Belle II Software  light-2403-persian
charmFlavorTagger.py
1 #!/usr/bin/env python3
2 
3 
10 
11 import basf2
12 import variables as va
13 import modularAnalysis as ma
14 
15 
16 def charmFlavorTagger(particle_list, uniqueIdentifier='CFT',
17  path=None):
18  """
19  Interfacing for the Charm Flavor Tagger.
20 
21  This function requires a reconstructed D meson signal particle list with a built RestOfEvent.
22 
23  :param particle_list: string, particle list of the reconstructed signal D meson
24  :param uniqueIdentifier: string, database identifier for the method
25  :param path: basf2 path obj
26  :return: None
27  """
28 
29  # create roe specific paths
30  roe_path = basf2.create_path()
31  dead_end_path = basf2.create_path()
32 
33  # define cft specific lists to enable multiple calls, if someone really wants to do that
34  extension = particle_list.replace(':', '_to_')
35  roe_particle_list_cut = 'isInRestOfEvent == 1 and dr < 1 and abs(dz) < 3'
36  roe_particle_list = 'pi+:cft' + '_' + extension
37 
38  # filter rest of events only for specific particle list
39  ma.signalSideParticleFilter(particle_list, '', roe_path, dead_end_path)
40 
41  # create final state particle lists
42  ma.fillParticleList(roe_particle_list, roe_particle_list_cut, path=roe_path)
43 
44  # compute ranking variable and additional CFT input variables, PID_diff=pionID-kaonID, deltaR=sqrt(deltaPhi**2+deltaEta**2)
45  rank_variable = 'opang_shift'
46  va.variables.addAlias(rank_variable, f"abs(formula(angleToClosestInList({particle_list}) - 3.14159265359/2))")
47  va.variables.addAlias("eta", "formula(-1*log(tan(formula(theta/2))))")
48  va.variables.addAlias("phi_sig", "particleRelatedToCurrentROE(phi)")
49  va.variables.addAlias("eta_sig", "particleRelatedToCurrentROE(eta)")
50  va.variables.addAlias("deltaPhi_temp", "abs(formula(phi-phi_sig))")
51  va.variables.addAlias(
52  "deltaPhi",
53  "conditionalVariableSelector(deltaPhi_temp>3.14159265359,formula(deltaPhi_temp-2*3.14159265359),deltaPhi_temp)")
54  va.variables.addAlias("deltaR", "formula(((deltaPhi)**2+(eta-eta_sig)**2)**0.5)")
55  va.variables.addAlias("PID_diff", "formula(pionID-kaonID)")
56 
57  # split tracks by charge, rank them (keep only the three highest ranking) and write CFT input to extraInfo of signal particle
58  var_list = ['mRecoil', 'PID_diff', 'deltaR']
59  cft_particle_dict = {'pi+:pos_charge': ['charge > 0 and p < infinity', 'p'],
60  'pi+:neg_charge': ['charge < 0 and p < infinity', 'n']}
61 
62  for listName, config in cft_particle_dict.items():
63  ma.cutAndCopyList(listName, roe_particle_list, config[0], writeOut=True, path=roe_path)
64  ma.rankByHighest(listName, rank_variable, numBest=3, path=roe_path)
65  roe_dict = {}
66  suffix = config[1]
67  for var in var_list:
68  for i_num in range(1, 3 + 1):
69  roe_dict[f'eventCached(getVariableByRank({listName}, {rank_variable}, {var}, {i_num}))'] = (
70  f'pi_{i_num}_{suffix}_{var}')
71  va.variables.addAlias(f'pi_{i_num}_{suffix}_{var}', f'extraInfo(pi_{i_num}_{suffix}_{var})')
72 
73  ma.variableToSignalSideExtraInfo(listName, roe_dict, path=roe_path)
74 
75  # apply CFT with MVAExpert module and write output to extraInfo
76  expert_module = basf2.register_module('MVAExpert')
77  expert_module.param('listNames', [particle_list])
78  expert_module.param('identifier', uniqueIdentifier)
79 
80  expert_module.param('extraInfoName', 'CFT_out')
81 
82  roe_path.add_module(expert_module)
83 
84  # The CFT output probability should be 0.5 when no track is reconstructed in the ROE
85  va.variables.addAlias(
86  'CFT_prob',
87  'conditionalVariableSelector(isNAN(pi_1_p_deltaR) and isNAN(pi_1_n_deltaR),0.5,formula(1-extraInfo(CFT_out)))')
88  va.variables.addAlias('CFT_qr', 'formula(2*CFT_prob-1)')
89 
90  path.for_each('RestOfEvent', 'RestOfEvents', roe_path)