results_known_alpha_rec();
     INCCMethodResult result;
     bool found = ias.Results.TryGetMethodResults(mos.MultiplicityParams, ias.Methods.selector, AnalysisMethod.KnownA, out result);
     if (found)
     {
         INCCMethodResults.results_known_alpha_rec m = (INCCMethodResults.results_known_alpha_rec)result;
         res.ka_mult = m.mult;
         res.ka_alpha = m.alphaK;
         res.ka_mult_corr_doubles = m.mult_corr_doubles.v;
         res.ka_mult_corr_doubles_err = m.mult_corr_doubles.err;
         res.ka_pu240e_mass = m.pu240e_mass.v;
         res.ka_pu240e_mass_err = m.pu240e_mass.err;
         res.ka_pu_mass = m.pu_mass.v;
         res.ka_pu_mass_err = m.pu_mass.err;
         res.ka_dcl_pu240e_mass = m.dcl_pu240e_mass;
         res.ka_dcl_minus_asy_pu_mass = m.dcl_minus_asy_pu_mass.v;
         res.ka_dcl_minus_asy_pu_mass_err = m.dcl_minus_asy_pu_mass.err;
         res.ka_dcl_minus_asy_pu_mass_pct = m.dcl_minus_asy_pu_mass_pct;
         StatePack(m.pass, res.ka_pass_fail);
         res.ka_dcl_u_mass = m.dcl_u_mass;
         res.ka_length = m.length;
         res.ka_heavy_metal_content = m.heavy_metal_content;
         res.ka_heavy_metal_correction = m.heavy_metal_correction;
         res.ka_corr_singles = m.corr_singles.v;
         res.ka_corr_singles_err = m.corr_singles.err;
         res.ka_corr_doubles = m.corr_doubles.v;
         res.ka_corr_doubles_err = m.corr_doubles.err;
         res.ka_corr_factor = m.corr_factor;
         res.ka_dry_alpha_or_mult_dbls = m.dry_alpha_or_mult_dbls;
         res.ka_alpha_wt_res = m.methodParams.alpha_wt;
         res.ka_rho_zero_res = m.methodParams.rho_zero;
         res.ka_k_res = m.methodParams.k;
         res.ka_a_res = m.methodParams.cev.a;
         res.ka_b_res = m.methodParams.cev.b;
         res.ka_var_a_res = m.methodParams.cev.var_a;
         res.ka_var_b_res = m.methodParams.cev.var_b;
         res.ka_covar_ab_res = m.methodParams.cev.covar(Coeff.a, Coeff.b);
         res.ka_sigma_x_res = m.methodParams.cev.sigma_x;
         res.ka_known_alpha_type_res = (double)m.methodParams.known_alpha_type;
         res.ka_heavy_metal_corr_factor_res = m.methodParams.heavy_metal_corr_factor;
         res.ka_heavy_metal_reference_res = m.methodParams.heavy_metal_reference;
         res.ka_lower_corr_factor_limit_res = m.methodParams.lower_corr_factor_limit;
         res.ka_upper_corr_factor_limit_res = m.methodParams.upper_corr_factor_limit;
         StrToBytes(INCC.MAX_DETECTOR_ID_LENGTH, ias.Methods.selector.detectorid, res.ka_known_alpha_detector_id);
         StrToBytes(INCC.MAX_ITEM_TYPE_LENGTH, ias.Methods.selector.material, res.ka_known_alpha_item_type);
     }
     return res;
 }
コード例 #28
0
ファイル: INCCMeasurement.cs プロジェクト: hnordquist/INCC6
        /// <summary>
        /// Save all updated and new results in the database
        /// </summary>
        public static void SaveMeasurementResults(this Measurement meas)
        {
            if (meas.Detector.ListMode)
            {
                long mid = meas.MeasurementId.UniqueId;
                foreach(SpecificCountingAnalyzerParams s in meas.CountingAnalysisResults.Keys)
                {
                    // this is a virtual LMSR so save each mkey
                    Type t = s.GetType();
                    DB.ElementList els = s.ToDBElementList();
                    if (t.Equals(typeof(Multiplicity)))
                    {
                        Multiplicity thisone = ((Multiplicity)s);
                        els.Add(new DB.Element("predelay", thisone.SR.predelay));
                    }
                    else if (t.Equals(typeof(Coincidence)))
                    {
                        Coincidence thisone = ((Coincidence)s);
                        els.Add(new DB.Element("predelay", thisone.SR.predelay));
                    }
                    DB.LMParamsRelatedBackToMeasurement counter = new DB.LMParamsRelatedBackToMeasurement(s.Table);
                    s.Rank = counter.Create(mid, els);
                    meas.Logger.TraceEvent(NCCReporter.LogLevels.Verbose, 34103, string.Format("Preserving {0}_m as {1}", s.Table, s.Rank));
                }
            }

            SaveMeasurementCycles(meas);

            IEnumerator iter = meas.CountingAnalysisResults.GetMultiplicityEnumerator();
            while (iter.MoveNext())
            {
                Multiplicity mkey = (Multiplicity)((KeyValuePair<SpecificCountingAnalyzerParams, object>)(iter.Current)).Key;
                if (NC.App.Opstate.IsAbortRequested)
                    return;

                INCCResult results;
                MeasOptionSelector moskey = new MeasOptionSelector(meas.MeasOption, mkey);
                bool found = meas.INCCAnalysisResults.TryGetValue(moskey, out results);  // APluralityOfMultiplicityAnalyzers: when does this actually get saved? It needs to be saved to DB after all calculations are complete

                try
                {
                    switch (meas.MeasOption)
                    {
                        case AssaySelector.MeasurementOption.background: // calculated in CalculateResults, update bkg and save the result to the DB
                            // save the background result to the bkg_parms_rec table under the current SR key
                            BackgroundParameters c = NC.App.DB.BackgroundParameters.Get(meas.Detector);
                            if (c != null)
                                c.Copy(meas.Background);  // copy changes back to original on user affirmation
                            else
                            {
                                c = meas.Background;
                                NC.App.DB.BackgroundParameters.GetMap().Add(meas.Detector, c);
                            }
                            NC.App.DB.BackgroundParameters.Set(meas.Detector, c);
                            break;
                        case AssaySelector.MeasurementOption.initial: // calculated in CalculateResults, update norm and save the norm and init_src result to the DB
                            INCCResults.results_init_src_rec results_init_src = (INCCResults.results_init_src_rec)results;
                            // on fail, only the relevant results_init_src_rec is saved
                            // on pass, the normalization parameters are modified with the results_init_src_rec results, and so both are updated.
                            if (results_init_src.pass)
                            {
                                NormParameters np = NC.App.DB.NormParameters.Get(meas.Detector);
                                if (np != null)
                                    np.Copy(meas.Norm);  // copy any changes made to Norm as defined for the current detector
                                else
                                {
                                    np = meas.Norm;
                                    NC.App.DB.NormParameters.GetMap().Add(meas.Detector, np);
                                }
                                NC.App.DB.NormParameters.Set(meas.Detector, np);
                            }
                            SaveSpecificResultsForThisMeasurement(meas, results);
                            break;
                        case AssaySelector.MeasurementOption.normalization:  // calculated in CalculateResults, now save the result to the DB
                        case AssaySelector.MeasurementOption.precision:      // ditto
                            SaveSpecificResultsForThisMeasurement(meas, results);
                            break;
                        case AssaySelector.MeasurementOption.calibration: // ditto with the method analyses results, but they're a bit different
                        case AssaySelector.MeasurementOption.verification:
                            SaveMethodResultsForThisMeasurement(meas, moskey);
                            break;
                        case AssaySelector.MeasurementOption.holdup: // NEXT: Hold-up held up, implement it #35
                            break;
                    }
                }
                catch (Exception e)
                {
                    meas.Logger.TraceException(e);
                }

                SaveSummaryResultsForThisMeasurement(meas, moskey);

            }

            meas.PersistFileNames();
        }
コード例 #29
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
 internal static unsafe iresultsbase MoveMult(INCCAnalysisState ias, MeasOptionSelector mos)
 {
     results_multiplicity_rec res = new results_multiplicity_rec();
     INCCMethodResult result;
     bool found = ias.Results.TryGetMethodResults(mos.MultiplicityParams, ias.Methods.selector, AnalysisMethod.Multiplicity, out result);
     if (found)
     {
         INCCMethodResults.results_multiplicity_rec m = (INCCMethodResults.results_multiplicity_rec)result;
         res.mul_mult = m.mult.v;
         res.mul_mult_err = m.mult.err;
         res.mul_alpha = m.alphaK.v;
         res.mul_alpha_err = m.alphaK.err;
         res.mul_corr_factor = m.alphaK.v;
         res.mul_corr_factor_err = m.alphaK.err;
         res.mul_efficiency = m.alphaK.v;
         res.mul_efficiency_err = m.alphaK.err;
         res.mul_pu240e_mass = m.pu240e_mass.v;
         res.mul_pu240e_mass_err = m.pu240e_mass.err;
         res.mul_pu_mass = m.pu_mass.v;
         res.mul_pu_mass_err = m.pu_mass.err;
         res.mul_dcl_pu240e_mass = m.dcl_pu240e_mass;
         res.mul_dcl_minus_asy_pu_mass = m.dcl_minus_asy_pu_mass.v;
         res.mul_dcl_minus_asy_pu_mass_err = m.dcl_minus_asy_pu_mass.err;
         res.mul_dcl_minus_asy_pu_mass_pct = m.dcl_minus_asy_pu_mass_pct;
         StatePack(m.pass, res.mul_pass_fail);
         res.mul_solve_efficiency_res = (byte)m.solve_efficiency_choice;
         res.mul_sf_rate_res = m.methodParams.sf_rate;
         res.mul_vs1_res = m.methodParams.vs1;
         res.mul_vs2_res = m.methodParams.vs2;
         res.mul_vs3_res = m.methodParams.vs3;
         res.mul_vi1_res = m.methodParams.vi1;
         res.mul_vi2_res = m.methodParams.vi2;
         res.mul_vi3_res = m.methodParams.vi3;
         res.mul_a_res = m.methodParams.a;
         res.mul_b_res = m.methodParams.b;
         res.mul_c_res = m.methodParams.c;
         res.mul_sigma_x_res = m.methodParams.sigma_x;
         res.mul_alpha_weight_res = m.methodParams.alpha_weight;
         StrToBytes(INCC.MAX_DETECTOR_ID_LENGTH, ias.Methods.selector.detectorid, res.mul_multiplicity_detector_id);
         StrToBytes(INCC.MAX_ITEM_TYPE_LENGTH, ias.Methods.selector.material, res.mul_multiplicity_item_type);
     }
     return res;
 }
コード例 #30
0
        // INCC5 enables subselecting each field and creates a two line header instead of one.
        Dictionary <string, string> GenerateEntries(Selections s, Measurement m)
        {
            Dictionary <string, string> entries = new Dictionary <string, string>();

            switch (s)
            {
            case Selections.AcquireParams:
                entries["Facility"]          = Q(m.AcquireState.facility.Name);
                entries["MBA"]               = Q(m.AcquireState.mba.Name);
                entries["Detector"]          = Q(m.AcquireState.detector_id);
                entries["IC"]                = Q(m.AcquireState.inventory_change_code);
                entries["IO"]                = Q(m.AcquireState.io_code);
                entries["Measurement Type"]  = Q(m.MeasOption.PrintName());
                entries["Meas Date"]         = m.MeasurementId.MeasDateTime.ToString("yy.MM.dd");
                entries["Meas Time"]         = m.MeasurementId.MeasDateTime.ToString("HH:mm:ss");
                entries["File Name"]         = Q(GetMainFilePath(m.ResultsFiles, m.MeasOption, true));
                entries["Inspector"]         = Q(m.AcquireState.user_id);
                entries["Inspection Number"] = Q(m.AcquireState.campaign_id);
                entries["Item ID"]           = Q(m.AcquireState.item_id);
                entries["Isotopics ID"]      = Q(m.AcquireState.isotopics_id);
                entries["Stratum ID"]        = Q(m.AcquireState.stratum_id.Name);
                entries["Material Type"]     = Q(m.AcquireState.item_type);
                break;

            case Selections.NormalizationParams:
                entries["Norm Cnst"]       = m.Norm.currNormalizationConstant.v.ToString("F4");           //	"Normalization constant"
                entries["Norm Cnst Error"] = m.Norm.currNormalizationConstant.err.ToString("F4");         //	"Normalization constant error"
                break;

            case Selections.BackgroundParams:
                entries["Singles Bkg"]         = m.Background.DeadtimeCorrectedSinglesRate.v.ToString("F1");   //	"Passive singles background"
                entries["Singles Bkg Error"]   = m.Background.DeadtimeCorrectedSinglesRate.err.ToString("F3"); //	"Passive singles background error"
                entries["Doubles Bkg"]         = m.Background.DeadtimeCorrectedDoublesRate.v.ToString("F2");   //	"Passive doubles background"
                entries["Doubles Bkg Error"]   = m.Background.DeadtimeCorrectedDoublesRate.err.ToString("F3"); //	"Passive doubles background error"
                entries["Triples Bkg"]         = m.Background.DeadtimeCorrectedTriplesRate.v.ToString("F2");   //	"Passive triples background"
                entries["Triples Bkg Error"]   = m.Background.DeadtimeCorrectedTriplesRate.err.ToString("F3"); //	"Passive triples background error"
                entries["Act Sngls Bkg"]       = m.Background.INCCActive.SinglesRate.ToString("F1");           //	"Active singles background"
                entries["Act Sngls Bkg Error"] = m.Background.INCCActive.Singles.err.ToString("F3");           //	"Active singles background error"
                break;

            case Selections.Summaries:
                if (m.INCCAnalysisState != null && m.INCCAnalysisResults != null)
                {
                    System.Collections.IEnumerator iter = m.INCCAnalysisResults.GetMeasSelectorResultsEnumerator();
                    while (iter.MoveNext())
                    {
                        MeasOptionSelector moskey = (MeasOptionSelector)iter.Current;
                        INCCResult         ir     = m.INCCAnalysisResults[moskey];
                        entries["Singles"]       = ir.DeadtimeCorrectedSinglesRate.v.ToString("F1");                   //	"Singles"
                        entries["Singles Error"] = ir.DeadtimeCorrectedSinglesRate.err.ToString("F3");                 //	"Singles error"
                        entries["Doubles"]       = ir.DeadtimeCorrectedDoublesRate.v.ToString("F2");                   //	"Doubles"
                        entries["Doubles Error"] = ir.DeadtimeCorrectedDoublesRate.err.ToString("F3");                 //	"Doubles error"
                        entries["Triples"]       = ir.DeadtimeCorrectedTriplesRate.v.ToString("F2");                   //	"Triples"
                        entries["Triples Error"] = ir.DeadtimeCorrectedTriplesRate.err.ToString("F3");                 //	"Triples error"
                        if (ir.Scaler1.v > 0 || ir.Scaler2.v > 0)
                        {
                            entries["Scaler 1"]       = ir.Scaler1.v.ToString("F1");
                            entries["Scaler 1 Error"] = ir.Scaler1.err.ToString("F3");
                            entries["Scaler 2"]       = ir.Scaler2.v.ToString("F1");
                            entries["Scaler 2 Error"] = ir.Scaler2.err.ToString("F3");
                        }
                        entries["Count Time"]  = (m.Cycles.Count > 0 ? m.Cycles[0].TS.TotalSeconds.ToString("F0") : "0"); // "Total count time for a measurement"
                        entries["Singles Sum"] = m.SinglesSum.ToString("F0");                                             // Sums - singles  Singles sum for a measurement"
                        entries["R+A Sum"]     = ir.RASum.ToString("F0");                                                 // Reals + accidentals sum for a measurement"
                        entries["A Sum"]       = ir.ASum.ToString("F0");                                                  // "Accidentals sum for a measurement"
                    }
                }
                break;

            case Selections.Comments:
                entries["Comment"] = m.AcquireState.comment;
                if (m.INCCAnalysisResults.TradResultsRec.acq.ending_comment &&
                    !string.IsNullOrEmpty(m.INCCAnalysisResults.TradResultsRec.acq.ending_comment_str))
                {
                    entries["End Comment"] = m.AcquireState.ending_comment_str;
                }
                break;

            case Selections.MassAnalysisMethods:
                break;

            case Selections.CalibrationCurve:
                INCCMethodResults.results_cal_curve_rec ccres = (INCCMethodResults.results_cal_curve_rec)
                                                                m.INCCAnalysisResults.LookupMethodResults(m.Detector.MultiplicityParams, m.INCCAnalysisState.Methods.selector, AnalysisMethod.CalibrationCurve, false);
                if (ccres != null)
                {
                    entries["Cal Cur Dcl Mass"]  = ccres.dcl_pu_mass.ToString("F2");               //	Calibration curve - declared mass"
                    entries["Cal Cur Mass"]      = ccres.pu_mass.v.ToString("F2");                 //	"Calibration curve - mass"
                    entries["Cal Cur Mass Err"]  = ccres.pu_mass.err.ToString("F3");               //	"Calibration curve - mass error"
                    entries["Cal Cur Dcl-Asy"]   = ccres.dcl_minus_asy_pu_mass.v.ToString("F2");   //	"Calibration curve - declared minus assay"
                    entries["Cal Cur Dcl-Asy %"] = ccres.dcl_minus_asy_pu_mass_pct.ToString("F2"); //	"Calibration curve - declared minus assay %"
                    entries["Cal Cur Status"]    = ccres.pass ? "Pass": "";                        //	"Calibration curve - measurement status"
                }
                break;

            case Selections.KnownAlpha:
                INCCMethodResults.results_known_alpha_rec kares = (INCCMethodResults.results_known_alpha_rec)
                                                                  m.INCCAnalysisResults.LookupMethodResults(m.Detector.MultiplicityParams, m.INCCAnalysisState.Methods.selector, AnalysisMethod.KnownA, false);
                if (kares != null)
                {
                    entries["Known A Dcl Mass"]  = kares.dcl_pu_mass.ToString("F2");               //	Known alpha - declared mass"
                    entries["Known A Mass"]      = kares.pu_mass.v.ToString("F2");                 //	"Known alpha - mass"
                    entries["Known A Mass Err"]  = kares.pu_mass.err.ToString("F3");               //	"Known alpha - mass error"
                    entries["Known A Dcl-Asy"]   = kares.dcl_minus_asy_pu_mass.v.ToString("F2");   //	"Known alpha - declared minus assay"
                    entries["Known A Dcl-Asy %"] = kares.dcl_minus_asy_pu_mass_pct.ToString("F2"); //	"Known alpha - declared minus assay %"
                    entries["Known A Mult"]      = kares.mult.ToString("F3");                      //	"Known alpha - multiplication"
                    entries["Known A Alpha"]     = kares.alphaK.ToString("F3");                    //	"Known alpha - alpha"
                    entries["Known A Status"]    = kares.pass ? "Pass": "";                        //	"Known alpha - measurement status"
                }
                break;

            case Selections.KnownM:
                INCCMethodResults.results_known_m_rec kmres = (INCCMethodResults.results_known_m_rec)
                                                              m.INCCAnalysisResults.LookupMethodResults(m.Detector.MultiplicityParams, m.INCCAnalysisState.Methods.selector, AnalysisMethod.KnownM, false);
                if (kmres != null)
                {
                    entries["Known M Dcl Mass"]  = kmres.dcl_pu_mass.ToString("F2");               //	Known M - declared mass"
                    entries["Known M Mass"]      = kmres.pu_mass.v.ToString("F2");                 //	"Known M - mass"
                    entries["Known M Mass Err"]  = kmres.pu_mass.err.ToString("F3");               //	"Known M - mass error"
                    entries["Known M Dcl-Asy"]   = kmres.dcl_minus_asy_pu_mass.v.ToString("F2");   //	"Known M - declared minus assay"
                    entries["Known M Dcl-Asy %"] = kmres.dcl_minus_asy_pu_mass_pct.ToString("F2"); //	"Known M - declared minus assay %"
                    entries["Known M Mult"]      = kmres.mult.ToString("F3");                      //	"Known M - multiplication"
                    entries["Known M Alpha"]     = kmres.alpha.ToString("F3");                     //	"Known M - alpha"
                    entries["Known M Status"]    = kmres.pass ? "Pass": "";                        //	"Known M - measurement status"
                }
                break;

            case Selections.Multiplicity:
                INCCMethodResults.results_multiplicity_rec mres = (INCCMethodResults.results_multiplicity_rec)
                                                                  m.INCCAnalysisResults.LookupMethodResults(m.Detector.MultiplicityParams, m.INCCAnalysisState.Methods.selector, AnalysisMethod.Multiplicity, false);
                if (mres != null)
                {
                    entries["Mult Dcl Mass"]    = mres.dcl_pu_mass.ToString("F2");               //	Multiplicity - declared mass"
                    entries["Mult Mass"]        = mres.pu_mass.v.ToString("F2");                 //	"Multiplicity- mass"
                    entries["Mult Mass Err"]    = mres.pu_mass.err.ToString("F3");               //	"Multiplicity - mass error"
                    entries["Mult Dcl-Asy"]     = mres.dcl_minus_asy_pu_mass.v.ToString("F2");   //	"Multiplicity - declared minus assay"
                    entries["Mult Dcl-Asy %"]   = mres.dcl_minus_asy_pu_mass_pct.ToString("F2"); //	"Multiplicity - declared minus assay %"
                    entries["Mult Mult"]        = mres.mult.v.ToString("F3");                    //	"Multiplicity - multiplication"
                    entries["Mult Mult Err"]    = mres.mult.err.ToString("F3");                  //	"Multiplicity - multiplication error"
                    entries["Mult Alpha"]       = mres.alphaK.v.ToString("F3");                  //	"Multiplicity - alpha"
                    entries["Mult Alpha Err"]   = mres.alphaK.err.ToString("F3");                //	"Multiplicity - alpha error"
                    entries["Mult Efficiency"]  = mres.efficiencyComputed.v.ToString("F3");      //	"Multiplicity - efficiency"
                    entries["Mult Eff Err"]     = mres.efficiencyComputed.err.ToString("F3");    //	"Multiplicity - efficiency error"
                    entries["Mult Status"]      = mres.pass ? "Pass": "";                        //	"Multiplicity - measurement status"
                    entries["Mult Predelay ms"] = m.Detector.SRParams.predelayMS.ToString();     //     "Multiplicity - predelay "
                    entries["Mult Gate ms"]     = m.Detector.SRParams.gateLengthMS.ToString();   //     "Multiplicity - gate width"
                }
                break;

            case Selections.AddASource:
                INCCMethodResults.results_add_a_source_rec aares = (INCCMethodResults.results_add_a_source_rec)
                                                                   m.INCCAnalysisResults.LookupMethodResults(m.Detector.MultiplicityParams, m.INCCAnalysisState.Methods.selector, AnalysisMethod.AddASource, false);
                if (aares != null)
                {
                    entries["Add-a-src Dcl Mass"]  = aares.dcl_pu_mass.ToString("F2");               //	Add-a-source - declared mass"
                    entries["Add-a-src Mass"]      = aares.pu_mass.v.ToString("F2");                 //	"Add-a-source - mass"
                    entries["Add-a-src Mass Err"]  = aares.pu_mass.err.ToString("F3");               //	"Add-a-source - mass error"
                    entries["Add-a-src Dcl-Asy"]   = aares.dcl_minus_asy_pu_mass.v.ToString("F2");   //	"Add-a-source - declared minus assay"
                    entries["Add-a-src Dcl-Asy %"] = aares.dcl_minus_asy_pu_mass_pct.ToString("F2"); //	"Add-a-source - declared minus assay %"
                    entries["Add-a-src Status"]    = aares.pass ? "Pass": "";                        //	"Add-a-source - measurement status"
                    entries["Add-a-src Corr"]      = aares.corr_factor.v.ToString("F3");             //	"Add-a-source - measurement status"
                }
                break;

            case Selections.CuriumRatio:
                INCCMethodResults.results_curium_ratio_rec cures = (INCCMethodResults.results_curium_ratio_rec)
                                                                   m.INCCAnalysisResults.LookupMethodResults(m.Detector.MultiplicityParams, m.INCCAnalysisState.Methods.selector, AnalysisMethod.CuriumRatio, false);
                if (cures != null)
                {
                    entries["Cm Ratio ID"]       = cures.methodParams2.cm_id;                               // Curium ratio - ID"
                    entries["Cm Ratio Input ID"] = cures.methodParams2.cm_input_batch_id;                   // Curium ratio - input batch ID"
                    entries["Cm Ratio Cm/Pu"]    = cures.methodParams2.cm_pu_ratio.v.ToString("F4");        // Curium ratio - Cm/Pu ratio"
                    entries["Cm Ratio Cm/U"]     = cures.methodParams2.cm_u_ratio.v.ToString("F4");         // Curium ratio - Cm/U ratio"
                    entries["Cm Mass"]           = cures.cm_mass.v.ToString("F3");                          // Curium ratio - Cm mass"
                    entries["Cm Err"]            = cures.cm_mass.err.ToString("F3");                        // Curium ratio - Cm mass error"

                    entries["Cm Ratio Pu Dcl Mass"]    = cures.pu.dcl_pu_mass.ToString("F2");               // Curium ratio - declared mass"
                    entries["Cm Ratio Pu Mass"]        = cures.pu.pu_mass.v.ToString("F2");                 //	"Curium ratio - mass"
                    entries["Cm Ratio Pu Mass Err"]    = cures.pu.pu_mass.err.ToString("F3");               //	"Curium ratio - mass error"
                    entries["Cm Ratio Pu Dcl-Asy"]     = cures.pu.dcl_minus_asy_pu_mass.v.ToString("F2");   //	"Curium ratio - declared minus assay"
                    entries["Cm Ratio Pu Dcl-Asy %"]   = cures.pu.dcl_minus_asy_pu_mass_pct.ToString("F2"); //	"Curium ratio - declared minus assay %"
                    entries["Cm Ratio U Dcl Mass"]     = cures.u.dcl_mass.ToString("F2");                   // "Curium ratio - U declared mass"
                    entries["Cm Ratio U Mass"]         = cures.u.mass.v.ToString("F2");                     //	"Curium ratio - U mass"
                    entries["Cm Ratio U Mass Err"]     = cures.u.mass.err.ToString("F3");                   //	"Curium ratio - U mass error"
                    entries["Cm Ratio U Dcl-Asy"]      = cures.u.dcl_minus_asy_mass.v.ToString("F2");       //	"Curium ratio - U declared minus assay"
                    entries["Cm Ratio U Dcl-Asy %"]    = cures.u.dcl_minus_asy_mass_pct.ToString("F2");     //	"Curium ratio - U declared minus assay %"
                    entries["Cm Ratio U235 Dcl Mass"]  = cures.u235.dcl_mass.ToString("F2");                // Curium ratio - U235 declared mass"
                    entries["Cm Ratio U235 Mass"]      = cures.u235.mass.v.ToString("F2");                  //	"Curium ratio - U235 mass"
                    entries["Cm Ratio U235 Mass Err"]  = cures.u235.mass.err.ToString("F3");                //	"Curium ratio - U235 mass error"
                    entries["Cm Ratio U235 Dcl-Asy"]   = cures.u235.dcl_minus_asy_mass.v.ToString("F2");    //	"Curium ratio - U235 declared minus assay"
                    entries["Cm Ratio U235 Dcl-Asy %"] = cures.u235.dcl_minus_asy_mass_pct.ToString("F2");  //	"Curium ratio - U235 declared minus assay %"
                    entries["Cm Ratio Pu Status"]      = cures.pu.pass ? "Pass": "";                        //	"Curium ratio - Pu measurement status"
                    entries["Cm Ratio U Status"]       = cures.u.pass ? "Pass": "";                         //	"Curium ratio - U measurement status"
                }
                break;

            case Selections.TruncatedMultiplicity:
                INCCMethodResults.results_truncated_mult_rec tmres = (INCCMethodResults.results_truncated_mult_rec)
                                                                     m.INCCAnalysisResults.LookupMethodResults(m.Detector.MultiplicityParams, m.INCCAnalysisState.Methods.selector, AnalysisMethod.TruncatedMultiplicity, false);
                if (tmres != null)
                {
                    entries["Trunc Mult Dcl Mass"] = tmres.k.dcl_mass.ToString("F2");               // "Truncated multiplicity - declared mass"
                    entries["Trunc Mult Mass"]     = tmres.k.pu_mass.v.ToString("F2");              // "Truncated multiplicity - mass"
                    entries["Trunc Mult Mass Err"] = tmres.k.pu_mass.err.ToString("F3");            // "Truncated multiplicity - mass error"
                    entries["Trunc Mult Dcl-Asy"]  = tmres.k.dcl_minus_asy_mass.v.ToString("F2");   // "Truncated multiplicity - declared minus assay"
                    entries["Trunc Dcl-Asy %"]     = tmres.k.dcl_minus_asy_mass_pct.ToString("F2"); //"Truncated multiplicity - declared minus assay %"
                    entries["Trunc Mult Status"]   = tmres.k.pass ? "Pass": "";                     // "Truncated multiplicity - measurement status"  // todo: what about 's'?
                }
                break;

            case Selections.ActiveCalibCurve:
                INCCMethodResults.results_active_rec acres = (INCCMethodResults.results_active_rec)
                                                             m.INCCAnalysisResults.LookupMethodResults(m.Detector.MultiplicityParams, m.INCCAnalysisState.Methods.selector, AnalysisMethod.Active, false);
                if (acres != null)
                {
                    entries["Active Dcl Mass"]  = acres.dcl_u235_mass.ToString("F2");               //	Active calibration curve - declared mass"
                    entries["Active Mass"]      = acres.u235_mass.v.ToString("F2");                 //	"Active calibration curve - mass"
                    entries["Active Mass Err"]  = acres.u235_mass.err.ToString("F3");               //	"Active calibration curve - mass error"
                    entries["Active Dcl-Asy"]   = acres.dcl_minus_asy_u235_mass.v.ToString("F2");   //	"Active calibration curve - declared minus assay"
                    entries["Active Dcl-Asy %"] = acres.dcl_minus_asy_u235_mass_pct.ToString("F2"); //	"Active calibration curve - declared minus assay %"
                    entries["Active Status"]    = acres.pass ? "Pass": "";                          //	"Active calibration curve - measurement status"
                }
                break;

            case Selections.CollarAmLi:
                INCCMethodResults.results_collar_rec rcres = (INCCMethodResults.results_collar_rec)
                                                             m.INCCAnalysisResults.LookupMethodResults(m.Detector.MultiplicityParams, m.INCCAnalysisState.Methods.selector, AnalysisMethod.CollarAmLi, false);
                if (rcres != null)
                {
                    entries["Collar Dbls Rate"]     = rcres.total_corr_fact.v.ToString("F2");           //	Collar - corrected doubles rate"
                    entries["Collar Dbls Rate Err"] = rcres.total_corr_fact.v.ToString("F2");           //	Collar -- corrected doubles rate error"
                    entries["Collar Dcl Mass"]      = rcres.dcl_total_u235.v.ToString("F2");            //	Collar - declared mass"
                    entries["Collar Mass"]          = rcres.u235_mass.v.ToString("F2");                 //	"Collar - mass"
                    entries["Collar Mass Err"]      = rcres.u235_mass.err.ToString("F3");               //	"Collar - mass error"
                    entries["Collar Dcl-Asy"]       = rcres.dcl_minus_asy_u235_mass.v.ToString("F2");   //	"Collar - declared minus assay"
                    entries["Collar Dcl-Asy %"]     = rcres.dcl_minus_asy_u235_mass_pct.ToString("F2"); //	"Collar - declared minus assay %"
                    entries["Collar Status"]        = rcres.pass ? "Pass": "";                          //	"Collar - measurement status"
                }
                break;

            case Selections.CollarCf:
                rcres = (INCCMethodResults.results_collar_rec)
                        m.INCCAnalysisResults.LookupMethodResults(m.Detector.MultiplicityParams, m.INCCAnalysisState.Methods.selector, AnalysisMethod.CollarCf, false);
                if (rcres != null)
                {
                    entries["Collar Dbls Rate"]     = rcres.total_corr_fact.v.ToString("F2");           //	Collar - corrected doubles rate"
                    entries["Collar Dbls Rate Err"] = rcres.total_corr_fact.v.ToString("F2");           //	Collar -- corrected doubles rate error"
                    entries["Collar Dcl Mass"]      = rcres.dcl_total_u235.v.ToString("F2");            //	Collar - declared mass"
                    entries["Collar Mass"]          = rcres.u235_mass.v.ToString("F2");                 //	"Collar - mass"
                    entries["Collar Mass Err"]      = rcres.u235_mass.err.ToString("F3");               //	"Collar - mass error"
                    entries["Collar Dcl-Asy"]       = rcres.dcl_minus_asy_u235_mass.v.ToString("F2");   //	"Collar - declared minus assay"
                    entries["Collar Dcl-Asy %"]     = rcres.dcl_minus_asy_u235_mass_pct.ToString("F2"); //	"Collar - declared minus assay %"
                    entries["Collar Status"]        = rcres.pass ? "Pass" : "";                         //	"Collar - measurement status"
                }
                break;

            default:
                break;
            }
            return(entries);
        }
コード例 #31
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
 // NEXT: confused with tm_bkg and bkg measurements
 internal static unsafe iresultsbase MoveTruncBkg(INCCAnalysisState ias, MeasOptionSelector mos)
 {
     results_tm_bkg_rec res = new results_tm_bkg_rec();
     INCCMethodResult result;
     bool found = ias.Results.TryGetMethodResults(mos.MultiplicityParams, ias.Methods.selector, AnalysisMethod.None, out result);
     if (found)
     {
         INCCMethodResults.results_tm_bkg_rec m = (INCCMethodResults.results_tm_bkg_rec)result;  // todo: tm bkg handling design incomplete
         res.results_tm_singles_bkg = m.methodParams.Singles.v;
         res.results_tm_singles_bkg_err = m.methodParams.Singles.err;
         res.results_tm_zeros_bkg = m.methodParams.Zeros.v;
         res.results_tm_zeros_bkg_err = m.methodParams.Zeros.err;
         res.results_tm_ones_bkg = m.methodParams.Ones.v;
         res.results_tm_ones_bkg_err = m.methodParams.Ones.err;
         res.results_tm_twos_bkg = m.methodParams.Twos.v;
         res.results_tm_twos_bkg_err = m.methodParams.Twos.err;
     }
     return res;
 }
コード例 #32
0
        /// <summary>
        /// Finalize measurement instance content for analysis
        /// Populate calibration parameters maps
        /// </summary>
        /// <param name="meas">The partially initialized measurement instance</param>
        /// <param name="useCurCalibParams">Default behavior is to use active method and other calibration parameters;
        ///                                 skipped if Reanalysis prepared the details from database measurement results
        /// </param>
        static public void FillInReanalysisRemainingDetails(Measurement meas, bool useCurCalibParams = true)
        {
            // get the current INCC5 analysis methods
            if (useCurCalibParams || meas.INCCAnalysisState == null)
            {
                meas.INCCAnalysisState = new INCCAnalysisState();
                INCCSelector    sel = new INCCSelector(meas.AcquireState.detector_id, meas.AcquireState.item_type);
                AnalysisMethods am;
                bool            found = CentralizedState.App.DB.DetectorMaterialAnalysisMethods.TryGetValue(sel, out am);
                if (found)
                {
                    am.selector = sel;                     // gotta do this so that the equality operator is not incorrect
                    meas.INCCAnalysisState.Methods = am;
                }
                else
                {
                    meas.INCCAnalysisState.Methods = new AnalysisMethods(sel);
                }
            }             // else use what was there

            meas.InitializeContext(clearCounterResults: false);
            meas.PrepareINCCResults();

            System.Collections.IEnumerator iter = meas.CountingAnalysisResults.GetATypedParameterEnumerator(typeof(Multiplicity));
            while (iter.MoveNext())
            {
                Multiplicity mkey = (Multiplicity)iter.Current;
                try
                {
                    MultiplicityCountingRes mcr = (MultiplicityCountingRes)meas.CountingAnalysisResults[mkey];
                    if (mcr.AB.Unset)
                    {
                        LMRawAnalysis.SDTMultiplicityCalculator.SetAlphaBeta(mkey, mcr);                         // works only if MaxBins is set
                    }
                    MeasOptionSelector mos    = new MeasOptionSelector(meas.MeasOption, mkey);
                    INCCResult         result = meas.INCCAnalysisState.Lookup(mos);
                    result.CopyFrom(mcr);
                }
                catch (Exception)
                {
                    //logger.TraceEvent(LogLevels.Error, 4027, "PrepareINCCResults error: " + ex.Message);
                }
            }

            // stratum look up, finds existing stratum by name
            if (useCurCalibParams || meas.Stratum == null)
            {
                List <INCCDB.StratumDescriptor> sl = CentralizedState.App.DB.StrataList();
                INCCDB.StratumDescriptor        s  = sl.Find(w => string.Compare(w.Desc.Name, meas.AcquireState.stratum_id.Name, true) == 0);
                if (s == null)
                {
                    meas.Stratum = new Stratum();
                }
                else
                {
                    meas.Stratum = new Stratum(s.Stratum);
                }
            }
            INCCResults.results_rec xres = new INCCResults.results_rec(meas);
            meas.INCCAnalysisResults.TradResultsRec  = xres;
            CentralizedState.App.Opstate.Measurement = meas;   // put the measurement definition on the global state
        }
コード例 #33
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
 public static unsafe List<INCCTransferFile> XFerFromMeasurements(List<Measurement> meas)
 {
     List<INCCTransferFile> list = new List<INCCTransferFile>();
     foreach (Measurement m in meas)
     {
         IEnumerator iter = m.CountingAnalysisResults.GetMultiplicityEnumerator();
         while (iter.MoveNext())                     // for each mkey, a seperate xfer file should be emitted
         {
             INCCTransferFile itf = new INCCTransferFile(NC.App.Loggers.Logger(LMLoggers.AppSection.Control), null);
             itf.Name = MethodResultsReport.EightCharConvert(m.MeasDate) + "." + m.MeasOption.INCC5Suffix();
             list.Add(itf);
             itf.results_rec_list.Add(Result5.MoveResultsRec(m));
             itf.results_status_list.Add(Result5.EncodeResultsStatus(m));
             Multiplicity mkey = (Multiplicity)((KeyValuePair<SpecificCountingAnalyzerParams, object>)(iter.Current)).Key;
             if (m.MeasOption >= AssaySelector.MeasurementOption.background && m.MeasOption <= AssaySelector.MeasurementOption.holdup)
             {
                 MeasOptionSelector mos = new MeasOptionSelector(m.MeasOption, mkey);
                 if (m.MeasOption == AssaySelector.MeasurementOption.initial)
                     itf.method_results_list.Add(Result5.MoveInitSrc(m.INCCAnalysisResults, mos));
                 else if (m.MeasOption == AssaySelector.MeasurementOption.normalization)
                     itf.method_results_list.Add(Result5.MoveBias(m.INCCAnalysisResults, mos));
                 else if (m.MeasOption == AssaySelector.MeasurementOption.precision)
                     itf.method_results_list.Add(Result5.MovePrecision(m.INCCAnalysisResults, mos));
                 else if (m.MeasOption == AssaySelector.MeasurementOption.background)
                     itf.method_results_list.Add(Result5.MoveTruncBkg(m.INCCAnalysisState, mos)); // NEXT: tm bkg, special case, unfinished
                 else if (m.MeasOption == AssaySelector.MeasurementOption.verification || m.MeasOption == AssaySelector.MeasurementOption.calibration)
                 {
                     itf.method_results_list.Add(Result5.MoveCalCurve(m.INCCAnalysisState, mos));
                     itf.method_results_list.Add(Result5.MoveKnownA(m.INCCAnalysisState, mos));
                     itf.method_results_list.Add(Result5.MoveKnownM(m.INCCAnalysisState, mos));
                     itf.method_results_list.Add(Result5.MoveMult(m.INCCAnalysisState, mos));
                     itf.method_results_list.Add(Result5.MoveDEMult(m.INCCAnalysisState, mos));
                     itf.method_results_list.Add(Result5.MoveActPass(m.INCCAnalysisState, mos));
                     itf.method_results_list.Add(Result5.MoveCollar(m.INCCAnalysisState, mos));
                     itf.method_results_list.Add(Result5.MoveActive(m.INCCAnalysisState, mos));
                     itf.method_results_list.Add(Result5.MoveActiveMult(m.INCCAnalysisState, mos));
                     itf.method_results_list.Add(Result5.MoveCurium(m.INCCAnalysisState, mos));
                     itf.method_results_list.Add(Result5.MoveTruncMult(m.INCCAnalysisState, mos));
                     itf.method_results_list.Add(Result5.MoveTruncBkg(m.INCCAnalysisState, mos)); // todo: here too, or just for bkg measurement?
                     itf.method_results_list.Add(Result5.MoveAAS(m.INCCAnalysisState, mos));
                 }
             }
             foreach (Cycle c in m.Cycles)
             {
                 itf.run_rec_list.Add(Result5.MoveCycleToRunRec(c, mkey));
             }
             if (m.MeasOption == AssaySelector.MeasurementOption.verification && m.INCCAnalysisState.Methods.HasMethod(AnalysisMethod.AddASource))
             {
                 itf.InitCFRunLists();
                 int aasp = 0;
                 foreach (CycleList cl in m.CFCycles)
                 {
                     foreach(Cycle cfc in cl)
                         itf.CFrun_rec_list[aasp].Add(Result5.MoveCycleToRunRec(cfc, mkey));
                     aasp++;
                 }
             }
         }
     }
     return list;
 }
コード例 #34
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
            internal static unsafe iresultsbase MoveAAS(INCCAnalysisState ias, MeasOptionSelector mos)
            {
                results_add_a_source_rec res = new results_add_a_source_rec();
                INCCMethodResult result;
                bool found = ias.Results.TryGetMethodResults(mos.MultiplicityParams, ias.Methods.selector, AnalysisMethod.AddASource, out result);
                if (found)
                {
                    INCCMethodResults.results_add_a_source_rec m = (INCCMethodResults.results_add_a_source_rec)result;
                    res.ad_dzero_cf252_doubles = m.dzero_cf252_doubles;
                    CopyTuples(m.sample_cf252_doubles, res.ad_sample_cf252_doubles, res.ad_sample_cf252_doubles_err, INCC.MAX_ADDASRC_POSITIONS);
                    TransferUtils.CopyDbls(m.sample_cf252_ratio, res.ad_sample_cf252_ratio);
                    res.ad_sample_avg_cf252_doubles = m.sample_avg_cf252_doubles.v;
                    res.ad_sample_avg_cf252_doubles_err = m.sample_avg_cf252_doubles.err;
                    res.ad_corr_doubles = m.corr_doubles.v;
                    res.ad_corr_doubles_err = m.corr_doubles.err;
                    res.ad_delta = m.delta.v;
                    res.ad_delta_err = m.delta.err;
                    res.ad_corr_factor = m.corr_factor.v;
                    res.ad_corr_factor_err = m.corr_factor.err;
                    res.ad_pu240e_mass = m.pu240e_mass.v;
                    res.ad_pu240e_mass_err = m.pu240e_mass.err;
                    res.ad_pu_mass = m.pu_mass.v;
                    res.ad_pu_mass_err = m.pu_mass.err;
                    res.ad_dcl_pu240e_mass = m.dcl_pu240e_mass;
                    res.ad_dcl_pu_mass = m.dcl_pu_mass;
                    res.ad_dcl_minus_asy_pu_mass = m.dcl_minus_asy_pu_mass.v;
                    res.ad_dcl_minus_asy_pu_mass_err = m.dcl_minus_asy_pu_mass.err;
                    res.ad_dcl_minus_asy_pu_mass_pct = m.dcl_minus_asy_pu_mass_pct;
                    StatePack(m.pass, res.ad_pass_fail);
                    res.ad_tm_corr_doubles = m.tm_corr_doubles.v;
                    res.ad_tm_corr_doubles_err = m.tm_corr_doubles.err;
                    res.ad_tm_doubles_bkg = m.tm_doubles_bkg.v;
                    res.ad_tm_doubles_bkg_err = m.tm_doubles_bkg.err;
                    res.ad_tm_uncorr_doubles = m.tm_uncorr_doubles.v;
                    res.ad_tm_uncorr_doubles_err = m.tm_uncorr_doubles.err;

                    res.ad_add_a_source_equation = (byte)m.methodParams.cev.cal_curve_equation;
                    res.ad_a_res = m.methodParams.cev.a;
                    res.ad_b_res = m.methodParams.cev.b;
                    res.ad_c_res = m.methodParams.cev.c;
                    res.ad_d_res = m.methodParams.cev.d;
                    res.ad_covar_ab_res = m.methodParams.cev.covar(Coeff.a, Coeff.b);
                    res.ad_covar_ac_res = m.methodParams.cev.covar(Coeff.a, Coeff.c);
                    res.ad_covar_ad_res = m.methodParams.cev.covar(Coeff.a, Coeff.d);
                    res.ad_covar_bc_res = m.methodParams.cev.covar(Coeff.b, Coeff.c);
                    res.ad_covar_bd_res = m.methodParams.cev.covar(Coeff.b, Coeff.d);
                    res.ad_covar_cd_res = m.methodParams.cev.covar(Coeff.c, Coeff.d);
                    res.ad_var_a_res = m.methodParams.cev.var_a;
                    res.ad_var_b_res = m.methodParams.cev.var_b;
                    res.ad_var_c_res = m.methodParams.cev.var_c;
                    res.ad_var_d_res = m.methodParams.cev.var_d;
                    res.ad_sigma_x_res = m.methodParams.cev.sigma_x;
                    TransferUtils.CopyDbls(m.methodParams.position_dzero, res.ad_position_dzero_res);
                    res.ad_dzero_avg_res = m.methodParams.dzero_avg;
                    byte[] b = new byte[INCC.DATE_TIME_LENGTH];
                    char[] a = m.methodParams.dzero_ref_date.ToString("yy.MM.dd").ToCharArray();
                    Encoding.ASCII.GetBytes(a, 0, a.Length, b, 0);
                    TransferUtils.Copy(b, res.ad_dzero_ref_date_res);
                    res.ad_num_runs_res = m.methodParams.num_runs;
                    res.ad_cf_a_res = m.methodParams.cf.a;
                    res.ad_cf_b_res = m.methodParams.cf.b;
                    res.ad_cf_c_res = m.methodParams.cf.c;
                    res.ad_cf_d_res = m.methodParams.cf.d;
                    res.ad_use_truncated_mult_res = (m.methodParams.use_truncated_mult ? 1 : 0);
                    res.ad_tm_weighting_factor_res = m.methodParams.tm_weighting_factor;
                    res.ad_tm_dbls_rate_upper_limit_res = m.methodParams.tm_dbls_rate_upper_limit;
                    StrToBytes(INCC.MAX_DETECTOR_ID_LENGTH, ias.Methods.selector.detectorid, res.ad_add_a_source_detector_id);
                    StrToBytes(INCC.MAX_ITEM_TYPE_LENGTH, ias.Methods.selector.material, res.ad_add_a_source_item_type);
                }
                return res;
            }
コード例 #35
0
ファイル: Central.cs プロジェクト: hnordquist/INCC6
        /// <summary>
        /// Finalize measurement instance content for analysis
        /// Populate calibration parameters maps
        /// </summary>
        /// <param name="meas">The partially initialized measurement instance</param>
        /// <param name="useCurCalibParams">Default behavior is to use active method and other calibration parameters;
        ///                                 skipped if Reanalysis prepared the details from database measurement results
        /// </param>
        public static void FillInReanalysisRemainingDetails(Measurement meas, bool useCurCalibParams = true)
        {
            // get the current INCC5 analysis methods
            if (useCurCalibParams || meas.INCCAnalysisState == null)
            {
                meas.INCCAnalysisState = new INCCAnalysisState();
                INCCSelector sel = new INCCSelector(meas.AcquireState.detector_id, meas.AcquireState.item_type);
                AnalysisMethods am;
                bool found = CentralizedState.App.DB.DetectorMaterialAnalysisMethods.TryGetValue(sel, out am);
                if (found)
                {
                    am.selector = sel; // gotta do this so that the equality operator is not incorrect
                    meas.INCCAnalysisState.Methods = am;
                }
                else
                    meas.INCCAnalysisState.Methods = new AnalysisMethods(sel);
            } // else use what was there

            meas.InitializeContext(clearCounterResults:false);
            meas.PrepareINCCResults();

            System.Collections.IEnumerator iter = meas.CountingAnalysisResults.GetATypedParameterEnumerator(typeof(Multiplicity));
            while (iter.MoveNext())
            {
                Multiplicity mkey = (Multiplicity)iter.Current;
                try
                {
             					MultiplicityCountingRes mcr = (MultiplicityCountingRes)meas.CountingAnalysisResults[mkey];
                    if (mcr.AB.Unset)
                        LMRawAnalysis.SDTMultiplicityCalculator.SetAlphaBeta(mkey, mcr); // works only if MaxBins is set
                    MeasOptionSelector mos = new MeasOptionSelector(meas.MeasOption, mkey);
                    INCCResult result = meas.INCCAnalysisState.Lookup(mos);
                    result.CopyFrom(mcr);
                }
                catch (Exception)
                {
                    //logger.TraceEvent(LogLevels.Error, 4027, "PrepareINCCResults error: " + ex.Message);
                }
            }

            // stratum look up, finds existing stratum by name
            if (useCurCalibParams || meas.Stratum == null)
            {
                List<INCCDB.StratumDescriptor> sl = CentralizedState.App.DB.StrataList();
                INCCDB.StratumDescriptor s = sl.Find(w => string.Compare(w.Desc.Name, meas.AcquireState.stratum_id.Name, true) == 0);
                if (s == null)
                    meas.Stratum = new Stratum();
                else
                    meas.Stratum = new Stratum(s.Stratum);
            }
            INCCResults.results_rec xres = new INCCResults.results_rec(meas);
            meas.INCCAnalysisResults.TradResultsRec = xres;
            CentralizedState.App.Opstate.Measurement = meas;   // put the measurement definition on the global state
        }
コード例 #36
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
 internal static unsafe iresultsbase MoveActiveMult(INCCAnalysisState ias, MeasOptionSelector mos)
 {
     results_active_mult_rec res = new results_active_mult_rec();
     INCCMethodResult result;
     bool found = ias.Results.TryGetMethodResults(mos.MultiplicityParams, ias.Methods.selector, AnalysisMethod.ActiveMultiplicity, out result);
     if (found)
     {
         INCCMethodResults.results_active_mult_rec m = (INCCMethodResults.results_active_mult_rec)result;
         res.am_mult = m.mult.v;
         res.am_mult_err = m.mult.err;
         res.am_vt1_res = m.methodParams.vt1;
         res.am_vt2_res = m.methodParams.vt2;
         res.am_vt3_res = m.methodParams.vt3;
         res.am_vf1_res = m.methodParams.vf1;
         res.am_vf2_res = m.methodParams.vf2;
         res.am_vf3_res = m.methodParams.vf3;
         StrToBytes(INCC.MAX_DETECTOR_ID_LENGTH, ias.Methods.selector.detectorid, res.am_mult_detector_id);
         StrToBytes(INCC.MAX_ITEM_TYPE_LENGTH, ias.Methods.selector.material, res.am_mult_item_type);
     }
     return res;
 }
コード例 #37
0
        protected Section ConstructReportSection(INCCReportSection section, MeasOptionSelector moskey, INCCResult ir, Detector det)
        {
            INCCStyleSection sec = null;
            try
            {
                switch (section)
                {

                    // NEXT: in progress, an identical copy of full INCC report sections
                    case INCCReportSection.SummedRawData:
                        sec = new INCCStyleSection(null, 1, INCCStyleSection.ReportSection.Summary);
                        sec.SetFPCurrentFormatPrecision(0);
                        sec.AddHeader(String.Format("{0} summed raw data",meas.INCCAnalysisState.Methods.HasActiveSelected() || meas.INCCAnalysisState.Methods.HasActiveMultSelected()?"Active":"Passive"));  // section header
                        sec.AddNumericRow("Shift register singles sum:", meas.SinglesSum);
                        sec.AddNumericRow("Shift register reals + accidentals sum:", ir.RASum);
                        sec.AddNumericRow("Shift register accidentals sum:", ir.ASum);
                        if (!det.Id.source.UsingVirtualSRCounting(det.Id.SRType))
                        {
                            sec.AddNumericRow("Shift register 1st scaler sum:", ir.S1Sum);
                            sec.AddNumericRow("Shift register 2nd scaler sum:", ir.S2Sum);
                        }
                        break;

                    case INCCReportSection.SummedRA:
                        sec = new INCCStyleSection(null, 1, INCCStyleSection.ReportSection.MultiColumn);
                        sec.AddHeader(String.Format("{0} summed multiplicity distributions",meas.INCCAnalysisState.Methods.HasActiveSelected() || meas.INCCAnalysisState.Methods.HasActiveMultSelected()?"Active":"Passive"));  // section header
                        int[] srawidths = new int[] { 5, 12, 12 };
                        int minbin, maxbin;
                        minbin = Math.Min(ir.RAMult.Length, ir.NormedAMult.Length);
                        maxbin = Math.Max(ir.RAMult.Length, ir.NormedAMult.Length);
                        sec.AddColumnRowHeader(new string[] { " ", "R+A sums", "A sums" }, srawidths);
                        for (int i = 0; i < minbin; i++)
                            sec.AddColumnRow(new ulong[] { (ulong)i, ir.RAMult[i], ir.NormedAMult[i] }, srawidths);
                        for (int i = minbin; i < maxbin; i++)  // check for uneven column
                        {
                            ulong[] potential = new ulong[3];
                            potential[0] = (ulong)i;
                            if (i < ir.RAMult.Length)
                                potential[1] = ir.RAMult[i];
                            if (i < ir.NormedAMult.Length)
                                potential[2] = ir.NormedAMult[i];
                            sec.AddColumnRow(potential, srawidths);
                        }
                        break;

                    case INCCReportSection.MassResults:
                        sec = new INCCStyleSection(null, 1, INCCStyleSection.ReportSection.MethodResults);
                        //Results are not always passive. Boo.
                        sec.AddHeader(String.Format("{0} Results",meas.INCCAnalysisState.Methods.HasActiveSelected() || meas.INCCAnalysisState.Methods.HasActiveMultSelected()?"Active":"Passive"));  // section header
                        sec.AddNumericRow("Singles:", ir.DeadtimeCorrectedSinglesRate);
                        sec.AddNumericRow("Doubles:", ir.DeadtimeCorrectedDoublesRate);
                        sec.AddNumericRow("Triples:", ir.DeadtimeCorrectedTriplesRate);
                        //changed to DTC rates.  Raw rates meaningless here hn 11.5.2014
                        //sec.AddNumericRow("Quads:", mcr.DeadtimeCorrectedQuadsRate); // todo: quads delayed until pents are ready per DN
                        if (!det.Id.source.UsingVirtualSRCounting(det.Id.SRType))
                        {
                            sec.AddNumericRow("Scaler 1:", ir.Scaler1);
                            sec.AddNumericRow("Scaler 2:", ir.Scaler2);
                        }

                        //if (det.Id.SRType >= LMDAQ.InstrType.NPOD)
                        //{
                        //    sec.Add(new Row()); // blank line
                        //    sec.AddNumericRow("Dyt. Singles:", ir.DytlewskiCorrectedSinglesRate);
                        //    sec.AddNumericRow("Dyt. Doubles:", ir.DytlewskiCorrectedDoublesRate);
                        //    sec.AddNumericRow("Dyt. Triples:", ir.DytlewskiCorrectedTriplesRate);
                        //}
                        break;
                    case INCCReportSection.MethodResultsAndParams:
                        // ir contains the measurement option-specific results: empty for rates and holdup, and also empty for calib and verif, the method-focused analyses, 
                        // but values are present for initial, normalization, precision, and should be present for background for the tm bkg results 
                        List<Row> rl = ir.ToLines(meas);
                        sec = new INCCStyleSection(null, 0, INCCStyleSection.ReportSection.MethodResults);
                        sec.AddRange(rl);

                        switch (meas.MeasOption)
                        {
                            case AssaySelector.MeasurementOption.background:
                                if (meas.Background.TMBkgParams.ComputeTMBkg)
                                    ctrllog.TraceEvent(LogLevels.Warning, 82010, "Background truncated multiplicity"); // todo: present the tm bkg results on m.Background
                                break;
                            case AssaySelector.MeasurementOption.initial:
                            case AssaySelector.MeasurementOption.normalization:
                            case AssaySelector.MeasurementOption.precision:
                                break;
                            case AssaySelector.MeasurementOption.verification:
                            case AssaySelector.MeasurementOption.calibration:
                                {
                                    INCCMethodResults imrs;
                                    bool beendonegot = meas.INCCAnalysisResults.TryGetINCCResults(moskey.MultiplicityParams, out imrs);
                                    if (beendonegot && imrs.Count > 0) // should be true for verification and calibration
                                    {
                                        // we've got a distinct detector id and material type on the methods, so that is the indexer here
                                        Dictionary<AnalysisMethod, INCCMethodResult> amimr = imrs[meas.INCCAnalysisState.Methods.selector];

                                        // now get an enumerator over the map of method results
                                        Dictionary<AnalysisMethod, INCCMethodResult>.Enumerator ai = amimr.GetEnumerator();
                                        while (ai.MoveNext())
                                        {
                                            INCCMethodResult imr = ai.Current.Value;
                                            // show the primaryMethod
                                            if (ai.Current.Key.Equals(imrs.primaryMethod))
                                            {
                                                sec.Add(new Row());
                                                Row rh = new Row();
                                                rh.Add(0, "            PRIMARY RESULT");
                                                sec.Add(rh);
                                            }
                                            rl = imr.ToLines(meas);
                                            sec.AddRange(rl);
                                            // todo: optional use of END_PRIMARY_RESULT as in some INCC report formats, but not others
                                        }
                                    }
                                }
                                break;
                            case AssaySelector.MeasurementOption.rates:
                            case AssaySelector.MeasurementOption.holdup:
                            case AssaySelector.MeasurementOption.unspecified:
                            default: // nothing new to present with these
                                break;
                        }
                        break;
                    case INCCReportSection.RawCycles:
                        sec = new INCCStyleSection(null, 1, INCCStyleSection.ReportSection.MultiColumn);
                        sec.AddHeader(String.Format("{0} cycle raw data",meas.INCCAnalysisState.Methods.HasActiveSelected() || meas.INCCAnalysisState.Methods.HasActiveMultSelected()?"Active":"Passive"));  // section header
                        int[] crdwidths = new int[] { 5, 10, 10, 10, 10, 10, 10 };
                        sec.AddColumnRowHeader(new string[] { "Cycle", "Singles", "R+A  ", "A    ", "Scaler1", "Scaler2", "QC Tests" }, crdwidths);
                        foreach (Cycle cyc in meas.Cycles)
                        {
                            // if no results on the cycle, these map indexers throw
                            if (cyc.CountingAnalysisResults.GetResultsCount(typeof(Multiplicity)) > 0)                            // if no results on the cycle, these map indexers throw
                            {
                                MultiplicityCountingRes mcr = (MultiplicityCountingRes)cyc.CountingAnalysisResults[moskey.MultiplicityParams];
                                sec.AddCycleColumnRow(cyc.seq,
                                    new ulong[] { (ulong)mcr.Totals, (ulong)mcr.RASum, (ulong)mcr.ASum, (ulong)mcr.Scaler1.v, (ulong)mcr.Scaler2.v },
                                    meas.AcquireState.qc_tests?cyc.QCStatus(moskey.MultiplicityParams).INCCString():"Off", crdwidths);
                            }
                        }
                        break;
                    case INCCReportSection.DTCRateCycles:
                       
                        sec = new INCCStyleSection(null, 1, INCCStyleSection.ReportSection.MultiColumn);
                        sec.AddHeader(String.Format("{0} cycle DTC rate data",meas.AcquireState.well_config == WellConfiguration.Active?"Active":"Passive"));  // section header
                        int[] crawidths = new int[] { 5, 13, 13, 13, 13, 10 };
                        sec.AddColumnRowHeader(new string[] { "Cycle", "Singles", "Doubles", "Triples", "Mass", "QC Tests" }, crawidths);
                        
                        foreach (Cycle cyc in meas.Cycles)
                        {
                            if (cyc.CountingAnalysisResults.GetResultsCount(typeof(Multiplicity)) > 0)                            // if no results on the cycle, these map indexers throw
                            {
                                MultiplicityCountingRes mcr = (MultiplicityCountingRes)cyc.CountingAnalysisResults[moskey.MultiplicityParams];
                                //These debug rows show raw rates for comparison hn 10.30
                                //sec.AddCycleColumnRow(cyc.seq,
                                    //Again, could be wrong.
                                //    new double[] { mcr.RawSinglesRate.v, mcr.RawDoublesRate.v, -1, -1 },
                                //     cyc.QCStatus(moskey.MultiplicityParams).INCCString(), crawidths); 
                                    //Again, could be wrong.
                               // TODO: Am actually printing out the DTC rates per cycle.  This seems to work in all cases EXCEPT "precision" hn 11.5
                                sec.AddCycleColumnRow(cyc.seq,
                                     // Using the corrected rates!
                                     new double[] { mcr.DeadtimeCorrectedSinglesRate.v, mcr.DeadtimeCorrectedDoublesRate.v, mcr.DeadtimeCorrectedTriplesRate.v, mcr.mass/*Mass*/ },
                                      meas.AcquireState.qc_tests?cyc.QCStatus(moskey.MultiplicityParams).INCCString():"Off", crawidths);
                            }
                        }
                        break;
                    case INCCReportSection.MultiplicityDistributions:
                        sec = new INCCStyleSection(null, 1, INCCStyleSection.ReportSection.MultiColumn);
                        sec.AddHeader(String.Format("{0} multiplicity distributions for each cycle",meas.INCCAnalysisState.Methods.HasActiveSelected() || meas.INCCAnalysisState.Methods.HasActiveMultSelected()?"Active":"Passive"));  // section header
                        int[] csrawidths = new int[] { 6, 12, 12 };
                        foreach (Cycle cyc in meas.Cycles)
                        {
                            if (cyc.CountingAnalysisResults.GetResultsCount(typeof(Multiplicity)) > 0)                            // if no results on the cycle, these map indexers throw
                            {
                                MultiplicityCountingRes mcr = (MultiplicityCountingRes)cyc.CountingAnalysisResults[moskey.MultiplicityParams];
                                minbin = Math.Min(mcr.RAMult.Length, mcr.NormedAMult.Length);
                                maxbin = Math.Max(mcr.RAMult.Length, mcr.NormedAMult.Length);
                                sec.AddColumnRowHeader(new string[] { "Cycle " + cyc.seq, "R+A ", "A   " }, csrawidths);
                                for (int i = 0; i < minbin; i++)
                                    sec.AddColumnRow(new ulong[] { (ulong)i, mcr.RAMult[i], mcr.NormedAMult[i] }, csrawidths);
                                for (int i = minbin; i < maxbin; i++)  // check for uneven column
                                {
                                    ulong[] potential = new ulong[3];
                                    potential[0] = (ulong)i;
                                    if (i < mcr.RAMult.Length)
                                        potential[1] = mcr.RAMult[i];
                                    if (i < mcr.NormedAMult.Length)
                                        potential[2] = mcr.NormedAMult[i];
                                    sec.AddColumnRow(potential, csrawidths);
                                }
                            }
                            sec.Add(new Row());// blank
                        }
                        break;
                    default:
                        break;
                }
            }
            catch (Exception e)
            {
                ctrllog.TraceException(e);
            }
            return sec;
        }
コード例 #38
0
ファイル: INCCKnew.cs プロジェクト: hnordquist/INCC6
 internal static unsafe iresultsbase MoveActPass(INCCAnalysisState ias, MeasOptionSelector mos)
 {
     results_active_passive_rec res = new results_active_passive_rec();
     INCCMethodResult result;
     bool found = ias.Results.TryGetMethodResults(mos.MultiplicityParams, ias.Methods.selector, AnalysisMethod.ActivePassive, out result);
     if (found)
     {
         INCCMethodResults.results_active_passive_rec m = (INCCMethodResults.results_active_passive_rec)result;
         res.ap_delta_doubles = m.delta_doubles.v;
         res.ap_delta_doubles_err = m.delta_doubles.err;
         res.ap_u235_mass = m.u235_mass.v;
         res.ap_u235_mass_err = m.u235_mass.err;
         res.ap_k0 = m.k0.v;
         res.ap_k1 = m.k1.v;
         res.ap_k1_err = m.k1.err;
         res.ap_k = m.k.v;
         res.ap_k_err = m.k.err;
         res.ap_dcl_u235_mass = m.dcl_u235_mass;
         res.ap_dcl_minus_asy_u235_mass = m.dcl_minus_asy_u235_mass.v;
         res.ap_dcl_minus_asy_u235_mass_err = m.dcl_minus_asy_u235_mass.err;
         res.ap_dcl_minus_asy_u235_mass_pct = m.dcl_minus_asy_u235_mass_pct;
         StatePack(m.pass, res.ap_pass_fail);
         res.ap_active_passive_equation = (byte)m.methodParams.cev.cal_curve_equation;
         res.ap_a_res = m.methodParams.cev.a;
         res.ap_b_res = m.methodParams.cev.b;
         res.ap_c_res = m.methodParams.cev.c;
         res.ap_d_res = m.methodParams.cev.d;
         res.ap_covar_ab_res = m.methodParams.cev.covar(Coeff.a, Coeff.b);
         res.ap_covar_ac_res = m.methodParams.cev.covar(Coeff.a, Coeff.c);
         res.ap_covar_ad_res = m.methodParams.cev.covar(Coeff.a, Coeff.d);
         res.ap_covar_bc_res = m.methodParams.cev.covar(Coeff.b, Coeff.c);
         res.ap_covar_bd_res = m.methodParams.cev.covar(Coeff.b, Coeff.d);
         res.ap_covar_cd_res = m.methodParams.cev.covar(Coeff.c, Coeff.d);
         res.ap_var_a_res = m.methodParams.cev.var_a;
         res.ap_var_b_res = m.methodParams.cev.var_b;
         res.ap_var_c_res = m.methodParams.cev.var_c;
         res.ap_var_d_res = m.methodParams.cev.var_d;
         res.ap_sigma_x_res = m.methodParams.cev.sigma_x;
         StrToBytes(INCC.MAX_DETECTOR_ID_LENGTH, ias.Methods.selector.detectorid, res.ap_active_passive_detector_id);
         StrToBytes(INCC.MAX_ITEM_TYPE_LENGTH, ias.Methods.selector.material, res.ap_active_passive_item_type);
     }
     return res;
 }
コード例 #39
0
        protected Section ConstructReportSection(INCCTestDataSection section, Detector det, MeasOptionSelector moskey = null)
        {
            INCCTestDataStyle sec = null;
            try
            {
                switch (section)
                {
                    case INCCTestDataSection.CycleSummary:
                        sec = new INCCTestDataStyle(null, 0);
                        sec.AddOne( (Int32)meas.Cycles.GetValidCycleCountForThisKey(moskey.MultiplicityParams)); // could also use CycleList length but CycleList can be longer when a reanalysis occurs and the analysis processing stops short of the end of the list due to modified termination conditions
                        sec.AddOne( (Int32)(meas.Cycles.Count > 0 ? meas.Cycles[0].TS.TotalSeconds : 0.0));
                        break;

                    default:
                        break;
                }
            }
            catch (Exception e)
            {
                ctrllog.TraceException(e);
            }
            return sec;
        }
コード例 #40
0
        // Based on the measurement type and result, show a bunch of stuff
        void FieldFiller()
        {
            Measurement m    = N.App.Opstate.Measurement;
            int         rep  = m.CountingAnalysisResults.GetResultsCount(typeof(Multiplicity));
            int         i    = 0;
            IEnumerator iter = m.CountingAnalysisResults.GetMultiplicityEnumerator();

            while (iter.MoveNext())
            {
                i++;
                string             augmenter = (rep > 1 ? " " + i.ToString() : ""); // use mkey indicator here, not just this indexer
                Multiplicity       mkey      = (Multiplicity)((KeyValuePair <SpecificCountingAnalyzerParams, object>)(iter.Current)).Key;
                INCCResult         r;
                MeasOptionSelector moskey = new MeasOptionSelector(m.MeasOption, mkey);
                bool found = m.INCCAnalysisResults.TryGetValue(moskey, out r);  // APluralityOfMultiplicityAnalyzers:
                switch (m.MeasOption)
                {
                case AssaySelector.MeasurementOption.rates:
                case AssaySelector.MeasurementOption.background:
                    //if (passive)
                    listView1.Items.Add(new ListViewItem(new string[] { "Passive rates" + augmenter }));
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format(" Singles: {0,13:F3} +- {1,9:F3}", r.DeadtimeCorrectedSinglesRate.v, r.DeadtimeCorrectedSinglesRate.err)
                    }));
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format(" Doubles: {0,13:F3} +- {1,9:F3}", r.DeadtimeCorrectedDoublesRate.v, r.DeadtimeCorrectedDoublesRate.err)
                    }));
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format(" Triples: {0,13:F3} +- {1,9:F3}", r.DeadtimeCorrectedTriplesRate.v, r.DeadtimeCorrectedTriplesRate.err)
                    }));
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format("Scaler 1: {0,13:F3} +- {1,9:F3}", r.Scaler1Rate.v, r.Scaler1Rate.err)
                    }));
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format("Scaler 2: {0,13:F3} +- {1,9:F3}", r.Scaler2Rate.v, r.Scaler2Rate.err)
                    }));
                    //if (active)
                    break;

                case AssaySelector.MeasurementOption.initial:
                    INCCResults.results_init_src_rec isr = (INCCResults.results_init_src_rec)r;
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format("                 Source id: {0}", isr.init_src_id)
                    }));
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format("Initial source measurement: {0}", (isr.pass ? "passed" : "failed"))
                    }));
                    break;

                case AssaySelector.MeasurementOption.normalization:
                    INCCResults.results_bias_rec br = (INCCResults.results_bias_rec)r;
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format("Normalization results for reference source: {0}", br.sourceId)
                    }));
                    if (br.mode == NormTest.Cf252Doubles)
                    {
                        listView1.Items.Add(new ListViewItem(new string[] {
                            string.Format("Normalization doubles rate expected/measured: {0,13:F3} +- {1,9:F3}",
                                          br.biasDblsRateExpectMeas.v, br.biasDblsRateExpectMeas.err)
                        }));
                    }
                    else if (br.mode == NormTest.Cf252Singles)
                    {
                        listView1.Items.Add(new ListViewItem(new string[] {
                            string.Format("Normalization singles rate expected/measured: {0,13:F3} +- {1,9:F3}",
                                          br.biasDblsRateExpectMeas.v, br.biasDblsRateExpectMeas.err)
                        }));
                    }
                    else
                    {
                        listView1.Items.Add(new ListViewItem(new string[] {
                            string.Format("Normalization singles rate expected/measured: {0,13:F3} +- {1,9:F3}",
                                          br.biasSnglsRateExpectMeas.v, br.biasSnglsRateExpectMeas.err)
                        }));
                    }
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format("Normalization test {0}", (br.pass ? "passed" : "failed"))
                    }));
                    break;

                case AssaySelector.MeasurementOption.precision:
                    INCCResults.results_precision_rec pr = (INCCResults.results_precision_rec)r;
                    listView1.Items.Add(new ListViewItem(new string[] { "Precision results" + augmenter }));
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format("Chi-square lower limit: {0,13:F3}", pr.chiSqLowerLimit)
                    }));
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format("Chi-square upper limit: {0,13:F3}", pr.chiSqUpperLimit)
                    }));
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format("       Sample variance: {0,13:F3}", pr.precSampleVar)
                    }));
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format("  Theoretical variance: {0,13:F3}", pr.precTheoreticalVar)
                    }));
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format("            Chi-square: {0,13:F3}", pr.precChiSq)
                    }));
                    listView1.Items.Add(new ListViewItem(new string[] {
                        string.Format("Precision test {0}.", (pr.pass ? "passed" : "failed"))
                    }));
                    break;

                case AssaySelector.MeasurementOption.calibration:
                    INCCMethodResults imrs;
                    bool ok = m.INCCAnalysisResults.TryGetINCCResults(moskey.MultiplicityParams, out imrs);
                    if (ok && imrs.Count > 0)     // should be true for verification and calibration
                    {
                        // we've got a distinct detector id and material type on the methods, so that is the indexer here
                        Dictionary <AnalysisMethod, INCCMethodResult> amimr = imrs[m.INCCAnalysisState.Methods.selector];

                        // now get an enumerator over the map of method results
                        Dictionary <AnalysisMethod, INCCMethodResult> .Enumerator ai = amimr.GetEnumerator();
                        while (ai.MoveNext())
                        {
                            INCCMethodResult imr = ai.Current.Value;
                            if (imr is INCCMethodResults.results_cal_curve_rec)
                            {
                                listView1.Items.Add(new ListViewItem(new string[] { "Passive calibration curve results" + augmenter }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("       Pu mass: {0,13:F3}", ((INCCMethodResults.results_cal_curve_rec)imr).pu_mass.v)
                                }));
                            }
                            else if (imr is INCCMethodResults.results_known_alpha_rec)
                            {
                                listView1.Items.Add(new ListViewItem(new string[] { "Known alpha results" + augmenter }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("Multiplication: {0,13:F3}", ((INCCMethodResults.results_known_alpha_rec)imr).mult)
                                }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("         Alpha: {0,13:F3}", ((INCCMethodResults.results_known_alpha_rec)imr).alphaK)
                                }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("       Pu mass: {0,13:F3}", ((INCCMethodResults.results_known_alpha_rec)imr).pu_mass.v)
                                }));
                            }
                            else if (imr is INCCMethodResults.results_add_a_source_rec)
                            {
                                listView1.Items.Add(new ListViewItem(new string[] { "Add-a-source results" + augmenter }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("       Pu mass: {0,13:F3}", ((INCCMethodResults.results_add_a_source_rec)imr).pu_mass.v)
                                }));
                            }
                            else if (imr is INCCMethodResults.results_active_rec)
                            {
                                listView1.Items.Add(new ListViewItem(new string[] { "Active calibration curve results" + augmenter }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("      U235 mass: {0,13:F3}", ((INCCMethodResults.results_active_rec)imr).u235_mass.v)
                                }));
                            }
                        }
                    }
                    break;

                case AssaySelector.MeasurementOption.verification:
                case AssaySelector.MeasurementOption.holdup:
                    INCCMethodResults imrvs;
                    bool okv = m.INCCAnalysisResults.TryGetINCCResults(moskey.MultiplicityParams, out imrvs);
                    if (okv && imrvs.Count > 0)     // should be true for verification and calibration
                    {
                        // we've got a distinct detector id and material type on the methods, so that is the indexer here
                        Dictionary <AnalysisMethod, INCCMethodResult> amimr = imrvs[m.INCCAnalysisState.Methods.selector];

                        // now get an enumerator over the map of method results
                        Dictionary <AnalysisMethod, INCCMethodResult> .Enumerator ai = amimr.GetEnumerator();
                        while (ai.MoveNext())
                        {
                            INCCMethodResult imr = ai.Current.Value;
                            if (imr is INCCMethodResults.results_cal_curve_rec)
                            {
                                INCCMethodResults.results_cal_curve_rec d = (INCCMethodResults.results_cal_curve_rec)imr;
                                listView1.Items.Add(new ListViewItem(new string[] { "Passive calibration curve results" + augmenter }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                 Pu mass: {0,13:F3} +- {1,9:F3}", d.pu_mass.v, d.pu_mass.err)
                                }));
                                if (d.dcl_pu_mass > 0)
                                {
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("        Declared Pu mass: {0,13:F3}", d.dcl_pu_mass)
                                    }));
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("Declared - assay Pu mass: {0,13:F3} +- {1,9:F3} or {2,6:F2}%",
                                                      d.dcl_minus_asy_pu_mass.v, d.dcl_minus_asy_pu_mass.err, d.dcl_minus_asy_pu_mass_pct)
                                    }));
                                }
                            }
                            else if (imr is INCCMethodResults.results_known_alpha_rec)
                            {
                                INCCMethodResults.results_known_alpha_rec d = (INCCMethodResults.results_known_alpha_rec)imr;
                                listView1.Items.Add(new ListViewItem(new string[] { "Known alpha results" + augmenter }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("          Multiplication: {0,13:F3}", d.mult)
                                }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                   Alpha: {0,13:F3}", d.alphaK)
                                }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                 Pu mass: {0,13:F3} +- {1,9:F3}", d.pu_mass.v, d.pu_mass.err)
                                }));
                                if (d.dcl_pu_mass > 0)
                                {
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("        Declared Pu mass: {0,13:F3}", d.dcl_pu_mass)
                                    }));
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("Declared - assay Pu mass: {0,13:F3} +- {1,9:F3} or {2,6:F2}%",
                                                      d.dcl_minus_asy_pu_mass.v, d.dcl_minus_asy_pu_mass.err, d.dcl_minus_asy_pu_mass_pct)
                                    }));
                                }
                            }
                            else if (imr is INCCMethodResults.results_known_m_rec)
                            {
                                INCCMethodResults.results_known_m_rec d = (INCCMethodResults.results_known_m_rec)imr;
                                listView1.Items.Add(new ListViewItem(new string[] { "Known M results" + augmenter }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("          Multiplication: {0,13:F3}", d.mult)
                                }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                   Alpha: {0,13:F3}", d.alpha)
                                }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                 Pu mass: {0,13:F3} +- {1,9:F3}", d.pu_mass.v, d.pu_mass.err)
                                }));
                                if (d.dcl_pu_mass > 0)
                                {
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("        Declared Pu mass: {0,13:F3}", d.dcl_pu_mass)
                                    }));
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("Declared - assay Pu mass: {0,13:F3} +- {1,9:F3} or {2,6:F2}%",
                                                      d.dcl_minus_asy_pu_mass.v, d.dcl_minus_asy_pu_mass.err, d.dcl_minus_asy_pu_mass_pct)
                                    }));
                                }
                            }
                            else if (imr is INCCMethodResults.results_multiplicity_rec)
                            {
                                INCCMethodResults.results_multiplicity_rec d = (INCCMethodResults.results_multiplicity_rec)imr;
                                listView1.Items.Add(new ListViewItem(new string[] { "Passive multiplicity results" + augmenter }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("          Multiplication: {0,13:F3} +- {1,9:F3}", d.mult.v, d.mult.err)
                                }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                   Alpha: {0,13:F3} +- {1,9:F3}", d.alphaK.v, d.alphaK.err)
                                }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("       Correction factor: {0,13:F3}", d.corr_factor.v, d.corr_factor.err)
                                }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                 Pu mass: {0,13:F3} +- {1,9:F3}", d.pu_mass.v, d.pu_mass.err)
                                }));
                                if (d.dcl_pu_mass > 0)
                                {
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("        Declared Pu mass: {0,13:F3}", d.dcl_pu_mass)
                                    }));
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("Declared - assay Pu mass: {0,13:F3} +- {1,9:F3} or {2,6:F2}%",
                                                      d.dcl_minus_asy_pu_mass.v, d.dcl_minus_asy_pu_mass.err, d.dcl_minus_asy_pu_mass_pct)
                                    }));
                                }
                            }
                            else if (imr is INCCMethodResults.results_add_a_source_rec)
                            {
                                INCCMethodResults.results_add_a_source_rec d = (INCCMethodResults.results_add_a_source_rec)imr;
                                listView1.Items.Add(new ListViewItem(new string[] { "Add-a-source results" + augmenter }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                   Delta: {0,13:F3} +- {1,9:F3}", d.delta.v, d.delta.err)
                                }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("       Correction factor: {0,13:F3}", d.corr_factor.v, d.corr_factor.err)
                                }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                 Pu mass: {0,13:F3} +- {1,9:F3}", d.pu_mass.v, d.pu_mass.err)
                                }));
                                if (d.dcl_pu_mass > 0)
                                {
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("        Declared Pu mass: {0,13:F3}", d.dcl_pu_mass)
                                    }));
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("Declared - assay Pu mass: {0,13:F3} +- {1,9:F3} or {2,6:F2}%",
                                                      d.dcl_minus_asy_pu_mass.v, d.dcl_minus_asy_pu_mass.err, d.dcl_minus_asy_pu_mass_pct)
                                    }));
                                }
                            }
                            else if (imr is INCCMethodResults.results_curium_ratio_rec)
                            {
                                INCCMethodResults.results_curium_ratio_rec d = (INCCMethodResults.results_curium_ratio_rec)imr;
                                listView1.Items.Add(new ListViewItem(new string[] { "Curium ratio results" + augmenter }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                 Cm mass: {0,13:F3}  +- {1,9:F3}", d.cm_mass.v, d.cm_mass.err)
                                }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                 Pu mass: {0,13:F3} +- {1,9:F3}", d.pu.pu_mass.v, d.pu.pu_mass.err)
                                }));
                                if (d.pu.dcl_pu_mass > 0)
                                {
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("        Declared Pu mass: {0,13:F3}", d.pu.dcl_pu_mass)
                                    }));
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("Declared - assay Pu mass: {0,13:F3} +- {1,9:F3} or {2,6:F2}%",
                                                      d.pu.dcl_minus_asy_pu_mass.v, d.pu.dcl_minus_asy_pu_mass.err, d.pu.dcl_minus_asy_pu_mass_pct)
                                    }));
                                }
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                  U mass: {0,13:F3} +- {1,9:F3}", d.u.mass.v, d.u.mass.err)
                                }));
                                if (d.u.dcl_mass > 0)
                                {
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("         Declared U mass: {0,13:F3}", d.u.dcl_mass)
                                    }));
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format(" Declared - assay U mass: {0,13:F3} +- {1,9:F3} or {2,6:F2}%",
                                                      d.u.dcl_minus_asy_mass.v, d.u.dcl_minus_asy_mass.err, d.u.dcl_minus_asy_mass_pct)
                                    }));
                                }
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("      Declared U235 mass: {0,13:F3} +- {1,9:F3}", d.u235.mass.v, d.u235.mass.err)
                                }));
                                if (d.u235.dcl_mass > 0)
                                {
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("      Declared U235 mass: {0,13:F3}", d.u235.dcl_mass)
                                    }));
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("  Decl - assay U235 mass: {0,13:F3} +- {1,9:F3} or {2,6:F2}%",
                                                      d.u235.dcl_minus_asy_mass.v, d.u235.dcl_minus_asy_mass.err, d.u235.dcl_minus_asy_mass_pct)
                                    }));
                                }
                            }
                            else if (imr is INCCMethodResults.results_truncated_mult_rec)
                            {
                                INCCMethodResults.results_truncated_mult_rec d = (INCCMethodResults.results_truncated_mult_rec)imr;
                                if (d.methodParams.known_eff)
                                {
                                    listView1.Items.Add(new ListViewItem(new string[] { "Known efficiency truncated multiplicity results" + augmenter }));
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("                 Pu mass: {0,13:F3} +- {1,9:F3}", d.k.pu_mass.v, d.k.pu_mass.err)
                                    }));
                                    if (d.k.dcl_pu_mass > 0)
                                    {
                                        listView1.Items.Add(new ListViewItem(new string[] {
                                            string.Format("        Declared Pu mass: {0,13:F3}", d.k.dcl_pu_mass)
                                        }));
                                        listView1.Items.Add(new ListViewItem(new string[] {
                                            string.Format("Declared - assay Pu mass: {0,13:F3} +- {1,9:F3} or {2,6:F2}%",
                                                          d.k.dcl_minus_asy_pu_mass.v, d.k.dcl_minus_asy_pu_mass.err, d.k.dcl_minus_asy_pu_mass_pct)
                                        }));
                                    }
                                }
                                if (d.methodParams.solve_eff)
                                {
                                    listView1.Items.Add(new ListViewItem(new string[] { "Solve efficiency truncated multiplicity results" + augmenter }));
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("                 Pu mass: {0,13:F3} +- {1,9:F3}", d.s.pu_mass.v, d.s.pu_mass.err)
                                    }));
                                    if (d.s.dcl_pu_mass > 0)
                                    {
                                        listView1.Items.Add(new ListViewItem(new string[] {
                                            string.Format("        Declared Pu mass: {0,13:F3}", d.s.dcl_pu_mass)
                                        }));
                                        listView1.Items.Add(new ListViewItem(new string[] {
                                            string.Format("Declared - assay Pu mass: {0,13:F3} +- {1,9:F3} or {2,6:F2}%",
                                                          d.s.dcl_minus_asy_pu_mass.v, d.s.dcl_minus_asy_pu_mass.err, d.s.dcl_minus_asy_pu_mass_pct)
                                        }));
                                    }
                                }
                            }
                            else if (imr is INCCMethodResults.results_active_rec)
                            {
                                INCCMethodResults.results_active_rec d = (INCCMethodResults.results_active_rec)imr;
                                listView1.Items.Add(new ListViewItem(new string[] { "Active calibration curve results" + augmenter }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                 U235 mass: {0,13:F3} +- {1,9:F3}", d.u235_mass.v, d.u235_mass.err)
                                }));
                                if (d.dcl_u235_mass > 0)
                                {
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("        Declared U235 mass: {0,13:F3}", d.dcl_u235_mass)
                                    }));
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("Declared - assay U235 mass: {0,13:F3} +- {1,9:F3} or {2,6:F2}%",
                                                      d.dcl_minus_asy_u235_mass.v, d.dcl_minus_asy_u235_mass.err, d.dcl_minus_asy_u235_mass_pct)
                                    }));
                                }
                            }
                            else if (imr is INCCMethodResults.results_active_passive_rec)
                            {
                                INCCMethodResults.results_active_passive_rec d = (INCCMethodResults.results_active_passive_rec)imr;
                                listView1.Items.Add(new ListViewItem(new string[] { "Active/passive results" + augmenter }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                 U235 mass: {0,13:F3} +- {1,9:F3}", d.u235_mass.v, d.u235_mass.err)
                                }));
                                if (d.dcl_u235_mass > 0)
                                {
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("        Declared U235 mass: {0,13:F3}", d.dcl_u235_mass)
                                    }));
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("Declared - assay U235 mass: {0,13:F3} +- {1,9:F3} or {2,6:F2}%",
                                                      d.dcl_minus_asy_u235_mass.v, d.dcl_minus_asy_u235_mass.err, d.dcl_minus_asy_u235_mass_pct)
                                    }));
                                }
                            }
                            else if (imr is INCCMethodResults.results_collar_rec)
                            {
                                INCCMethodResults.results_collar_rec d = (INCCMethodResults.results_collar_rec)imr;
                                listView1.Items.Add(new ListViewItem(new string[] { "Collar results" + augmenter }));
                                listView1.Items.Add(new ListViewItem(new string[] {
                                    string.Format("                 U235 mass: {0,13:F3} +- {1,9:F3}", d.u235_mass.v, d.u235_mass.err)
                                }));
                                if (d.dcl_total_u235.v > 0)
                                {
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("        Declared U235 mass: {0,13:F3} +- {1,9:F3}", d.dcl_total_u235.v, d.dcl_total_u235.err)
                                    }));
                                    listView1.Items.Add(new ListViewItem(new string[] {
                                        string.Format("Declared - assay U235 mass: {0,13:F3} +- {1,9:F3} or {2,6:F2}%",
                                                      d.dcl_minus_asy_u235_mass.v, d.dcl_minus_asy_u235_mass.err, d.dcl_minus_asy_u235_mass_pct)
                                    }));
                                }
                            }
                        }
                    }
                    break;

                case AssaySelector.MeasurementOption.unspecified:
                    listView1.Items.Add(new ListViewItem(new string[] { "List mode results" + augmenter }));
                    listView1.Items.Add(new ListViewItem(new string[] { "TODO " }));     // todo: fill in with something useful for LM
                    break;
                }
            }
        }