The Level 3 part of the trigger rate tool has been completely rewritten and this has also meant that the trigger names have been changed considerably. ------------------------------ Level 3 ------------------------ Missing ET filter: L3MET(x) with x=10,15,20,25,30,40,50 Jets: all types of jets are now available (SC5JET_8_PV1, SC5JET_8_PV3, SC5JET_9_PV1 and SC5JET_9_PV3, but for run 204974 only the last two are actually declared in the triggerlist used for trigsim). The threshold for the jet finding is at either 8 or 9 GeV, the rapidity coverage is |eta|<3.6, the primary vertex finder uses tracks with a cut at 1 or 3 GeV). The acoplanarity filter will not trigger on single jet events as well. The different types of jet are identified by the "yy" code below with the following translation table: SC5JET_8_PV1 ---> **=81 SC5JET_8_PV3 ---> **=83 SC5JET_9_PV1 ---> **=91 SC5JET_9_PV3 ---> **=93 L3JET**(n,x) with n=1,2,3,4,5 and x=8,9,10,12,15,18,20,25,30,35,40 L3HT**(x) with x=40,50,60,70,80,90,100,110,120,125,130,140,150,200 L3HTA**(x) with x=30,40,50,60,70,80,90,100 L3JACOP**(x) with x=135,165,170,175 L3MHT**(x) with x=15,20,25.30.35,40 A new filter MHTAngle is emulated: this filter requires a missing MHT in excess of x GeV which does not point in the direction of the two leading jets (a separation of at least y degrees from the axis of the jets is required). L3MHTAngle**(x,y,z) with x=10,15,20,25,30 and y= 5,10,15,20,25 and z=180-y or 180 QCD jet triggers: uses SCJET_8 jets (threshold at 8 GeV, covers rapidity range |eta|<4.0) L3QCD(x) request 1 jet with Et>x, with x=8,15,25,45,65,95,125 L3JETMASS(x) request 2 jets with invariant mass x=225,250,300, 320,340,360,380,400,430,460,500 Muons: there are now 7 types of muon triggers: L3MU(n,type,x) n=1,2 type=As,ls,md,tg x=0,1,2,3,4,5,6,8,10,12,15,20 GeV requires n local muons with quality type A-stub, loose, medium or tight and pT>x GeV L3MU_CM(n,type,x) n=1,2 type=As,ls,md,tg x=0,1,2,3,4,5,6,8,10,12,15,20 GeV require n muons with a central track match and quality type A-stub, loose, medium or tight and pT>x GeV L3MU_CMIsoT1(n,type,x) n=1,2 type=As,ls,md,tg x=0,1,2,3,4,5,6,8,10,12,15,20 GeV require n muons matched to a tightly isolated central track and quality type A-stub, loose, medium or tight and pT>x GeV L3MU_CMIsoL1(n,type,x) n=1,2 type=As,ls,md,tg x=0,1,2,3,4,5,6,8,10,12,15,20 GeV require n muons matched to a loosely isolated central track and quality type A-stub, loose, medium or tight and pT>x GeV L3MU_CM(n,type,x) n=1,2 type=As,ls,md,tg x=0,1,2,3,4,5,6,8,10,12,15,20 GeV require n muons matched to tightly isolated central track and quality require n muons with a central track match and quality type A-stub, loose, medium or tight and pT>x GeV L3MU_BTAG_CM(1,ls,x) require 1 loose muon with a pT>x GeV. The muon is matched to a central track with pT>3 GeV and an impact parameter significance of at least 3 and also matched to a jet with at least 9 GeV of transverse energy L3MU_IP3_CM(n,ls,x) n=1,2 x=0,1,2,3,4,5 GeV require n muons matched to a central track with an impact parameter significance of at least 3 and pT>x GeV there is also a dimuon invariant mass trigger: L3MUMASS_CM(1.5,2.5,4.0,opp) requires a pair of muons with pT>1.5 GeV, both matched to central tracks and with opposite charges, having an invariant mass between 2.5 and 4.0 GeV Electrons: when more than 1 electron fire a trigger in Level 3 the name of the filter is prepended with a digit indicating the number of L3 electron trigger candidates of that type. Below the threshold x can assume the following values: x=2,3,4,5,6,7,8,10,11,12,13,15,18,20,22,24,25,28,30,35,40,50,60,70,80,90,100 NCx: find electron candidates passing very loose requirements (no cut on EM fraction). VL: find electron candidates passing loose requirements (EM fraction greater than 0.8). Lx: find electron candidates passing loose requirements (EM fraction greater than 0.9). SHx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 2.3, 1.7, 1.5 in the CC and 1.4, 1.35 and 1.4 in the EC). SHTx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a tight shower shape cut (width: 1.8, 1.4, 1.15 in the CC and 1., 1. and 1.2 in the EC). SHIx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 2.3, 1.7, 1.5 in the CC and 1.4, 1.35 and 1.4 in the EC) and require the ratio of the energy in the ring covering 0.25 < dR < 0.4 to be smaller than 2 GeV. SHTIx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 1.8, 1.4, 1.15 in the CC and 1., 1. and 1.2 in the EC) and require the ratio of the energy in the ring covering 0.25 < dR < 0.4 to be smaller than 2 GeV. TyVLx: find electron candidates passing the loose requirements (EM fraction greater than 0.8) and matched to a track (pT>25 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1. TPyVLx: find electron candidates passing the loose requirements (EM fraction greater than 0.8) and matched to a track (pT>25 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1, with an E/p ratio between 0.4 and 1.3 TyLx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and matched to a track (pT>5 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1. TPyLx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and matched to a track (pT>5 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1, with an E/p ratio between 0.4 and 1.3 TySHx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 2.3, 1.7, 1.5 in the CC and 1.4, 1.35 and 1.4 in the EC) and require a track match (pT>5 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1. T{ySHx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 2.3, 1.7, 1.5 in the CC and 1.4, 1.35 and 1.4 in the EC) and require a track match (pT>5 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1, with an E/p ratio between 0.4 and 1.3 TySHTx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a tight shower shape cut (width: 1.8, 1.4, 1.15 in the CC and 1., 1. and 1.2 in the EC) and require a track match (pT>5 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1. TPySHTx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a tight shower shape cut (width: 1.8, 1.4, 1.15 in the CC and 1., 1. and 1.2 in the EC) and require a track match (pT>5 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1, with an E/p ratio between 0.4 and 1.3 lTIySHx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 2.3, 1.7, 1.5 in the CC and 1.4, 1.35 and 1.4 in the EC) and require a track match (pT>7 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1 with an isolated track (sum of the pT of other tracks < 3 GeV). lTIPySHx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 2.3, 1.7, 1.5 in the CC and 1.4, 1.35 and 1.4 in the EC) and require a track match (pT>7 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1 with an isolated track (sum of the pT of other tracks < 3 GeV), which also satisfies 0.4 < E/p < 1.3. mTIySHx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 2.3, 1.7, 1.5 in the CC and 1.4, 1.35 and 1.4 in the EC) and require a track match (pT>7 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1 with an isolated track (sum of the pT of other tracks < 2 GeV). mTIPySHx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 2.3, 1.7, 1.5 in the CC and 1.4, 1.35 and 1.4 in the EC) and require a track match (pT>7 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1 with an isolated track (sum of the pT of other tracks < 2 GeV), which also satisfies 0.4 < E/p < 1.3. tTIySHx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 2.3, 1.7, 1.5 in the CC and 1.4, 1.35 and 1.4 in the EC) and require a track match (pT>7 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1 with an isolated track (sum of the pT of other tracks < 1 GeV). tTIPySHx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 2.3, 1.7, 1.5 in the CC and 1.4, 1.35 and 1.4 in the EC) and require a track match (pT>7 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1 with an isolated track (sum of the pT of other tracks < 1 GeV), which also satisfies 0.4 < E/p < 1.3. lTIySHTx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a tight shower shape cut (width: 1.8, 1.4, 1.15 in the CC and 1., 1. and 1.2 in the EC) and require a track match (pT>7 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1 with an isolated track (sum of the pT of other tracks < 3 GeV) lTIySHTx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a tight shower shape cut (width: 1.8, 1.4, 1.15 in the CC and 1., 1. and 1.2 in the EC) and require a track match (pT>7 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1 with an isolated track (sum of the pT of other tracks < 3 GeV), which also satisfies 0.4 < E/p < 1.3. mTIySHTx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a tight shower shape cut (width: 1.8, 1.4, 1.15 in the CC and 1., 1. and 1.2 in the EC) and require a track match (pT>7 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1 with an isolated track (sum of the pT of other tracks < 3 GeV) mTIySHTx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a tight shower shape cut (width: 1.8, 1.4, 1.15 in the CC and 1., 1. and 1.2 in the EC) and require a track match (pT>7 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1 with an isolated track (sum of the pT of other tracks < 3 GeV), which also satisfies 0.4 < E/p < 1.3. tTIySHTx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a tight shower shape cut (width: 1.8, 1.4, 1.15 in the CC and 1., 1. and 1.2 in the EC) and require a track match (pT>7 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1 with an isolated track (sum of the pT of other tracks < 2 GeV) tTIySHTx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a tight shower shape cut (width: 1.8, 1.4, 1.15 in the CC and 1., 1. and 1.2 in the EC) and require a track match (pT>7 GeV) within |dEta|<0.2, |dPhi|<0.2 and dR<0.1 with an isolated track (sum of the pT of other tracks < 1 GeV), which also satisfies 0.4 < E/p < 1.3. ISHx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 2.3, 1.7, 1.5 in the CC and 1.4, 1.35 and 1.4 in the EC) and apply a track isolation cut (the sum of the pT of tracks in 0.05 < dR < 0.4 is 1 GeV at most). ISHTx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a tight shower shape cut (width: 1.8, 1.4, 1.15 in the CC and 1., 1. and 1.2 in the EC) and apply a track isolation cut (the sum of the pT of tracks in 0.05 < dR < 0.4 is 1 GeV at most). PSSHx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 2.3, 1.7, 1.5 in the CC and 1.4, 1.35 and 1.4 in the EC) and require a CPS cluster matching the electron candidate. PSSHTx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a tight shower shape cut (width: 1.8, 1.4, 1.15 in the CC and 1., 1. and 1.2 in the EC) and require a CPS cluster matching the electron candidate. TPSSHx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 2.3, 1.7, 1.5 in the CC and 1.4, 1.35 and 1.4 in the EC) and require a CPS cluster matching a track. PSTSHx: find electron candidates passing the loose requirements (EM fraction greater than 0.9) and add a shower shape cut (width: 2.3, 1.7, 1.5 in the CC and 1.4, 1.35 and 1.4 in the EC) and require a CPS cluster matching a track which matches the electron candidate. RLx: find electron candidates reconstructed with the road method (EM fraction larger than 0.6, E/p between 0.4 and 1.3) with a track with pT>2 GeV. RTx: find electron candidates reconstructed with the road method (EM fraction larger than 0.6, E/p between 0.6 and 1.05) with a track with pT>2 GeV. Tau: the names of the tau candidates have been completely changed, but internally nothing has L3TAU(n,x,NNy) for n=1,2 x=5,7,10,15 or 20 GeV with different neural networks output (noNN, NN03, NN05, NN07, indicating at which threshold you are going to trigger. Tracks: the number of tracks has increased consideraly: L3TK(n,pT,hits,type) where n is the number of tracks (1-4), pT is the threshold (0.5,0.75,1., 1.25,1.5,2.,2.5,3.,4.,5.,6.,7.,8.,10.,12.,13.,15.,20.,25.), hits is the number of hits required on the track (8 or 10) and type is one of the following: Trk05 - minimum track finding pT 0.5 GeV (recommended for b-physics triggers) Trk1 - minimum track finding pT 1. GeV Trk2 - minimum track finding pT 2. GeV Trk3 - minimum track finding pT 3. GeV (recommended for high pT triggers) Trk5 - minimum track finding pT 5. GeV Trk10 - minimum track finding pT 10. GeV HTrk10 - minimum track finding pT 10. GeV, uses HTrack algorithm Iso3L1 - minimum track finding pT 3 GeV, loose track isolation requirement (variant 1) Iso3L2 - minimum track finding pT 3 GeV, loose track isolation requirement (variant 2) Iso3T1 - minimum track finding pT 3 GeV, tight track isolation requirement (variant 1) Iso3T2 - minimum track finding pT 3 GeV, tight track isolation requirement (variant 2) L3TK(n,pT,type) where n is the number of tracks (1-4), pT is the threshold (0.5,0.75,1., 1.25,1.5,2.,2.5,3.,4.,5.,6.,7.,8.,10.,12.,13.,15.,20.,25.) and type is: IP3 - minimum track finding pT 0.5 GeV, impact parameter significance > 3 L3PHIMASS(pT,hits,type): require two tracks with pT>0.5 GeV (10 axial hits) and an invariant mass compatible with the phi-->KK decay where hits (10) is the minimum number of axial hits on the track and type (PhTrk05) contains the threshold used in the track finding. The mininum pT can assume the values of 0.5 and 0.75 GeV. L3PHIMASS(pT,IP3): require two tracks with pT>0.5 GeV (10 axial hits) with impact parameter significance of at least 3 and an invariant mass compatible with the phi-->KK decay where hits (10) is the minimum number of axial hits on the track and type (PhTrk05) contains the threshold used in the track finding. The mininum pT can assume the values of 0.5 and 0.75 GeV. L3D0MASS(pT,hits,type) Similarly for the D0-->Kp combination (both combination are tested). L3D0MASS(pT,IP3) B-tagging: BIDnn require at least one jet with b-tagging probability BIDnn_6 require at least one jet with b-tagging probability (only 1st six jets considered) B3Dnn require at least one jet with b-tagging probability (use 3D) B3Dnn_6 require at least one jet with b-tagging probability (use 3D, only 1st six jets considered) nn = 05 (p>0.05), 10 (p>0.10), 15 (p>0.15), 30 (p>0.30), 50 (p>0.50), 70 (p>0.70) BJET(n,x) require n jets with b-tagging probability larger than x=0.05,0.1,0.15,0.3,0.5,0.7,1.0 BJET3D(n,x) ditto but with 3D