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HKS collaboration meeting @JLab 2008/5/16 Akihiko&Yoko @ Wedding Party 2008/5/10
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Topics Bug in REPLAY Blind analysis by Lulin
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Bug in REPLAY
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Multiplicity problem Run# 56089, eventID 1954 3 events @ JLab ENGINE 2events @ Tohoku ENGINE Ntuples are inconsistent parameter files and source codes should be checked
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Bug in analyzer Cut condition for ENGE momentum (depends on “default” matrix) Different “default” matrix between USA and Japan Bug depends on multiplicity of ENGE Event#1 Event#2 Event#3 (out of acceptance) Event#4 … Accept Reject
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Old ntuple vs. New ntuple +12.1% +14.7% +17.5% +16.6% Fixed bug and re-analyze
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Old RAP(12Jan08) vs. New RAP(04Apr08) TargetOld RAP [events] New RAP [events] Improve CH22580026530+2.8 % 12C159484167387+5.0 % 28Si118755125766+5.9 % 7Li6486669123+6.6 % Number of events …. Coin ntuple Multiplicity (ENGE) RAP Coincidence between HKS and ENGE
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Blind analysis by Lulin
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Simulation data for blind analysis Focal plane resolution in sigma 86 m (exf), 0.7 mrad (expfp), 210 m(eyf), 2.8 mrad (eypf) 110 m (hxf), 0.5 mrad (hxpfp), 110 m(hyf), 0.7 mrad (hypf) Fixed beam energy (1853.1 MeV) NO energy loss @ target # of event & S/N (Updated) moderately ( : ~2150 counts, : ~400 counts, 12 B g.s. :~600 counts) Sieve Slit data is ready Raster (0.25 cm × 0.25 cm) for CH 2
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Lulin’s blind analysis Tune CH 2 & 12 C –Add peaks of 12 C one by one (maximum 6 peaks) Raster correction –only momentum of kaon Weight in the final step of tuning –1.0( ), 1.0( ), 5.0 (B.E.=11.43), 0.0(B.E.=13.63), 6.0(B.E.=16.70), 3.0(B.E.=20.35), 4.5(B.E.=23.04), 6.0(B.E.=23.70) Detailed will be shown in Lulin’s talk * In the following pictures …… GOD : answer of simulation Lulin-tune : result from Lulin’s tuning
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Lulin-tune CH2(tuned event) Top : GOD. Bottom Lulin-tune RED : coin., BLACK : B.G. Top : GOD, Bottom : Lulin-tune for All event
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Lulin-tune CH2 (NOT tuned background event) TOP : Lulin MM vs. GOD MM BOTTOM : wide region TOP : GOD MM BOTTOM : LulinMM
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Each component (xpt,ypt,dp) Lulin vs. GOD expt eypt edp hxpt hypt hdp offset due to different central momentum
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Lulin-tune C12(tuned event) Top : GOD. Bottom Lulin-tune RED : coin., BLACK : B.G. Top : GOD, Bottom : Lulin-tune for All event
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Oka-tune C12 (NOT tuned background event) RED : coin., BLACK : B.G.
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Binding energy & Yield Lulin analysisGOD Binding energy [MeV] Yield [counts] Contamination [%] Binding energy [MeV] Yield [counts] S/N 11.43 (g.s.)~4914.411.37 (g.s.)6001.45 13.63~54N/A 16.70~19183.616.31300.09 20.35~14242.420.311000.27 23.70 & 23.04~4071.523.375501.28
![Binding energy & Yield Lulin analysisGOD Binding energy [MeV] Yield [counts] Contamination [%] Binding energy [MeV] Yield [counts] S/N (g.s.)~ (g.s.) ~54N/A 16.70~ ~ & 23.04~](http://images.slideplayer.com./33/10134632/slides/slide_16.jpg "Binding energy & Yield Lulin analysisGOD Binding energy [MeV] Yield [counts] Contamination [%] Binding energy [MeV] Yield [counts] S/N (g.s.)~ (g.s.) ~54N/A 16.70~ ~ & 23.04~")
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How to estimate contamination Fit each peak by gaussian + offset Fitted counts : Integration of gaussian Real counts : # of real events in the peak(3 ) (simulation data can be identified) Contamination [%] = ((Fitted counts) – (Real counts)) / (Fitted counts) ×100
![How to estimate contamination Fit each peak by gaussian + offset Fitted counts : Integration of gaussian Real counts : # of real events in the peak(3 ) (simulation data can be identified) Contamination [%] = ((Fitted counts) – (Real counts)) / (Fitted counts) ×100](http://images.slideplayer.com./33/10134632/slides/slide_17.jpg "How to estimate contamination Fit each peak by gaussian + offset Fitted counts : Integration of gaussian Real counts : # of real events in the peak(3 ) (simulation data can be identified) Contamination [%] = ((Fitted counts) – (Real counts)) / (Fitted counts) ×100")
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Contamination vs S/N ratio
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Step by step missing mass Step 1 Initial matrix ( *.1110 ) Step 2 After involving and (*.02121) Step 3 After involving B.E.=11.43, 23.04, 23.70 (*.03307) Step4 After involving B.E.=20.35 (*.03308) Step5 After involving B.E.=16.70 (*.04022)
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Missing mass of step1(Initial) Top : CH2 for All event Bottom : Coin.(RED), B.G.(BLACK) Top : C12 for All event Bottom : Coin.(RED), B.G.(BLACK)
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Missing mass of step2(tune , ) Top : CH2 for All event Bottom : Coin.(RED), B.G.(BLACK) Top : C12 for All event Bottom : Coin.(RED), B.G.(BLACK)
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Missing mass of step3 (tune , ,2 major peaks) Top : CH2 for All event Bottom : Coin.(RED), B.G.(BLACK) Top : C12 for All event Bottom : Coin.(RED), B.G.(BLACK)
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Missing mass of step4 (tune , ,2 major peaks, core#1) Top : CH2 for All event Bottom : Coin.(RED), B.G.(BLACK) Top : C12 for All event Bottom : Coin.(RED), B.G.(BLACK)
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Missing mass of step5 (tune , ,2 major peaks, core#1,core#2) Top : CH2 for All event Bottom : Coin.(RED), B.G.(BLACK) Top : C12 for All event Bottom : Coin.(RED), B.G.(BLACK)
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Summary The trend is the same as Okayasu’s result The linearity between reference masses ( and ) seems OK but the outside is deformed Background contamination in 12 C peaks The background events that not used for tuning do not make peak Accuracy of binding energy : < 0.4 MeV
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Comments on 7 He Okayasu Spectrum Lulin Spectrum Lulin Mass : 6716.71 MeV/c2 (atomic masses are used) Lulin Binging energy : -5.53 MeV/c2 Okayasu Mass : 6716.15 MeV/c2 (nuclear masses are used) Okayasu Binging energy : -5.07 MeV/c2 Lulin 7 He + : 6722.2413 MeV/c2 7 He + : 6721.20 MeV/c2 = 0.46 MeV
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