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Thomas Jefferson National Accelerator Facility Page 1 CLAS12 Computing Requirements G.P.Gilfoyle University of Richmond.

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Presentation on theme: "Thomas Jefferson National Accelerator Facility Page 1 CLAS12 Computing Requirements G.P.Gilfoyle University of Richmond."— Presentation transcript:

1 Thomas Jefferson National Accelerator Facility Page 1 CLAS12 Computing Requirements G.P.Gilfoyle University of Richmond

2 Thomas Jefferson National Accelerator Facility Page 2 CLAS12 Computing Requirements Assume October, 2014 start date. Present major assumptions and results for:  Data acquisition  Calibration  Simulation  Reconstruction  Reconstruction studies  Physics analysis.

3 Thomas Jefferson National Accelerator Facility Page 3 CLAS12 Computing Requirements Data Acquisition Assumptions:Event rate = 10 kHzWeeks running = 35 Event size = 10 kBytes24-hour duty factor = 60% Data Rate = Event Rate x Event Size = 100 Mbyte/s Average 24-hour rate = Data Rate x 24-hour duty factor = 60 Mbyte/s Events/year = Event Rate x Weeks Running x 24-hour duty factor = 1.3x10 11 Events/year Data Volume/year = Events/year x Event size = 1270 TByte/year

4 Thomas Jefferson National Accelerator Facility Page 4 CLAS12 Computing Requirements Calibration Assumptions:CPU-time/event = 155 msData fraction = 5% Data Passes = 5Core efficiency = 90% CPU-time/year = Events/year x CPU-time/event-core x Data fraction x Data passes = 4.9x10 9 s Calibration Cores = (CPU-time/year)/(year in seconds x Core efficiency) = 173 cores

5 Thomas Jefferson National Accelerator Facility Page 5 CLAS12 Computing Requirements Reconstruction - 1 Assumptions:CPU-data-time/event = 155 ms Output/input size = 2 Data passes = 2 Fraction to disk = 10% Event size = 10 kBytes Events/year = 1.3 x 10 11 Data volume/year = 1.3 Pbytes/year Core efficiency = 90% CPU time/year = Data-events/year x CPU-data-time/event x Data passes = 3.9 x 10 10 CPU-s/year Reconstruction Cores = CPU-time/year/(year in seconds x Core efficiency) = 1387 cores Cooked data to tape = Data volume/year x Data passes x Output/input size = 5080 TByte/year

6 Thomas Jefferson National Accelerator Facility Page 6 CLAS12 Computing Requirements Reconstruction - 2 AssumptionsCPU-data-time/event = 155 ms Output/input size = 2 and Results:Data passes = 2 Fraction to disk = 10% Event size = 10 kBytes Events/year = 1.3 x 10 11 Data volume/year = 1.3 Pbytes/year Core efficiency = 90% Disk Storage = Cooked data to tape x Fraction to disk = 508 TByte Average bandwidth = Event size x (1 + Output/input size) x Cores/(CPU-data-time/event) = 268 Mbyte/s

7 Thomas Jefferson National Accelerator Facility Page 7 CLAS12 Computing Requirements Simulation -1 Assumptions: CPU-sim-time/event = 485 ms Events/year = 1.3 x 10 11 Electron fraction = 50% Simulated/data events = 10 Analyzed fraction = 50% Multiplicity = 1.5 Core efficiency = 90% Sim-events/year = Events/year x Electron fraction x Analyzed fraction x Simulated/data events = 3.2 x 10 11 CPU-sim-time/year = CPU-sim-time/event x Sim-events/year x Multiplicity = 2.3 x 10 11 CPU-s/year Simulation Cores = (CPU-sim-time/year)/(year in seconds x Core efficiency) = 8,139 cores

8 Thomas Jefferson National Accelerator Facility Page 8 CLAS12 Computing Requirements Simulation - 2 AssumptionsCPU-sim-time/event = 485 ms Fraction to disk = 2% and Results: Sim-events/year = 3.2x10 11 Fraction to tape = 10% Simulation Cores = 8,139 Multiplicity = 1.5 Output event size = 50 kBytes Work Disk = Sim-events/year x Output event size x Fraction to Disk = 318 TBytes Tape storage = Sim-events/year x Output event size x Fraction to Tape = 1,588 TBytes/year Average Bandwidth = (Output event size x Simulation cores)/CPU-sim-time/event = 839 MBytes/s

9 Thomas Jefferson National Accelerator Facility Page 9 CLAS12 Computing Requirements Reconstruction Studies Assumptions:CPU-data-time/event = 155 ms Fraction to disk = 5% Data passes = 10 Core efficiency = 90% CPU-time/year = Fraction to disk x Events/year x Data passes CPU-data-time/event = 3.4 x 10 10 s Cores = CPU-time/year/(year in seconds x Core efficiency) = 1,214 cores

10 Thomas Jefferson National Accelerator Facility Page 10 CLAS12 Computing Requirements Physics Analysis CPU-time/year = Fraction to disk x Events/year x Data passes x CPU-data-time/event = 1.7 x 10 10 CPU-s/year Cores = CPU-time/year/(year in seconds x Core efficiency) = 607 cores AssumptionsCPU-data-time/event-core = 8 msFraction of events = 50% Data passes = 10Core efficiency = 90%

11 Thomas Jefferson National Accelerator Facility Page 11 CLAS12 Computing Requirements Summary CoresDisk (TByte)Tape (TByte/yr) DAQ1,270 Calibration173 Reconstruction1,3875085,080 Simulation8,1393181,558 Reconstruction Studies1,214508 Physics Analysis607889 Sum11,5202,2237,938

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