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GEANT SIMULATION of CREAM-I
Jayoung Wu UMD June14-15, 2007
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CREAM-I configuration
S0X S0Y S1X S1Y SCD TARGET1 S2X S2Y TARGET2 S3Y CALORIMETER June 14-15, 2007 Jayoung Wu, UMD
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an example of event Ein = 150 GeV charged particles (except muon)
inc. part. = proton inc. pos. = (10.545, , 88) gamma 1st intr. pos. = (10.545, , ) Neutral hadrons or neutrinos Total Ed = GeV June 14-15, 2007 Jayoung Wu, UMD
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Output Data Format Event #, Random Seeds
COORDINATES OF THE FIRST INTERACTION =X, Y, Z SCD and SCN HODO INFORMATION (INCIDENT ONLY) energy deposit by incident particle in si and each scn layer layer energy deposit(GeV) 1 SI 2 S0X 3 S0Y 4 S1X 5 S1Y 6 S2X 7 S2Y 8 S3Y June 14-15, 2007 Jayoung Wu, UMD
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Output Data Format - continued
4. ENERGY DEPOSITION IN SCD energy deposit in each si pixel( * *0.038) pixel # [energy deposit/GeV] pixel index in output data si(52, 56) si(2912) 56 2861 2912 y y … x x 3 2 53 104 1 2 3 52 1 … 1 2 3 52 June 14-15, 2007 Jayoung Wu, UMD
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Output Data Format - continued
5. ENERGY DEPOSITION IN SCN HODO energy deposit in each scn strip strip # [energy deposit/GeV] 380 y x S0X 2 LAYER STRIP# DIMENSION S0X S0Y 1 – * 76 * 0.2 S1X S1Y 1 – * 76 * 0.2 S2X S2Y 1 – * 64.2 * 0.2 S3Y – * 52* 0.2 1 y x S0Y 1 2 380 June 14-15, 2007 Jayoung Wu, UMD
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Output Data Format - continued
6. ENERGY DEPOSITION IN TUNG CALORIMETER energy deposit in each tungsten layer layer # [energy deposit/GeV] z x 1 2 20 June 14-15, 2007 Jayoung Wu, UMD
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Output Data Format - continued
7. ENERGY DEPOSITION IN SCN CALORIMETER energy deposit in 19 scn fibers of each ribbon ribbon # [energy deposit/GeV] odd layers (1, 3, …, 19) even layers (2, 4, …, 20) y 50 19 fibers y x … x … 2 19 fibers … 1 2 50 1 19 fibers … 19 fibers 19 fibers 19 fibers 8. SUM total energy deposit in SCN calorimeter [energy deposit/GeV] June 14-15, 2007 Jayoung Wu, UMD
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Simulation Output ***** EVENT: 1, RNDM SEEDS: 128621967 2079139486
x = y = Ein = GeV COORDINATES OF THE FIRST INTERACTION = SCD and SCN HODO INFORMATION (INCIDENT ONLY) S EDP/GeV E-03 E-03 E-03 E-03 E-03 ENERGY DEPOSITION IN SCD 1846[ E-03] 1853[ E-03] 2159[ E-03] June 14-15, 2007 Jayoung Wu, UMD
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Simulation Output – continued
ENERGY DEPOSITION IN SCN HODO LAYER = SX0 243[ E-03] 247[ E-03] 248[ E-04] 269[ E-03] 270[ E-03] 271[ E-02] 273[ E-04] 274[ E-02] 275[ E-03] LAYER = SY0 174[ E-04] 175[ E-03] 176[ E-02] 177[ E-03] 190[ E-03] 243[ E-03] LAYER = SX1 243[ E-03] 271[ E-02] LAYER = SY1 177[ E-03] 178[ E-02] 179[ E-04] 243[ E-03] LAYER = SX2 203[ E-03] 204[ E-03] 205[ E-03] 206[ E-03] 210[ E-03] 212[ E-03] 213[ E-03] 214[ E-03] 220[ E-03] LAYER = SY2 187[ E-04] 188[ E-03] 201[ E-04] 202[ E-03] 208[ E-03] 209[ E-02] 212[ E-03] 214[ E-03] 218[ E-03] 219[ E-03] June 14-15, 2007 Jayoung Wu, UMD
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Simulation Output – continued
LAYER = SY3 187[ E-04] 188[ E-03] 201[ E-04] 202[ E-03] 208[ E-03] 209[ E-02] 212[ E-03] 214[ E-03] 218[ E-03] 219[ E-03] ENERGY DEPOSITION IN TUNG CALORIMETER L EDP/GeV June 14-15, 2007 Jayoung Wu, UMD
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Simulation Output – continued
ENERGY DEPOSITION IN SCN CALORIMETER CAL LAYER = 1 24[ E-05] 25[ E-04] 35[ E-02] 36[ E-02] 37[ E-04] 38[ E-04] 41[ E-03] CAL LAYER = 2 25[ E-02] 29[ E-04] 31[ E-04] 32[ E-03] 33[ E-03] 35[ E-03] 36[ E-02] 37[ E-02] 38[ E-02] CAL LAYER = 3 24[ E-03] 34[ E-02] 35[ E-02] 36[ E-02] 37[ E-03] 38[ E-02] 39[ E-03] 41[ E-04] 42[ E-04] 44[ E-02] CAL LAYER = 4 31[ E-04] 32[ E-02] 33[ E-03] 35[ E-02] 36[ E-02] 37[ E-02] 38[ E-03] 39[ E-04] CAL LAYER = 5 16[ E-04] 23[ E-04] 33[ E-04] 34[ E-02] 35[ E-02] 36[ E-02] 37[ E-02] 38[ E-02] 39[ E-03] 41[ E-04] 42[ E-04] June 14-15, 2007 Jayoung Wu, UMD
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Simulation Output – continued
CAL LAYER = 6 30[ E-03] 32[ E-03] 33[ E-03] 34[ E-03] 35[ E-02] 36[ E-02] 37[ E-02] 38[ E-02] 39[ E-03] CAL LAYER = 7 22[ E-03] 23[ E-04] 34[ E-03] 35[ E-02] 36[ E-02] 37[ E-03] 38[ E-02] 39[ E-03] 40[ E-03] 41[ E-03] 42[ E-04] CAL LAYER = 8 30[ E-03] 32[ E-03] 34[ E-03] 35[ E-02] 36[ E-02] 37[ E-02] 38[ E-02] 39[ E-03] 40[ E-03] 42[ E-04] CAL LAYER = 9 33[ E-04] 34[ E-02] 35[ E-02] 36[ E-02] 37[ E-02] 38[ E-02] 39[ E-03] 40[ E-03] 41[ E-04] 42[ E-04] CAL LAYER = 10 30[ E-04] 34[ E-04] 35[ E-02] 36[ E-01] 37[ E-02] 38[ E-03] 39[ E-02] 44[ E-06] June 14-15, 2007 Jayoung Wu, UMD
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Simulation Output – continued
CAL LAYER = 11 30[ E-04] 33[ E-04] 34[ E-03] 35[ E-02] 36[ E-02] 37[ E-02] 38[ E-02] 39[ E-02] 42[ E-04] 43[ E-03] CAL LAYER = 12 30[ E-04] 32[ E-03] 34[ E-03] 35[ E-03] 36[ E-02] 37[ E-02] 38[ E-03] 39[ E-03] CAL LAYER = 13 30[ E-03] 31[ E-03] 32[ E-04] 34[ E-03] 35[ E-02] 36[ E-02] 37[ E-03] 38[ E-03] 39[ E-02] 42[ E-04] 43[ E-04] CAL LAYER = 14 29[ E-04] 33[ E-04] 34[ E-04] 35[ E-02] 36[ E-02] 37[ E-03] 38[ E-03] 39[ E-04] CAL LAYER = 15 34[ E-03] 35[ E-02] 36[ E-02] 37[ E-02] 38[ E-02] 39[ E-02] 40[ E-03] 41[ E-03] 42[ E-04] 43[ E-05] June 14-15, 2007 Jayoung Wu, UMD
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Simulation Output – continued
CAL LAYER = 16 29[ E-04] 34[ E-03] 35[ E-03] 36[ E-02] 37[ E-03] 38[ E-03] 39[ E-04] CAL LAYER = 17 35[ E-02] 36[ E-02] 37[ E-04] 38[ E-02] 39[ E-02] 40[ E-04] 42[ E-04] CAL LAYER = 18 29[ E-04] 34[ E-04] 35[ E-03] 36[ E-03] 37[ E-03] 38[ E-03] 39[ E-04] CAL LAYER = 19 33[ E-03] 34[ E-03] 35[ E-03] 36[ E-03] 37[ E-03] 38[ E-03] 39[ E-03] 43[ E-04] 44[ E-04] 48[ E-01] CAL LAYER = 20 28[ E-04] 36[ E-03] 37[ E-03] 38[ E-03] 39[ E-04] SUM = June 14-15, 2007 Jayoung Wu, UMD
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Simulation Data List as 6/4/07
1. Vertical Incident Particle Inc. Energy Inc. Pos. (cm) Tot # of Events comments (x,y,z) ============================================================================ p 100 GeV (10.545,10.545,88) 1k p 150 GeV (10.545,10.545,88) 1k smpl SCD* p 250 GeV (10.545,10.545,88) 1k smpl SCD* p 350 GeV (10.545,10.545,88) 1k smpl SCD* p 1 TeV (10.545,10.545,88) 1k smpl SCD* p 1 TeV (10.545,10.545,88) 1k p 1 TeV ( 9.545, 9.545,88) 3k p 1 TeV ( 0.545, 0.545,88) 1k p 10 TeV (10.545,10.545,88) smpl SCD* p 10 TeV (10.545,10.545,88) 1157 p 10 TeV ( 0.545, 0.545,88) 176 p 100 TeV (10.545,10.545,88) smpl SCD* p 100 TeV (10.545,10.545,88) running(393) smpl SCD* 1cmCAL* e GeV (10.545,10.545,88) 1k NOTE: smpl SCD* = no supporting materials in SCD configuration 1cm CAL* = use 1 * 50 * 0.05 strip instead of 19 fibers for CAL SCN June 14-15, 2007 Jayoung Wu, UMD
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Simulation Data List -- continued
2. Isotropic Incident Particle Inc. Energy Tot # of Events ============================================= p 1 TeV 10k p 2 TeV 10k p 3 TeV 10k p 5 TeV 10,828 p 10 TeV 10,194 p 50 TeV running(2763) 3. Simulation Data available on CREAM website: June 14-15, 2007 Jayoung Wu, UMD
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