SMP-V: Report for Luminosity Calibration Study

1. SMP-V: Report for Luminosity Calibration Study Jiyeon Han, Ping Tan Alexey Svyatkovskiy, Hwidong Yoo Stoyan Stoynev Ilya Kravchenko, Jamila Butt Youn Roh, Efe Yazgan

2. Introduction • Significant luminosity calibration issue with 2011 dataset is introduced from Luminosity group • https://indico.cern.ch/getFile.py/access?contribId=2&resId=0&materialId=slides&confId=169386 • About 7.5% uncertainty • SMP-V group organizes the task force team to investigate the issue using Zmumu and Zee events • Single ISO muon trigger based • Based on muon charge asymmetry analysis • Double muon trigger based • Based on Drell-Yan measurement • Double electron trigger based • Based on Drell_Yan & AFB measurements • Products • Number of Z candidates as a function of run period • Efficiency as a function of run period / number of vertices • Z yield corrected by efficiency • Absolute Z cross section • Predicted luminosity using Z cross section (using NNLO Z cross section)

3. lumiCalc2.py • We use 3 different version of lumiCalc2.py • Plain version: default described in https://twiki.cern.ch/twiki/bin/view/CMS/LumiCalc • Will call as v1 in this talk • v2: updated in last week. It is available in HEAD • --correctionv2 • v3: updated yesterday. It needs to change in scripts manually

4. Single Iso-Mu Trigger • Provided by Jiyeon Han, Ping Tan

5. Samples & Event Selection • Samples • Runs_160325-163268 : Run2011A-May10ReReco-v1_AOD • Runs_163269-163869_DS_SingleMu_Run2011A-May10ReReco-v1_AOD • Runs_165071-165761_DS_SingleMu_Run2011A-PromptReco-v4_AOD • Runs_165762-167043_DS_SingleMu_Run2011A-PromptReco-v4_AOD • Runs_167044-167913_DS_SingleMu_Run2011A-PromptReco-v4_AOD • Runs_170053-172619_DS_SingleMu_Run2011A-05Aug2011-v1_AOD • Runs_172620-173235_DS_SingleMu_Run2011A-PromptReco-v6_AOD • Runs_173236-173692_DS_SingleMu_Run2011A-PromptReco-v6_AOD • Runs_175832-178419_DS_SingleMu_Run2011B-PromptReco-v1_AOD • Runs_178420-179958_DS_SingleMu_Run2011B-PromptReco-v1_AOD • Runs_179959-180252_DS_SingleMu_Run2011B-PromptReco-v1_AOD • Trigger • HLT_IsoMu15 up to run = 163268 • HLT_IsoMu24 for 2011A data set above run = 163269 • HLT_IsoMu30 for 2011B data set • Selection • VBTF baseline selection • Slide 3: https://indico.cern.ch/getFile.py/access?contribId=2&resId=0&materialId=slides&confId=167985

6. Run Period • Run period 1 : a. 5E32; May10; run range (160404-163869) • Run period 2 : b. 1.4E33; PromptV4; run range (165088-167913) • Run period 3 : c. 2E33; Aug05+PromptV6; run range (170249-173198) • Run period 4 : d. 3E33; PromptV6; run range (173236-173692) • Run period 5 : e. 3E33(higher PU); 2011B; run range (175971-178419) • Run period 6 : f. 5E33; 2011B; run range (178420-180252)

7. Efficiencies • Single muon object efficiency as a function of run period and number of vertices Trigger efficiency Reco+ID efficiency

8. N (events) / Efficiencies lumiCalc2.py v1 • Efficiency corrected number of events which we can check the trend of luminositycalculation • Normalize using existing lumiCalc2.py • The results are in CMS acceptance • No acceptance correction is applied • Leading muon pt > 30 GeV • 2nd leading muon pt > 20 GeV • Both muons |eta| < 2.1 3% lumiCalc2.py v3 lumiCalc2.py v2 1.5% 7.5%

9. Double Muon Trigger • Provided by Alexey Svyatkovskiy, Stoyan Stoynev, Hwidong Yoo

10. Samples & Event Selection • Use DoubleMu PD • /DoubleMu/Run2011A-May10ReReco-v1/AOD (160404-163869) • /DoubleMu/Run2011A-PromptReco-v4/AOD (165088-167913) • /DoubleMu/Run2011A-05Aug2011-v1/AOD (170249-173198) • /DoubleMu/Run2011A-PromptReco-v6/AOD (173236-173692) • /DoubleMu/Run2011B-PromptReco-v1/AOD (175971-180252) • Use HLT_DoubleMu6 + HLT_Mu13_Mu8 • MC: DYM20 Fall11 42X • Event selection: event selection using in DY differential cross section measurement • Baseline muon ID • Muon1 pt > 14 GeV, muon2 pt > 9 GeV • PF-based isolation

11. Efficiencies (1) • Efficiency is determined using t&p method • Measurement single muon object efficiency and event efficiency is estimated by eff (event) = eff(mu1) * eff(mu2) • This way doesn’t take into account for all system uncertainties and correlation between two legs of trigger. We should consider 2-3% level of systematic uncertainties on the determination. RunBv1: 175832-178078

12. Efficiencies (2) • Efficiencies as function of run period and number of vertices

13. MC Inputs • We use the MC inputs to determine absolute Z cross section

14. Luminosity Expectation (1) • Predicted luminosity is determined using the number of Z candidates passing all selection, and efficiencies, acceptance with theoretical cross section (970 pb) from NNLO. • Well agreement with lumiCalc2.py v2 With v3 1.8% 3.3% 4.1% 4.5% 3.2% ~0% 1.4% 1.8% 1.7% ~0%

15. Luminosity Expectation (2) • Absolute Z cross section and luminosity prediction as a function of run period LumiCalc2.py v1 is used T.S. Merge 3 consecutive runs Merge 10 consecutive runs Used Run < 178420

16. Luminosity Expectation (3) • Test with lumiCalc2.py v2 Merge 3 consecutive runs Merge 10 consecutive runs Used Run < 178420

17. Luminosity Expectation (4) • Test with lumiCalc2.py v3 Merge 3 consecutive runs Merge 10 consecutive runs Used Run < 178420

18. Zee • Provided by Ilya Kravchenko, Jamila Butt, Youn Roh, Efe Yazgan • Event yields after selection • Normalized integrated luminosity • No efficiency correction • No acceptance correction • More corrections are needed to check the trend observed in Zmumu Apply energy scale correction