SCT parametric simulation
From Charm-Tau Detector
(Difference between revisions)
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(→Particle gun) |
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=== Particle gun === | === Particle gun === | ||
| + | |||
| + | To use the particle gun algorithm, it is necessary to import the following libraries | ||
| + | <pre> | ||
| + | from Configurables import ParticleGun | ||
| + | from Configurables import GenAlg | ||
| + | from Configurables import HepMCToEDMConverter | ||
| + | from Configurables import HepMCFileWriter | ||
| + | |||
| + | from Configurables import Gaudi__ParticlePropertySvc | ||
| + | from PathResolver import PathResolver | ||
| + | </pre> | ||
| + | |||
| + | and to write the following strings | ||
| + | <pre> | ||
| + | particlePropertySvc = Gaudi__ParticlePropertySvc( | ||
| + | "ParticlePropertySvc", | ||
| + | ParticlePropertiesFile=PathResolver.FindDataFile('GenParticleData/ParticleTable.txt') | ||
| + | ) | ||
| + | |||
| + | from math import pi | ||
| + | guntool = ParticleGun("PdgCodes", PdgCodes=[211]) | ||
| + | guntool.OutputLevel=DEBUG | ||
| + | |||
| + | guntool.MomentumMin = 0 * units.MeV | ||
| + | guntool.MomentumMax = 4 * units.GeV | ||
| + | |||
| + | guntool.ThetaMin = 0 * units.rad | ||
| + | guntool.ThetaMax = pi * units.rad | ||
| + | |||
| + | guntool.PhiMin = 0 * units.rad | ||
| + | guntool.PhiMax = 2 * pi * units.rad | ||
| + | |||
| + | gun = GenAlg("ParticleGun", SignalProvider=guntool) | ||
| + | gun.hepmc.Path = "hepmc" | ||
| + | |||
| + | writer = HepMCFileWriter("HepMCFileWriter") | ||
| + | writer.hepmc.Path="hepmc" | ||
| + | |||
| + | hepmc_converter = HepMCToEDMConverter("Converter") | ||
| + | hepmc_converter.hepmc.Path="hepmc" | ||
| + | hepmc_converter.genparticles.Path="allGenParticles" | ||
| + | hepmc_converter.genvertices.Path="allGenVertices" | ||
| + | </pre> | ||
| + | |||
| + | Some parameters can be changed: | ||
| + | * PdgCodes - a list containing particles PDG codes to generate | ||
| + | * MomentumMin - a minimum particle momentum | ||
| + | * MomentumMax - a maximum particle momentum | ||
| + | * ThetaMin - a minimum theta angle | ||
| + | * ThetaMax - a maximum theta angle | ||
| + | * PhiMin - a minimum phi angle | ||
| + | * PhiMax - a maximum phi angle | ||
| + | |||
=== EvtGen === | === EvtGen === | ||
== SctParSim == | == SctParSim == | ||
== Analysis == | == Analysis == | ||
== Podio output == | == Podio output == | ||
Revision as of 12:54, 21 November 2021
Contents |
Configure example
There is an example of running the entire chain from generating particles to running an analysis tool. A more detailed description of the algorithms and their parameters is presented below.
from Configurables import ApplicationMgr
from Gaudi.Configuration import *
from Configurables import GenAlg, EvtGenInterface
from Configurables import HepMCToEDMConverter
from Configurables import ScTauDataSvc
from Configurables import PodioOutput
from Configurables import SctParSimAlg
from Configurables import EventLoader
from Configurables import NtupleAlg, NTupleSvc
from Configurables import ParticleCombinerAlg
from Configurables import Gaudi__ParticlePropertySvc
from PathResolver import PathResolver
ofile = 'sctparsim_out.root' # name of output file
eventNumber = 50000 # number of events
############################
#### Event generation ####
############################
podioevent = ScTauDataSvc("EventDataSvc")
# Particle service
particlePropertySvc = Gaudi__ParticlePropertySvc(
"ParticlePropertySvc",
ParticlePropertiesFile=PathResolver.FindDataFile('GenParticleData/ParticleTable.txt')
)
# EvtGen
evtgen = EvtGenInterface('SignalProvider')
#evtgen.userdec = "./mydec.dec"
#evtgen.rootParticle = "J/psi"
gen = GenAlg('EvtGenAlg', SignalProvider=evtgen)
gen.hepmc.Path = 'hepmc'
# HepMC3 to PODIO
edm = HepMCToEDMConverter("Converter")
edm.hepmc.Path=gen.hepmc.Path
edm.genparticles.Path="allGenParticles"
edm.genvertices.Path="allGenVertices"
############################
# SctParSim
############################
sct_alg = SctParSimAlg('SctAlg')
#sct_alg.CaloSystemTool.caloClSizeEGamma = 0.2 # Example how to change a subsystem parameter
############################
# Podio output
############################
out = PodioOutput('out', filename=ofile)
out.outputCommands = ["keep *"]
############################
# Analisis
############################
evlo = EventLoader('EvtLoader')
evlo.pcl.Path = 'Particles' # Branch (in the input ROOT-file) for reading
evlo.pListMap.Path = 'Lists1'
evlo.plists = [['gamma']] # Partilce list for further analisis
# Select particle combinations
cmbr = ParticleCombinerAlg('Cmbr',
decStr = 'pi0 -> gamma gamma', # Investigated decay
cutStr = 'E > 0.5', # Selection criteria
selfConj = True # if neutral particle True, else False
)
cmbr.pListMapI = evlo.pListMap.Path
cmbr.pListMapO.Path = 'Lists2'
# Select variables to save to n-tuple
tupl = NtupleAlg('piTuple')
tupl.listName = 'pi0'
tupl.fileName = 'scttuple/tup'
# List contains the particle parametes to write an output file
tupl.vars = [['px_mc', 'py_mc', 'pz_mc', 'E', 'pi0 -> ^gamma ^gamma'],
['M', ''],
]
tupl.pListMapI.Path = cmbr.pListMapO.Path
NTupleSvc(Output = ["scttuple DATAFILE='tup.root' OPT='NEW' TYP='ROOT'"])
options= {
'TopAlg' : [gen, edm, sct_alg, evlo, cmbr, tupl, out],
'EvtSel' : 'NONE',
'ExtSvc' : [particlePropertySvc, podioevent],
'EvtMax' : eventNumber,
'StatusCodeCheck' : True,
'AuditAlgorithms' : True,
'AuditTools' : True,
'AuditServices' : True,
'OutputLevel' : INFO,
'HistogramPersistency' : 'ROOT',
}
ApplicationMgr(**options)
Event generation
Podio input
It is possible to read the particle parameters from a ROOT file.
You have to import the library
from Configurables import PodioInput
and to create the algorithm instance
podioevent = ScTauDataSvc("EventDataSvc", input=ifile)
podioinput = PodioInput("PodioReader", OutputLevel=INFO, collections=['allGenParticles'])
The important parametres:
- input - an input file name
- collections - a name of a branch with MC particles
Particle gun
To use the particle gun algorithm, it is necessary to import the following libraries
from Configurables import ParticleGun from Configurables import GenAlg from Configurables import HepMCToEDMConverter from Configurables import HepMCFileWriter from Configurables import Gaudi__ParticlePropertySvc from PathResolver import PathResolver
and to write the following strings
particlePropertySvc = Gaudi__ParticlePropertySvc(
"ParticlePropertySvc",
ParticlePropertiesFile=PathResolver.FindDataFile('GenParticleData/ParticleTable.txt')
)
from math import pi
guntool = ParticleGun("PdgCodes", PdgCodes=[211])
guntool.OutputLevel=DEBUG
guntool.MomentumMin = 0 * units.MeV
guntool.MomentumMax = 4 * units.GeV
guntool.ThetaMin = 0 * units.rad
guntool.ThetaMax = pi * units.rad
guntool.PhiMin = 0 * units.rad
guntool.PhiMax = 2 * pi * units.rad
gun = GenAlg("ParticleGun", SignalProvider=guntool)
gun.hepmc.Path = "hepmc"
writer = HepMCFileWriter("HepMCFileWriter")
writer.hepmc.Path="hepmc"
hepmc_converter = HepMCToEDMConverter("Converter")
hepmc_converter.hepmc.Path="hepmc"
hepmc_converter.genparticles.Path="allGenParticles"
hepmc_converter.genvertices.Path="allGenVertices"
Some parameters can be changed:
- PdgCodes - a list containing particles PDG codes to generate
- MomentumMin - a minimum particle momentum
- MomentumMax - a maximum particle momentum
- ThetaMin - a minimum theta angle
- ThetaMax - a maximum theta angle
- PhiMin - a minimum phi angle
- PhiMax - a maximum phi angle
