Single Top Polarization analysis
Group info
- Members: Joosep Pata, Andres Tiko, Matthias Komm, Steffen Roecker (students), Dmitri Konstantinov, Liis Rebane, Thorsten Chwalek (postdocs), Andrea Giammanco, Mario Kadastik, Jeannine Wagner-Kuhr (staff)
- Mailing list: cms-stop-pol@cernNOSPAMPLEASE.ch
Useful papers
Models to investigate
Flavor-Changing Neutral Currents (FCNC) in tgq (q=u,c) coupling
The best limits come from ATLAS (
ref.):
- K_tgu/Λ < 0.0069 TeV-1
- K_tgc/Λ < 0.016 TeV-1
A different kind of search, with the same topology as we will investigate, has been performed by D0 (
ref.) obtaining these limits:
- K_tgu/Λ < 0.013 TeV-1
- K_tgc/Λ < 0.057 TeV-1
The D0 analysis is performed with 2.3/fb, with a Bayesian Neural Network, optimized for the processes in the figure below in the
lepton + 2 jets topology. See the references in the Introduction for a nice list of new-physics models that can give an effective FCNC coupling of this kind.
FCNC tgq interactions at leading order, from D0's paper:
The CDF (
ref.1,
ref.2) and ATLAS experiments optimize instead for the diagram qg->t and therefore they investigate the
lepton + 1 jet topology, see figure below (from ATLAS):
Additional jets can come from gluon radiation, therefore our kind of analysis (which needs a second jet to define the approximate spin axis) can be also sensitive to this diagram.
Comparing D0 (lepton + 2 jets) with 2.3/fb and CDF (lepton + 1 jet) with 2.2/fb, one sees that for a similar statistics the strongest limits come from D0. Therefore, the lepton + 2 jets selection might be intrinsically more sensitive to FCNC signals in the tgq coupling.
Suggestion by Lev Dudko:
since there are no any interference between Ktcg/L and Ktug/L couplings
and cross section depends quadratically from these couplings it is
enough to generate two samples for each process. One with one coupling
and another sample for the second coupling and use one of the value for
the coupling. All other values one can simulate with the same sample
with quadratic renormalization to the new value of the coupling.
Therefore, it is very simple, you can take one sample, use quadratic
parameter of the FCNC sample normalization (e.g. in distribution of the
cos_theta) and apply Theta package to find the limit for this quadratic
coupling.
Flavor-Changing Neutral Currents (FCNC) in tγq (q=u,c) coupling
For this kind of coupling, it is difficult to improve over HERA limits from γq->t search. An alternative strategy pursued in hadron colliders is the search for t->γq decays in ttbar events (see
an old MC study in CMS).
Flavor-Changing Neutral Currents (FCNC) in tZq (q=u,c) coupling
For this kind of coupling, it is difficult to improve over LEP limits from Z->tq search (see
paper by ALEPH). An alternative strategy pursued in hadron colliders is the search for t->Zq decays in ttbar events (see the
latest study from ATLAS and
from CMS)
Anomalous tWb couplings
Latest results are from D0 (
ref.)
Samples with generic (non-left-handed) tWb couplings are being produced in Moscow.
Useful links
General Work Plan
Analysis at 7 TeV with ~1/fb
- Reproduce TOP-11-021 selection numbers in both data and MC
- Produce FastSim samples for models with A < 100%
- Set up statistics macros to extract A and set upper limits on non-SM models
- Extract from dedicated control samples the abundance and the cos θ* shape for W + light jets, ttbar, QCD
- Evaluate all the systematics (see this wiki)
- Get the results. No need to keep the analysis "blind" at this stage, as the main result will be the 8 TeV one. In case we will decide to use the full 7 TeV dataset, the additional statistics will be handled with the same work plan as for 8 TeV below.
Question to be answered once all data-driven background estimations and all systematics are included in the analysis: is the current definition of the θ* angle the most optimal for this analysis? What about using the "beam-line basis" instead of the "spectator basis"? (See
Mahlon, Parke 2000)
- Which of the two gives the best ΔA and the best limits when running on MC only? (Use pseudo-data diced from the overall MC expectation.)
- Is the data-MC agreement equally satisfactory for both?
- Is the model dependence for the W + heavy flavor background roughly the same?
Synchronization to 2011
To be performed as specified in
https://twiki.cern.ch/twiki/bin/viewauth/CMS/SingleTopSync2011
The datafiles on phys are copied to /hdfs/local/stpol/sync2011
Joosep START42_V17 |
Lepton Veto |
Jet Cut |
MTW |
B-tagging |
Monte Carlo, muon sel. |
1183 |
565 |
263 |
182 |
Monte Carlo, electron sel. |
805 |
426 |
155 |
101 |
Joosep START42_V13 |
Lepton Veto |
Jet Cut |
MTW |
B-tagging |
Monte Carlo, muon sel. |
1183 |
563 |
263 |
183 |
Monte Carlo, electron sel. |
805 |
419 |
154 |
100 |
Synchronization of the 4_2_X code to the Naples group
Process the
SbarChannel dataset
/Tbar_TuneZ2_s-channel_7TeV-powheg-tauola/Summer11-PU_S4_START42_V11-v1/AODSIM
and try to get the following numbers after the cuts:
globalTag=START42_V17 and doResol=True in TChannel_cfg.py
lepton id |
lepton |
jet |
met |
btag |
mu |
8156 |
3838 |
2103 |
1456 |
ele |
5508 |
2560 |
1079 |
752 |
Correlation between costheta in the eta beamline basis and the spectator jet basis
Plots are here:
http://phys.hep.kbfi.ee/~joosep/stpol/costheta_corr/
Done using
UserCode/STPol/util_scripts/costheta_corr.py
Forward jet selection bias
Plots are here:
http://phys.hep.kbfi.ee/~joosep/stpol/fwdJet_selection_bias/ The forward jet selection is
(abs(fwdJetEta)<4.5 && abs(fwdJetEta)>2.5 && fwdJetPt>30)
The probability is calculated using the Kolmogorov test, the areas are normalized to 1.
Forward jet eta
Plots are here:
http://phys.hep.kbfi.ee/~joosep/stpol/fwdJet_plots/
Analysis at 8 TeV
Note: please don't take the 7 and 8 TeV analyses as necessarily sequential. As soon as 8 TeV data arrive, it is mandatory to look at those (to validate many things: the quality of the detector and of the reconstruction, the effect of the worse pile-up conditions, to check the scaling of the backgrounds from 7 to 8 TeV) even if the 7 TeV analysis is not complete yet. Ideally, things should be done in parallel; priorities would be rediscussed at each of our weekly meetings.
- Check data-MC agreement (in rate and in cos θ* shape) in the control samples for W + light jets, ttbar, QCD
- Perform a MC only analysis to assess the expected sensitivity of the analysis. (Use pseudo-data diced from the overall MC expectation.)
- Re-optimize if needed, using the control samples to quantify the non-single-top backgrounds
- Use FastSim for non-SM signals, SM backgrounds that don't arrive quickly enough, systematic variations around the generation parameters of the SM backgrounds
- Keep the analysis blind. In our case this means that we should abstain from looking at cosθ* in the single-top-dominated region until we are really confident that we understand the background-dominated regions and we are considering at least the main systematic uncertainties that can affect the shape of this observable and the rate of events.
Processed datasets for code HEP-KBFI/stpol
List of datasets
DYJets |
/DYJetsToLL_M-50_TuneZ2Star_8TeV-madgraph-tarball/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
GJets1 |
/GJets_HT-200To400_8TeV-madgraph/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
GJets2 |
/GJets_HT-400ToInf_8TeV-madgraph/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
QCD_BCtoE1 |
/QCD_Pt_20_30_BCtoE_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
QCD_BCtoE2 |
/QCD_Pt_30_80_BCtoE_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
QCD_BCtoE3 |
/QCD_Pt_80_170_BCtoE_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
QCD_BCtoE4 |
/QCD_Pt_170_250_BCtoE_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
QCD_BCtoE5 |
/QCD_Pt_250_350_BCtoE_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
QCD_BCtoE6 |
/QCD_Pt_350_BCtoE_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v2/AODSIM |
START53_V20::All |
|
QCD_EM1 |
/QCD_Pt_20_30_EMEnriched_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
QCD_EM2 |
/QCD_Pt_30_80_EMEnriched_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
QCD_EM3 |
/QCD_Pt_80_170_EMEnriched_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
QCD_EM4 |
/QCD_Pt_170_250_EMEnriched_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
QCD_EM5 |
/QCD_Pt_250_350_EMEnriched_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
QCD_EM6 |
/QCD_Pt_350_EMEnriched_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
QCD_Mu |
/QCD_Pt_20_MuEnrichedPt_15_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
SingleElectron_RunABCD |
/SingleElectron/Run2012D-22Jan2013-v1/AOD |
FT_53_V21_AN4::All |
|
SingleMu_RunABCD |
/SingleMu/Run2012D-22Jan2013-v1/AOD |
FT_53_V21_AN4::All |
|
Tbar_s |
/Tbar_s-channel_TuneZ2star_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
Tbar_t_mass166_5 |
/TBarToLeptons_t-channel_mass166_5_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
Tbar_t_mass178_5 |
/TBarToLeptons_t-channel_mass178_5_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TbarToLeptons_t-channel |
/TBarToLeptons_t-channel_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
Tbar_t_scaledown |
/TBarToLeptons_t-channel_scaledown_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
Tbar_t_scaleup |
/TBarToLeptons_t-channel_scaleup_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
Tbar_t |
/Tbar_t-channel_TuneZ2star_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
Tbar_tW |
/Tbar_tW-channel-DR_TuneZ2star_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
T_s |
/T_s-channel_TuneZ2star_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
TTbar_FullLept2 |
/TTJets_FullLeptMGDecays_8TeV-madgraph/Summer12_DR53X-PU_S10_START53_V7A-v2/AODSIM |
START53_V20::All |
doSkimming=False |
TTbar_SemiLept2 |
/TTJets_SemiLeptMGDecays_8TeV-madgraph/Summer12_DR53X-PU_S10_START53_V7A_ext-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TTbar |
/TTJets_MassiveBinDECAY_TuneZ2star_8TeV-madgraph-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TTJets_mass166_5 |
/TTJets_mass166_5_TuneZ2star_8TeV-madgraph-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TTJets_mass178_5 |
/TTJets_mass178_5_TuneZ2star_8TeV-madgraph-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TTJets_matchingdown |
/TTJets_matchingdown_TuneZ2star_8TeV-madgraph-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TTJets_matchingup |
/TTJets_matchingup_TuneZ2star_8TeV-madgraph-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TTJets_scaledown |
/TTJets_scaledown_TuneZ2star_8TeV-madgraph-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TTJets_scaleup |
/TTJets_scaleup_TuneZ2star_8TeV-madgraph-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
T_t_mass166_5 |
/TToLeptons_t-channel_mass166_5_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
T_t_mass178_5 |
/TToLeptons_t-channel_mass178_5_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TToBENu_anomWtb-0100 |
/TToBENu_anomWtb-0100_t-channel_TuneZ2star_8TeV-comphep/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TToBENu_anomWtb-unphys |
/TToBENu_anomWtb-unphys_t-channel_TuneZ2star_8TeV-comphep/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TToBMuNu_anomWtb-0100 |
/TToBMuNu_anomWtb-0100_t-channel_TuneZ2star_8TeV-comphep/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TToBMuNu_anomWtb-unphys |
/TToBMuNu_anomWtb-unphys_t-channel_TuneZ2star_8TeV-comphep/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TToBTauNu_anomWtb-0100 |
/TToBTauNu_anomWtb-0100_t-channel_TuneZ2star_8TeV-comphep/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TToBTauNu_anomWtb-unphys |
/TToBTauNu_anomWtb-unphys_t-channel_TuneZ2star_8TeV-comphep/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
TToLeptons_t-channel |
/TToLeptons_t-channel_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
T_t_scaledown |
/TToLeptons_t-channel_scaledown_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
T_t_scaleup |
/TToLeptons_t-channel_scaleup_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
T_t |
/T_t-channel_TuneZ2star_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
doSkimming=False |
T_tW |
/T_tW-channel-DR_TuneZ2star_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
WJets1 |
/WJetsToLNu_TuneZ2Star_8TeV-madgraph-tarball/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
WJets2 |
/WJetsToLNu_TuneZ2Star_8TeV-madgraph-tarball/Summer12_DR53X-PU_S10_START53_V7A-v2/AODSIM |
START53_V20::All |
|
WJets_excl1 |
/W1JetsToLNu_TuneZ2Star_8TeV-madgraph/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
WJets_excl2 |
/W2JetsToLNu_TuneZ2Star_8TeV-madgraph/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
WJets_excl3 |
/W3JetsToLNu_TuneZ2Star_8TeV-madgraph/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
WJets_excl4 |
/W4JetsToLNu_TuneZ2Star_8TeV-madgraph/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
WJets_matchingdown |
/WJetsToLNu_matchingdown_8TeV-madgraph-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
WJets_matchingup |
/WJetsToLNu_matchingup_8TeV-madgraph-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
WJets_scaledown |
/WJetsToLNu_scaledown_8TeV-madgraph-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
WJets_scaleup |
/WJetsToLNu_scaleup_8TeV-madgraph-tauola/Summer12_DR53X-PU_S10_START53_V7A-v2/AODSIM |
START53_V20::All |
|
WW |
/WW_TuneZ2star_8TeV_pythia6_tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
WZ |
/WZ_TuneZ2star_8TeV_pythia6_tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
ZZ |
/ZZ_TuneZ2star_8TeV_pythia6_tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM |
START53_V20::All |
|
step1
Here are the datasets processed by the (skim) +
PF2PAT + (slim) code. Use the following snippet to get the list of files:
das_cli.py --query="file dataset=/T_t-channel_TuneZ2star_8TeV-powheg-tauola/jpata-stpol_step1_v2_1_noSkim-6d0886f8efd932bc8d37cab903c44a2c/USER instance=cms_dbs_ph_analysis_02" --limit=0
all MC |
skim, mu, ele |
DAS |
T_t |
noSkim, ele, mu |
/T_t-channel_TuneZ2star_8TeV-powheg-tauola/jpata-stpol_step1_v2_1_noSkim-6d0886f8efd932bc8d37cab903c44a2c/USER |
Tbar_t |
noSkim, ele, mu |
/Tbar_t-channel_TuneZ2star_8TeV-powheg-tauola/jpata-stpol_step1_v2_1_noSkim-6d0886f8efd932bc8d37cab903c44a2c/USER |
SingleMu RunA+RunB |
ele, mu, 5238 pb^-1 |
/SingleMu/jpata-stpol_step1_v3_1-60389801c9c75bd7ec94ff0c7c5a7358/USER |
step1 Feb6 rerun
source dataset |
destination dataset |
output lumi from crab [/pb] |
/SingleElectron/Run2012A-recover-06Aug2012-v1/AOD |
/SingleElectron/joosep-step1_Data_Feb6-a67a46c387bb052b77f0782979d2cf48/USER |
82 |
/SingleElectron/Run2012A-13Jul2012-v1/AOD |
/SingleElectron/joosep-step1_Data_Feb6-2cdd420c4c725097a4330835f90d1ada/USER |
808 |
/SingleElectron/Run2012B-13Jul2012-v1/AOD |
/SingleElectron/joosep-step1_Data_Feb6-2cdd420c4c725097a4330835f90d1ada/USER |
4423 |
/SingleElectron/Run2012C-24Aug2012-v1/AOD |
/SingleElectron/joosep-step1_Data_Feb6-2d70b925c06acab65b2731ef9f08c3c1/USER |
495 |
/SingleElectron/Run2012C-PromptReco-v2/AOD |
/SingleElectron/joosep-step1_Data_Feb6-14d3879a0dccd7e6c1fb317f2674eaf1/USER |
6218 |
/SingleElectron/Run2012D-PromptReco-v1/AOD |
/SingleElectron/joosep-step1_Data_Feb6-4ad4eefaf926ac722f9a48104acbb5cc/USER |
7248 |
/SingleMu/Run2012A-13Jul2012-v1/AOD |
/SingleMu/joosep-step1_Data_Feb6-2cdd420c4c725097a4330835f90d1ada/USER |
808 |
/SingleMu/Run2012A-recover-06Aug2012-v1/AOD |
/SingleMu/joosep-step1_Data_Feb6-2cdd420c4c725097a4330835f90d1ada/USER |
82 |
/SingleMu/Run2012B-13Jul2012-v1/AOD |
/SingleMu/joosep-step1_Data_Feb6-2cdd420c4c725097a4330835f90d1ada/USER |
4429 |
/SingleMu/Run2012C-24Aug2012-v1/AOD |
/SingleMu/joosep-step1_Data_Feb6-14d3879a0dccd7e6c1fb317f2674eaf1/USER |
495 |
/SingleMu/Run2012C-PromptReco-v2/AOD |
/SingleMu/joosep-step1_Data_Feb6-14d3879a0dccd7e6c1fb317f2674eaf1/USER |
6387 |
/SingleMu/Run2012D-PromptReco-v1/AOD |
/SingleMu/joosep-step1_Data_Feb6-4ad4eefaf926ac722f9a48104acbb5cc/USER |
7274 |
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30459503 |
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10494617 |
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1740229 |
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2048152 |
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1945525 |
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1948112 |
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2026521 |
/QCD_Pt_350_BCtoE_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v2/AODSIM |
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1948532 |
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35040695 |
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33088888 |
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34542763 |
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34601322 |
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34080562 |
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7529312 |
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139974 |
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1711403 |
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1935072 |
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259961 |
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4246444 |
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12119013 |
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11229902 |
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25424818 |
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6923750 |
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3758227 |
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497658 |
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18393090 |
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57709905 |
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10000431 |
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10000283 |
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9799908 |
Synchronization to 2012 / CMSSW_5_3_4
Analysis steps are the same as described in
https://twiki.cern.ch/twiki/bin/view/CMS/TWikiTopRefEventSel#Single_Top_Channels
Tbar_t data file:
/store/mc/Summer12_DR53X/T_t-channel_TuneZ2star_8TeV-powheg-tauola/AODSIM/PU_S10_START53_V7A-v1/0000/0077EE51-88DC-E111-88BE-0018F3D09684.root
Muon channel
name |
processed |
skim + HLT |
iso lepton |
loose muon veto |
loose electron veto |
nJets==2 |
MTW |
nBTags==1 |
Remarks |
Joosep |
10566 |
3355 |
626 |
625 |
622 |
244 |
197 |
77 |
Skim, noHLT, TCHP tight, START53_V7A, CMSSW_5_3_4 |
Joosep |
10566 |
10566 |
626 |
625 |
622 |
244 |
197 |
77 |
noSkim, noHLT, TCHP tight, START53_V7A, CMSSW_5_3_4 |
Mario |
10566 |
665 |
590 |
589 |
589 |
210 |
167 |
84 |
noSkim, HLT (IsoMu24_eta2p1_v13), Loose PU jet veto, CSV medium, START53_V7F (the recommended tag for analysis), CMSSW_5_3_4 |
Mario |
10566 |
10566 |
657 |
656 |
656 |
236 |
190 |
94 |
noSkim, noHLT, rest is the same |
Joosep |
10566 |
665 |
589 |
588 |
586 |
227 |
182 |
72 |
HLT (IsoMu24_eta2p1_v13), loose PU jet veto, TCHP tight, START53_V7F, CMSSW_5_3_4, rho corr rel iso (muons) |
Mario |
10566 |
665 |
590 |
589 |
589 |
211 |
168 |
83 |
HLT, loose PU veto, CSVM b-tag, MC smearing, START53_V7F, CMSSW_5_3_4, rho corr rel iso |
Code
Naples ntuplizer
- Naples code can be found here
- Instructions here
CMSSW version: in the first stage, let's stick to 4_2_8 in order to reproduce Naples results. We will have to move to later releases (5_2_X) for the analysis of 2012 data. If we decide to perform the 7 TeV analysis with the full 2011 data set, moving to 4_4_4 is recommended (or to 5_2_X if a re-reco of the 2011 data and MC in this version is ready in time.)
Setting up SingleTop _52X on phys.hep.kbfi.ee
First export the SCRAM_ARCH as
export SCRAM_ARCH=slc5_amd64_gcc462
Now follow the
instructions, but instead of CMSSW_5_2_5 use CMSSW_5_2_5_patch1. The datafiles mentioned in the instructions are copied to
/hdfs/local/stpol/sync_5_2_X
Producing the trees using trees_wrapper_cfg.py
In order to do step 2 to produce the trees from the ntuples, the script
UserCode/STPol/util_scripts/trees_wrapper_cfg.py can be used. Place the script in the CMSSW_4_2_8/src/TopQuarkAnalysis/SingleTop/test directory.
cd CMSSW_4_2_8/src
cvs co UserCode/STPol
cp UserCode/STPol/util_scripts/trees_wrapper_cfg.py TopQuarkAnalysis/SingleTop/test/
cd TopQuarkAnalysis/SingleTop/test/
Also copy the latest version of the file TChannel_cfg.py from the directory
TopQuarkAnalysis/SingleTop/test/synch/
cp synch/TChannel_cfg.py ./
Now run the treemaker as
cmsRun trees_wrapper_cfg.py inputFiles_load=infiles.txt outputFile=out.root maxEvents=-1 channel=CHAN
CHAN is taken from the file
SingleTopPSetsSummer _cfi.py and removing the Ele/Mu suffix. So when running on the TChannel ntuples,
channel=TChannel.
Producing the W-split samples
In order to produce the W-split samples, the input dataset must be the one corresponding to WJets and the channel must be one of
channel=WJets_wlight,
channel=WJets_wbb,
channel=WJets_wcc
Producing trees from data
To process data, the following changes have to be made in TChannel_cfg:
process.TreesMu.doResol = cms.untracked.bool(False)
process.TreesEle.doResol = cms.untracked.bool(False)
process.TreesMu.doPU = cms.untracked.bool(False)
process.TreesEle.doPU = cms.untracked.bool(False)
MC_instruction = False
channel_instruction = "mu"
for muons or
channel_instruction = "ele"
for electrons
process.WeightProducer +
needs to be commented out from the
channel_instruction
Troubleshooting the naples code on phys for CMSSW_4_2_8
A working tagset seems to be
--- Tag --- -------- Package --------
V03-03-07 DataFormats/METReco
V06-04-19-01 DataFormats/PatCandidates
V02-03-00 JetMETCorrections/Algorithms
V05-00-17-01 JetMETCorrections/Modules
V03-01-00 JetMETCorrections/Objects
V04-05-07 JetMETCorrections/Type1MET
CMSSW_4_2_8 PhysicsTools/PatAlgos
V00-05-24 PhysicsTools/PatExamples
b4_2_X_cvMEtCorr_30Nov11 PhysicsTools/PatUtils
V00-03-24 PhysicsTools/SelectorUtils
V08-02-14 PhysicsTools/UtilAlgos
V08-03-10 PhysicsTools/Utilities
V00-04-11 RecoBTag/PerformanceDB
V00-03-31 RecoEgamma/ElectronIdentification
V03-03-05 RecoLuminosity/LumiDB
SingleTop_42X TopQuarkAnalysis/SingleTop
Error occurred while creating for module of type 'SingleTopLeptonCounter' with label 'countLeptons'
StatusMismatch: Parameter 'minNumberTight' is designated as untracked in the code,
but is not designated as untracked in the configuration file.
Please change the configuration file to 'untracked <type> minNumberTight'.
Change the following things in the source files from untracked to tracked
src/SingleTopLeptonCounter.cc
minTight_ = iConfig.getParameter<int>("minNumberTight");
maxTight_ = iConfig.getParameter<int>("maxNumberTight");
minLoose_ = iConfig.getParameter<int>("minNumberLoose");
maxLoose_ = iConfig.getParameter<int>("maxNumberLoose");
python/SingleTopSelectors_cff.py
countLeptons = cms.EDFilter("SingleTopLeptonCounter",
looseMuons = cms.InputTag("looseMuons"),
looseElectrons = cms.InputTag("looseElectrons"),
tightMuons = cms.InputTag("tightMuons"),
tightElectrons = cms.InputTag("tightElectrons"),
qcdMuons = cms.InputTag("tightMuonsZeroIso"),
qcdElectrons = cms.InputTag("tightElectronsZeroIso"),
minNumberTight = cms.int32(1),
maxNumberTight = cms.int32(1),
minNumberLoose = cms.int32(0),
maxNumberLoose = cms.int32(0),
minNumberQCD = cms.untracked.int32(1),
maxNumberQCD = cms.untracked.int32(1),
rejectOverlap = cms.untracked.bool(True),
doQCD = cms.untracked.bool(True),
)
SelectionCuts_Skim_cff.py
minTightLeptons = cms.int32(1)
maxTightLeptons = cms.int32(99)
minLooseLeptons = cms.int32(0)
maxLooseLeptons = cms.int32(99)
Error occurred while creating for module of type 'SingleTopSystematicsTreesDumper' with label 'TreesMu'
Error occurred while creating for module of type 'SingleTopSystematicsTreesDumper' with label 'TreesMu'
---- JetCorrectorParameters BEGIN
No definitions found!!!
---- JetCorrectorParameters END
You need to copy the file from CMSSW_4_2_8/src/TopQuarkAnalysis/SingleTop/test/JEC11_V12_AK5PF_UncertaintySources.txt to CMSSW_4_2_8/src/TopQuarkAnalysis/SingleTop/test/synch
terminate called after throwing an instance of 'boost::exception_detail::clone_impl >'
You need to set the LHAPATH environment variable
export LHAPATH=/cvmfs/cms.cern.ch/slc5_amd64_gcc434/external/lhapdf/5.8.5-cms3/share/lhapdf/PDFsets
python encountered the error: Path 'pathPreselection' contains a module of type 'FastjetJetProducer' which has no assigned label.
Comment the following in
SingleTopMC_PF2PAT_cfg.py
process.load("PhysicsTools.PatUtils.patPFMETCorrections_cff")
process.selectedPatJetsForMETtype1p2Corr.src = cms.InputTag('selectedPatJets')
process.selectedPatJetsForMETtype2Corr.src = cms.InputTag('selectedPatJets')
process.patPFJetMETtype1p2Corr.type1JetPtThreshold = cms.double(10.0)
process.patPFJetMETtype1p2Corr.skipEM = cms.bool(False)
process.patPFJetMETtype1p2Corr.skipMuons = cms.bool(False)
and remove producePatPFMETCorrections from the path
process.pathPreselection = cms.Path(
process.patseq #+ process.producePatPFMETCorrections
)
crab weirdness introducing a lumi discrepancy
Somehow, the results from crab -report and lumiCalc2.py are inconsisent.
Diff between
83a02e9_Jul22 (Mario - old) and
Aug4_c6a4b11(Joosep - new). The former was used for the previous presentation at the single top meeting, and for the plots in the AN/PAS. The latter includes MET-PHI corrections, PU reweighting systematics, top/ttbar reweighting by pt.
data block A
label |
subpath |
parent |
int. lumi (/pb) |
old |
not available, added by lumisection diffs |
|
new |
./Aug1/WD_SingleMu_miss |
/SingleMu/joosep-missing_data-8c29f3a4ed8afc34a59f7c305acd4b13/USER |
1094 |
data block B
label |
subpath |
parent |
int. lumi (/pb) |
old |
./Jul15/WD_SingleMu2 |
/SingleMu/joosep-Jul8_51f69b-7cb0fdcb434651e6fe30ffadc793c329/USER |
4918 |
new |
WD_SingleMu2 |
/SingleMu/joosep-Jul8_51f69b-7cb0fdcb434651e6fe30ffadc793c329/USER |
6398 |
data block C
label |
subpath |
parent |
int. lumi (/pb) |
old |
./Jul15/WD_SingleMu1 |
/SingleMu/joosep-Jul16_7d17c5-7cb0fdcb434651e6fe30ffadc793c329/USER |
6823 |
new |
WD_SingleMu1 |
/SingleMu/joosep-Jul16_7d17c5-7cb0fdcb434651e6fe30ffadc793c329/USER |
6784 |
data block D
label |
subpath |
parent |
int. lumi (/pb) |
old |
WD_SingleMu3 |
/SingleMu/jpata-Jul16_7d17c5-7cb0fdcb434651e6fe30ffadc793c329/USER |
5277 |
new |
./Jul15/WD_SingleMu3 |
/SingleMu/jpata-Jul16_7d17c5-7cb0fdcb434651e6fe30ffadc793c329/USER |
5319 |
Differences between WD_SingleMu2
new
CMSSW.datasetpath : /SingleMu/joosep-Jul8_51f69b-7cb0fdcb434651e6fe30ffadc793c329/USER
CMSSW.dbs_url : https://cmsdbsprod.cern.ch:8443/cms_dbs_ph_analysis_02_writer/servlet/DBSServlet
CMSSW.get_edm_output : 1
CMSSW.lumi_mask : /home/joosep/singletop/stpol/crabs/lumis/Cert_190456-208686_8TeV_22Jan2013ReReco_Collisions12_JSON.txt
CMSSW.lumis_per_job : 100
2013-08-04 02:23:54,216 [INFO] 528 jobs created to run on 67196 lumis
/home/joosep/singletop/stpol/crabs/Aug4_c6a4b11/step2/data/iso/Jul15/WD_SingleMu2
Total Events read: 42747328
Total Files read: 1133
Total Jobs : 528
Luminosity section summary file: /home/joosep/singletop/stpol/crabs/Aug4_c6a4b11/step2/data/iso/Jul15/WD_SingleMu2/res/lumiSummary.json
# Jobs: Done:1
# Jobs: Retrieved:527
old
CMSSW.datasetpath : /SingleMu/joosep-Jul8_51f69b-7cb0fdcb434651e6fe30ffadc793c329/USER
CMSSW.dbs_url : https://cmsdbsprod.cern.ch:8443/cms_dbs_ph_analysis_02_writer/servlet/DBSServlet
CMSSW.get_edm_output : 1
CMSSW.lumi_mask : /home/mario/Summer13/stpol/crabs/lumis/Cert_190456-208686_8TeV_22Jan2013ReReco_Collisions12_JSON.txt
CMSSW.lumis_per_job : 100
2013-07-22 17:13:32,755 [INFO] 520 jobs created to run on 66059 lumis
/home/mario/Summer13/stpol/crabs/83a02e9_Jul22/step2/data/iso/Jul15/WD_SingleMu2
Total Events read: 55737606
Total Files read: 1480
Total Jobs : 520
Luminosity section summary file: /home/mario/Summer13/stpol/crabs/83a02e9_Jul22/step2/data/iso/Jul15/WD_SingleMu2/res/lumiSummary.json
# Jobs: Done:3
# Jobs: Retrieved:517
So somehow, the number of lumis is the same, but the number of events read is different, and thus is the final luminosity! How can that be?
crab -report
lumiCalc2.py -i lumiSummary.json overview
Tallinn analysis code 1 for CMSSW_5_3_X
Access is via github:
https://github.com/HEP-KBFI/stpol
. Instructions are located on github as well.
Analysis macros and other shared material
Our own private macros must be committed in
UserCode/STPol. At the moment this directory is empty, but it will be useful to share macros, scripts, etc.
To check out code from our directory:
cvs co UserCode/STPol
; this creates a directory UserCode/STPol inside the directory where you are located.
Plenty of instructions to use cvs are available on the web, but here follow the few essential ones:
To commit a file or a directory:
cvs add [yourfile]
cvs commit -m 'brief description' [yourfile]
The
cvs add
command is only needed when the file is new on cvs.
If you are already working on an old version of this directory and you know there are updates, type
cvs update
.
See also this
how to
(We will want to use "tags" at some point, but let's start with the basics...)
GRID utilities
The users and passwords have been distributed to everyone. The server name is
phys.hep.kbfi.ee
. To get access to Grid and CMSSW tools you should add this to your .bash_profile file to be included at every login:
export SCRAM_ARCH=slc5_amd64_gcc434
export LCG_GFAL_INFOSYS=bdii.balticgrid.org:2170
source /opt/software/cms/cmsset_default.sh
export CVSROOT=:ext:mario@cmscvs.cern.ch:/cvs_server/repositories/CMSSW
replacing mario with your CERN username in the CVSROOT environment. To use
CRAB you first do cmsenv in some CMSSW software area and then you can source it:
source /opt/software/CRAB_2_7_8/crab.sh
This version of
CRAB doesn't have the 500 job limitation if you want to submit without a
CRAB server. However over 2500 jobs might be problematic as job ID lists will exceed command line limits etc that are way harder to debug out of
CRAB. It's possible, but then we should coordinate as one needs to modify some parts of
CRAB temporarily.
For local storage access (there is no CASTOR access from Tallinn) you have /hdfs/ mounted that is the whole storage. You can access anything that's already transferred to Estonia under /hdfs/cms/store/... including your stageout directory that is for example /hdfs/cms/store/user/mario/... The storage is Hadoop meaning that files that are in there can be either written from scratch or read. You cannot open files in read/write mode.
You can also use VNC on phys, but we recommend using a client that enables ssh tunneling as the default VNC protocol sends cleartext passwords. On Mac the best and fastest possible VNC (that actually allows live working on remote machine with close to 0 lag if the network is decent) is Jolly's Fast VNC. It's not free, but it costs only a few USD on Mac App Store and is well worth the money due to the speed increase as well as all the ssh tunneling etc features. For other OS's you'll have to figure it out on your own
GRID with remoteGlidein
Get a proper clean environment, then initialize crab:
source /opt/software/CRAB_2_8_3/crab.sh
In crab.cfg you must have
[CRAB]
scheduler = remoteGlidein
use_server = 0
[GRID]
se_white_list = kbfi
GRID with local submission from *.hep.kbfi.ee
You need to use a modified version of
CRAB:
source /opt/software/CRAB2/crab.sh
Also, the following modifications are necessary in crab.cfg
[CRAB]
jobtype = cmssw
scheduler = pbsv2withsrm
use_server = 0
[PBSV2WITHSRM]
forceTransferFiles = 1
workernodebase = /home/USERNAME
use_proxy = 1
You can check whether the jobs are running using
qstat
.
Datasets
An essential tool for finding out the datasets you need is the
DAS webpage or the corresponding command-line instructions. See the
FAQs You can also use DBS queries. Example:
dbs --search --query='find file where dataset like /T_TuneZ2_t-channel_7TeV-powheg-tauola/Summer11-PU_S4_START42_V11-v1/AODSIM'
this lists the names of all the files corresponding to that dataset. Type
dbs --help
to know more. See also these
instructions.
Accessing the desired run range in real data requires the use of JSON files. Their use is explained
here (and links within). The repository of officially validated JSON files is
here.
Checking for local datasets in Tallinn using the DAS CLI
das_cli.py --query="dataset site=T2_EE_Estonia" --limit=0 | grep "/Tbar_TuneZ2_s-channel_7TeV-powheg-tauola"
or to find the Summer11+START42 datasets
das_cli.py --query="dataset dataset=/T_TuneZ2_s-channel_7TeV-powheg-tauola/Summer11*START42*AODSIM" --limit=0
Checking the sites of a dataset
das_cli.py --query="site dataset=/T_TuneZ2_s-channel_7TeV-powheg-tauola/Summer11-PU_S4_START42_V11-v1/AODSIM" --limit=0
Getting the list of files for a (local) dataset that has been stored on the instance cms_dbs_ph_analysis_02
das_cli.py --query="file dataset=/SingleMu/atiko-SingleTopPol-Summer11-v42_OldScript_data-75dcb0b28b0100c77354e3c05053de97/USER instance=cms_dbs_ph_analysis_02" --limit=0
8 TeV analysis:
5_3 datasets:
/T_t-channel_TuneZ2star_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /T_t-channel_TuneZ2star_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v2/AODSIM /Tbar_t-channel_TuneZ2star_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /T_tW-channel-DR_TuneZ2star_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /Tbar_tW-channel-DR_TuneZ2star_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /T_s-channel_TuneZ2star_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /Tbar_s-channel_TuneZ2star_8TeV-powheg-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /TTJets_MassiveBinDECAY_TuneZ2star_8TeV-madgraph-tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /WJetsToLNu_TuneZ2Star_8TeV-madgraph-tarball/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /WJetsToLNu_TuneZ2Star_8TeV-madgraph-tarball/Summer12_DR53X-PU_S10_START53_V7A-v2/AODSIM /DYJetsToLL_M-50_TuneZ2Star_8TeV-madgraph-tarball/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /WW_TuneZ2star_8TeV_pythia6_tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /WZ_TuneZ2star_8TeV_pythia6_tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /ZZ_TuneZ2star_8TeV_pythia6_tauola/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /QCD_Pt_20_MuEnrichedPt_15_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /QCD_Pt_20_30_BCtoE_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /QCD_Pt_30_80_BCtoE_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /QCD_Pt_80_170_BCtoE_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /QCD_Pt_170_250_BCtoE_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /QCD_Pt_250_350_BCtoE_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /QCD_Pt_350_BCtoE_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v2/AODSIM
/QCD_Pt_20_30_EMEnriched_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /QCD_Pt_30_80_EMEnriched_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /QCD_Pt_80_170_EMEnriched_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /QCD_Pt_170_250_EMEnriched_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /QCD_Pt_250_350_EMEnriched_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /QCD_Pt_350_EMEnriched_TuneZ2star_8TeV_pythia6/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /GJets_HT-200To400_8TeV-madgraph/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM /GJets_HT-400ToInf_8TeV-madgraph/Summer12_DR53X-PU_S10_START53_V7A-v1/AODSIM
/SingleMu/Run2012A-13Jul2012-v1/AOD /SingleMu/Run2012B-13Jul2012-v1/AOD /SingleMu/Run2012C-PromptReco-v1/AOD /SingleMu/Run2012C-PromptReco-v2/AOD
/SingleElectron/Run2012A-recover-06Aug2012-v1/AOD 190782 - 190949
/SingleElectron/Run2012A-13Jul2012-v1/AOD 190456 - 193621
/SingleElectron/Run2012B-13Jul2012-v1/AOD 193834 - 196531
/SingleElectron/Run2012C-24Aug2012-v1/AOD 198022 - 198523
/SingleElectron/Run2012C-PromptReco-v1/AOD 197770 - 198913
/SingleElectron/Run2012C-PromptReco-v2/AOD 198934 - 202998
The 24th Aug rereco is only a subrange of 2012C v1 so probably a recovery of something. The recover-06Aug2012 seems to be the 2012A ECAL corruption recovery (looking at run ranges). So we need to use them all and just make sure the overlaps are removed. The 13 Jul, 6th aug and 24th aug rerecos have their separate JSON's that should be handled accordingly and the prompt recos need to use the golden JSON and remove the rereco sections.
Some missing Datasets were produced by Dmitri using
FastSim. The results are collected in the following table. SInce the RECO filter was applied, the effective number of generated events necessary for correct normalization is to be determined. The correct CMSSW.dbs_url to use in crab.cfg is
CMSSW.dbs_url= https://cmsdbsprod.cern.ch:8443/cms_dbs_ph_analysis_02_writer/servlet/DBSServlet
name |
dataset |
effective # of gen. events |
ntuple |
merged tuple |
t-channel |
/T_t-channel_TuneZ2star_8TeV-powheg-tauola_CAF_EDM/dkonst-T_t-channel_TuneZ2star_8TeV-powheg-tauola-AOD-FASTSIM_5_2_6_filter-f4dff057d52a2128cc15dd525ba19b60/USER |
0.087238665 |
/T_t-channel_TuneZ2star_8TeV-powheg-tauola_CAF_EDM/jpata-TChannel_ntuples_v2-c7fb5b868024440b562f1d714504aa0d/USER |
srm://ganymede.hep.kbfi.ee:8888/srm/v2/server?SFN=/hdfs/local/stpol/joosep/ntuples/FastSim/ntuples_FastSim_T_t.root |
WJets1 |
/WJetsToLNu_TuneZ2Star_8TeV-madgraph-tarball_EDM_1/dkonst-WJetsToLNu_TuneZ2Star_8TeV-madgraph-tarball_AOD-FASTSIM_5_2_6_filter_1-fdf9c3be443855829751ee3dedf96c91/USER |
??? |
/WJetsToLNu_TuneZ2Star_8TeV-madgraph-tarball_EDM_1/jpata-ntuples_v1_WJets1-c7fb5b868024440b562f1d714504aa0d/USER |
srm://ganymede.hep.kbfi.ee:8888/srm/v2/server?SFN=/hdfs/local/stpol/joosep/ntuples/FastSim/ntuples_FastSim_WJets1.root |
WJets2 |
/WJetsToLNu_TuneZ2Star_8TeV-madgraph-tarball_EDM_2/dkonst-WJetsToLNu_TuneZ2Star_8TeV-madgraph-tarball_AOD-FASTSIM_5_2_6_filter_2-fdf9c3be443855829751ee3dedf96c91/USER |
??? |
/WJetsToLNu_TuneZ2Star_8TeV-madgraph-tarball_EDM_2/jpata-ntuples_v1_WJets2-c7fb5b868024440b562f1d714504aa0d/USER |
srm://ganymede.hep.kbfi.ee:8888/srm/v2/server?SFN=/hdfs/local/stpol/joosep/ntuples/FastSim/ntuples_FastSim_WJets2.root |
WJets3 |
/WJetsToLNu_TuneZ2Star_8TeV-madgraph-tarball_EDM_3/dkonst-WJetsToLNu_TuneZ2Star_8TeV-madgraph-tarball_AOD-FASTSIM_5_2_6_filter_1-fdf9c3be443855829751ee3dedf96c91/USER |
??? |
/WJetsToLNu_TuneZ2Star_8TeV-madgraph-tarball_EDM_3/jpata-ntuples_v1_WJets3-c7fb5b868024440b562f1d714504aa0d/USER |
srm://ganymede.hep.kbfi.ee:8888/srm/v2/server?SFN=/hdfs/local/stpol/joosep/ntuples/FastSim/ntuples_FastSim_WJets3.root |
Systematic samples with 7 to 8 TeV PDF reweighing
Since MC samples for 8
TeV for some systematics were not available, the
TopMonteCarloReweighting tool was used to reweight Fall11 7
TeV samples using CMSSW_4_2 and the corresponding
SingleTop _42X code.
name |
7 TeV dataset |
reweighted dataset (on cms_dbs_ph_analysis_02) |
merged tuple (on T2_EE_Estonia) |
T_t default |
/T_TuneZ2_t-channel_7TeV-powheg-tauola/Fall11-PU_S6_START42_V14B-v1/AODSIM |
??? |
srm://ganymede.hep.kbfi.ee:8888/srm/v2/server?SFN=/hdfs/local/stpol/joosep/ntuples/PDFreweight/ntuples_T_t_default.root |
T_t scaleup |
/T_TuneZ2_scaleup_t-channel_7TeV-powheg-tauola/Fall11-PU_S6_START42_V14B-v1/AODSIM |
/T_TuneZ2_scaleup_t-channel_7TeV-powheg-tauola/jpata-systematics_reweight_7to8TeV_v3_T_t_scaleup-c75044d3a7593caf1221e3b610b44154/USER |
srm://ganymede.hep.kbfi.ee:8888/srm/v2/server?SFN=/hdfs/local/stpol/joosep/ntuples/PDFreweight/ntuples_T_t_scaleup.root |
T_t scaledown |
/T_TuneZ2_scaledown_t-channel_7TeV-powheg-tauola/Fall11-PU_S6_START42_V14B-v1/AODSIM |
/T_TuneZ2_scaledown_t-channel_7TeV-powheg-tauola/jpata-systematics_reweight_7to8TeV_v3_T_t_scaledown-c75044d3a7593caf1221e3b610b44154/USER |
srm://ganymede.hep.kbfi.ee:8888/srm/v2/server?SFN=/hdfs/local/stpol/joosep/ntuples/PDFreweight/ntuples_T_t_scaledown.root |
Tbar_t default |
/Tbar_TuneZ2_t-channel_7TeV-powheg-tauola/Fall11-PU_S6_START42_V14B-v1/AODSIM |
??? |
??? |
Tbar_t scaleup |
/Tbar_TuneZ2_scaledown_t-channel_7TeV-powheg-tauola/Fall11-PU_S6_START42_V14B-v1/AODSIM |
??? |
??? |
Tbar_t scaledown |
/Tbar_TuneZ2_scaledown_t-channel_7TeV-powheg-tauola/Fall11-PU_S6_START42_V14B-v1/AODSIM |
??? |
??? |
TTJets default |
/TTJets_TuneZ2_7TeV-madgraph-tauola/Fall11-PU_S6_START42_V14B-v2/AODSIM |
??? |
??? |
TTJets matchingup |
/TTjets_TuneZ2_matchingup_7TeV-madgraph-tauola/Fall11-PU_S6_START42_V14B-v2/AODSIM |
/TTjets_TuneZ2_matchingup_7TeV-madgraph-tauola/jpata-systematics_reweight_7to8TeV_v3_TTJets_matchingup-c75044d3a7593caf1221e3b610b44154/USER |
??? |
TTJets matchingdown |
/TTjets_TuneZ2_matchingdown_7TeV-madgraph-tauola/Fall11-PU_S6_START42_V14B-v2/AODSIM |
/TTjets_TuneZ2_matchingdown_7TeV-madgraph-tauola/jpata-systematics_reweight_7to8TeV_v3_TTJets_matchingdown-c75044d3a7593caf1221e3b610b44154/USER |
srm://ganymede.hep.kbfi.ee:8888/srm/v2/server?SFN=/hdfs/local/stpol/joosep/ntuples/PDFreweight/ntuples_TTJets_matchingdown.root |
TTJets scaleup |
/TTjets_TuneZ2_scaleup_7TeV-madgraph-tauola/Fall11-PU_S6_START42_V14B-v1/AODSIM |
/TTjets_TuneZ2_scaleup_7TeV-madgraph-tauola/jpata-systematics_reweight_7to8TeV_v3_TTJets_scaleup-c75044d3a7593caf1221e3b610b44154/USER |
??? |
TTJets scaledown |
/TTjets_TuneZ2_scaledown_7TeV-madgraph-tauola/Fall11-PU_S6_START42_V14B-v2/AODSIM |
/TTjets_TuneZ2_scaledown_7TeV-madgraph-tauola/jpata-systematics_reweight_7to8TeV_v3_TTJets_scaledown-c75044d3a7593caf1221e3b610b44154/USER |
??? |
Orso's EDM-ntuples for 8 TeV
Due to their size the latest tuples are on the Naples storage element which can be accessed as follows.
voms-proxy-init -voms cms
lcg-ls -b -D srmv2 -T srmv2 "srm://cmsse02.na.infn.it:8446/srm/managerv2?SFN=/dpm/na.infn.it/home/cms/store/user/oiorio/2012/Summer12/MergedJul24/"
lcg-cp -b -D srmv2 -T srmv2 "srm://cmsse02.na.infn.it:8446/srm/managerv2?SFN=/dpm/na.infn.it/home/cms/store/user/oiorio/2012/Summer12/MergedJul24/remote_file.root" /path/to/local/file.root
7 TeV analysis
As written above, at least in a first stage we want to use 7
TeV data and MC to make sure that we are synchronized with the cross section analysis of TOP-11-021.
Therefore, data and MC samples must be the same as listed in slides 5 and 75 of the
TOP-11-021 approval talk (in principle also in tables 1 and 2 of
AN-2011-229).
This means that CMSSW_4_2_8 must be used, and only the first 1.14/fb in the muon channel and 1.51/fb in the electron channel will be analyzed. This corresponds to the following JSON files:
- Cert_160404-163869_7TeV_May10ReReco_Collisions11_JSON_v3.txt
- Cert_160404-180252_7TeV_PromptReco_Collisions11_JSON.txt
- Cert_170249-172619_7TeV_ReReco5Aug_Collisions11_JSON_v3.txt
The complete dataset names for the MC samples in Table 2 are obtained by adding
/Summer11-PU_S4_START42_V11-v1/AODSIM
(e.g.,
/T_TuneZ2_t-channel_7TeV-powheg-tauola/Summer11-PU_S4_START42_V11-v1/AODSIM
) Is this true? 42_V11 no longer exists in Tallinn, instead there is 42_V14B.
The MC datasets from the analysis present in Tallinn (under the conditions of tag=START42 and either Fall11 or Summer11) are
/T_TuneZ2_t-channel_7TeV-powheg-tauola
/Tbar_TuneZ2_t-channel_7TeV-powheg-tauola
/T_TuneZ2_s-channel_7TeV-powheg-tauola -> /T_TuneZ2_s-channel_7TeV-powheg-tauola/Fall11-PU_S6_START42_V14B-v1/AODSIM
/Tbar_TuneZ2_s-channel_7TeV-powheg-tauola
/T_TuneZ2_tW-channel-DR_7TeV-powheg-tauola
/Tbar_TuneZ2_tW-channel-DR_7TeV-powheg-tauola
/TTJets_TuneZ2_7TeV-madgraph-tauola
/WJetsToLNu_TuneZ2_7TeV-madgraph-tauola
/DYJetsToLL_TuneZ2_M-50_7TeV-madgraph-tauola
/QCD_Pt-20_MuEnrichedPt-15_TuneZ2_7TeV-pythia6
/QCD_Pt-80to170_EMEnriched_TuneZ2_7TeV-pythia7
And the ones missing are:
/WW_TuneZ2_7TeV_pythia6_tauola
/WZ_TuneZ2_7TeV_pythia6_tauola
/ZZ_TuneZ2_7TeV_pythia6_tauola
/QCD_Pt-20to30_BCtoE_TuneZ2_7TeV-pythia7
/QCD_Pt-30to80_BCtoE_TuneZ2_7TeV-pythia6
/QCD_Pt-80to170_BCtoE_TuneZ2_7TeV-pythia6
/QCD_Pt-20to30_EMEnriched_TuneZ3_7TeV-pythia6
/QCD_Pt-30to80_EMEnriched_TuneZ2_7TeV-pythia6
/GJets_TuneD6T_HT-40To100_7TeV-madgraph
/GJets_TuneD6T_HT-100To200_7TeV-madgraph
/GJets_TuneD7T_HT-200_7TeV-madgraph
All the MC datasets processed with
SingleTopMC_PF2PAT_cfg.py
are available
here and data
here.
FCNC samples:
- t,j -> b,l,nu,j with tug coupling.(MCDB 3655)
/TJetToBLNuJet_FCNC_tug_TuneZ2_7TeV-comphep-EDM/dkonst-TJetToBLNuJet_FCNC_tug_TuneZ2_7TeV-comphep-FASTSIM-92a8e0ecc98e6ae221fc036cdde0c771/USER
dbs_url= https://cmsdbsprod.cern.ch:8443/cms_dbs_ph_analysis_02_writer/servlet/DBSServlet
- t,j -> b,l,nu,j with tcg coupling.(MCDB 3655) 1 job is still running.
- t,j -> b,l,nu,j with tug and tcg (MCDB 3654) are still running
FCNC datasets after step one are
here
Unfolding
Documentation about the KIT-style unfolding, as used in the ttbar A_C analysis (courtesy by Jeannine and collaborators):
TSVDUnfolding:
RooUnfold:
Statistics Committee interim note on unfolding:
MET-phi modulation studies
Private productions with Fast Simulation
Eventually, we will request official samples of non-SM signals from interesting models to be produced with Full Simulation. But before requesting an official production we need to validate the generation parameters, and anyway they will take time before being ready.
Ad interim, then, we should use FastSim for private productions.
In this section we will list and describe several configuration files (to be stored somewhere in our
UserCode/STPol directory).
It is useful to use the cmsDriver script to create standard configuration files.
To be coherent with 4_2_X samples from the "Summer11" production, the following string must be used (in 4_2_8):
cmsDriver.py GEN-fragment --step GEN,FASTSIM,HLT:GRun --beamspot Realistic7TeV2011Collision --conditions START42_V11::All --pileup FlatDist10_2011EarlyData_50ns --geometry DB --datamix NODATAMIXER --eventcontent AODSIM --datatier AODSIM
Documentation
The URL of the svn web browser for our documents is
https://svnweb.cern.ch/cern/wsvn/tdr2/?. Your AN is under notes.
Instructions for retrieving the template version and building it are now
available on the wiki at
https://twiki.cern.ch/twiki/bin/view/CMS/Internal/TdrProcessing There are
additional hints in the template document itself, which is available
formatted as
https://svnweb.cern.ch/cern/wsvn/tdr2/papers/XXX-08-000/trunk/XXX-08-000_temp.pdf
Please note the use of our standard definitions for particle names
and commonly used HEP terms as shown in the appendices. BibTeX hints are in
both the tex and bib files. A more thorough treatment of many CMS document
production tasks may be found at
https://svnweb.cern.ch/cern/wsvn/tdr2/utils/branches/dev/general/notes_for_authors.pdf
(for the development version). The general CMS style guide is
currently located at
https://twiki.cern.ch/twiki/bin/view/CMS/Internal/PubGuidelines, and the
publications wiki page is
https://twiki.cern.ch/twiki/bin/viewauth/CMS/Internal/Publications
Analysis Note 2012/448
> svn co -N svn+ssh://svn.cern.ch/reps/tdr2 myDir # where myDir is a placeholder for a name of your choice
> cd myDir
> svn update utils
> svn update -N notes
> svn update notes/AN-12-448
> eval `./notes/tdr runtime -csh` # for tcsh. use -sh for bash.
> cd notes/AN-12-448/trunk
# (edit the template, then to build the document)
> tdr --style=an b AN-12-448
You can commit your changes with
> svn commit -m "commit message"
New files will first need to be added with
> svn add NewFileNames
before they can be committed.
Note: I committed a script MAKENOTE for compiling without having to remember the exact command line.
PAS TOP-13-001
> svn co -N svn+ssh://svn.cern.ch/reps/tdr2 myDir # where myDir is a placeholder for a name of your choice
> cd myDir
> svn update utils
> svn update -N notes
> svn update notes/TOP-13-001
> eval `./notes/tdr runtime -csh` # for tcsh. use -sh for bash.
> cd notes/TOP-13-001/trunk
# (edit the template, then to build the document)
> tdr --style=pas b TOP-13-001
You can commit your changes with
> svn commit -m "commit message"
New files will first need to be added with
> svn add NewFileNames
before they can be committed.
Note: I committed a script MAKEPAS for compiling without having to remember the exact command line.
I also committed a couple of shell scripts (.sh) to compare some files that are supposed to be the same in AN and PAS, and to copy from AN to PAS.
Wiki of answers to reviewers
PasTop13001QA
To-do-list towards the final paper
- Why so much QCD in muon channel? [Joosep]
- Check if more statistics can be produced for the MC-limited systematic samples, especially for Wjets and Zjets
- Move from TCHP to CSV at step 2 [Joosep]
- BDT anti-QCD [Morten]
- QCD estimation based on fit to its output [Andres]
- Specialized anti-Wjets and anti-ttbar BDTs [Mario?, Morten?]
- 2D fit in the plane of their two outputs [Steffen]
- or, in alternative, train super-BDT using as input the outputs of the specialized BDTs (including the anti-QCD one?)
- Find a solid way to choose the optimal cut (not necessarily a rectangular cut, in case of the 2D plane)
- "Real" linearity check with anomalous comphep samples
- Find optimal binning size [Steffen]
- Combine muon+electron channels without using BLUE, i.e. immediately after unfolding [Steffen,Thorsten]
- Verify that TopFit is well behaving, and resurrect anomalous limits [Matthias]
- Resurrect cut-based cross-check analysis (based on C instead of eta_j'?) [Andres, Steffen]
- Separate measurements for top and antitop (in addition, not as replacement to the global result.)
Talks in CMS meetings
--
AndreaGiammanco - 16-Mar-2012