Intro to CMS Physics Objects


  • Physics objects are the final abstraction in the detector that can be associated to physical entities like particles.
  • NanoAOD stores physics object properties as branches of a ROOT tree, linked by common name prefixes.

Electrons & Photons


  • Quantities such as impact parameters and charge have common member functions.
  • Physics objects in CMS are reconstructed from detector signals and are never 100% certain!
  • Identification and isolation algorithms are important for reducing fake objects.

Muons & Taus


  • Track access may differ, but track-related member functions are common across objects.
  • Physics objects in CMS are reconstructed from detector signals and are never 100% certain!
  • Muons typically use pre-configured identification and isolation variables”

Jets and MET


  • Jets are spatially-grouped collections of particles that traversed the CMS detector
  • Particles from additional proton-proton collisions (pileup) must be removed from jets
  • Missing transverse energy is the negative vector sum of particle candidates
  • Many of the variables discussed for other objects also exist for jets

Jet flavor tagging


  • Tagging algorithms separate heavy flavor jets from jets produced by the hadronization of light quarks and gluons
  • FatJet tagging algorithms can identify jets from massive SM particles
  • Tagging algorithms produce a disriminator value for each jet that represents the likelihood that the jet came from a particular particle
  • Each tagging algorithm has recommended ‘working points’ (discriminator values) based on a misidentification probability for non-interesting jets

Jet corrections


  • Jet energy corrections are factorized and account for many mismeasurement effects
  • L1+L2+L3 should be applied to jets used for analyses, with residual corrections for data
  • Jet energy resolution in simulation is typically too narrow and is smeared using scale factors
  • Jet energy and resolution corrections are sources of systematic error and uncertainties should be evaluated
  • In general, the jet corrections are significant and lower the momenta of the jets with standard LHC pileup conditions
  • For most jets, the JES uncertainty dominates over the JER uncertainty
  • In the endcap region of the detector, the JER uncertainty in larger and matches the JES uncertainty