Rivet analyses
Measurement of R between 3.888 and 4.586 GeV
Experiment: MARKI (Spear)
Inspire ID: 108144
Status: VALIDATED
Authors: - Peter Richardson
References: - Phys.Rev.Lett. 36 (1976) 700, 1976
Beams: e- e+
Beam energies: (1.9, 1.9); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.3, 2.3); (1.9, 1.9); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.0, 2.0); (2.1, 2.1); (2.1, 2.1); (2.1, 2.1); (2.1, 2.1); (2.1, 2.1); (2.1, 2.1); (2.1, 2.1); (2.1, 2.1); (2.1, 2.1); (2.1, 2.1); (2.1, 2.1); (2.1, 2.1); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.2, 2.2); (2.3, 2.3); (2.3, 2.3)GeV
Run details: - e+ e- to hadrons and e+ e- to mu+ mu- (for normalization)
Measurement of R in e+e− collisions by MARKI for energies between 3.888 and 4.586 GeV. The individual hadronic and muonic cross sections are also outputted to the yoda file so that ratio R can be recalcuated if runs are combined.
Source
code:MARKI_1976_I108144.cc
// -*- C++ -*-
#include "Rivet/Analysis.hh"
#include "Rivet/Projections/FinalState.hh"
namespace Rivet {
/// @brief R measurement
class MARKI_1976_I108144 : public Analysis {
public:
/// Constructor
RIVET_DEFAULT_ANALYSIS_CTOR(MARKI_1976_I108144);
/// @name Analysis methods
/// @{
/// Book histograms and initialise projections before the run
void init() {
// Initialise and register projections
declare(FinalState(), "FS");
// Book histograms
book(_c_hadrons, "/TMP/sigma_hadrons", refData<YODA::BinnedEstimate<string>>(1,1,1));
book(_c_muons, "/TMP/sigma_muons" , refData<YODA::BinnedEstimate<string>>(1,1,1));
for (const string& en : _c_hadrons.binning().edges<0>()) {
double eval = stod(en)*GeV;
if (isCompatibleWithSqrtS(eval)) {
_sqs = en; break;
}
}
raiseBeamErrorIf(_sqs.empty());
}
/// Perform the per-event analysis
void analyze(const Event& event) {
const FinalState& fs = apply<FinalState>(event, "FS");
map<long,int> nCount;
int ntotal(0);
for (const Particle& p : fs.particles()) {
nCount[p.pid()] += 1;
++ntotal;
}
if (nCount[-13]==1 && nCount[13]==1 && ntotal==2+nCount[22]) {
// mu+mu- + photons
_c_muons->fill(_sqs);
}
else _c_hadrons->fill(_sqs); // everything else
}
/// Normalise histograms etc., after the run
void finalize() {
BinnedEstimatePtr<string> mult;
book(mult, 1, 1, 1);
divide(_c_hadrons, _c_muons, mult);
}
/// @}
/// @name Histograms
/// @{
BinnedHistoPtr<string> _c_hadrons, _c_muons;
string _sqs = "";
/// @}
};
RIVET_DECLARE_PLUGIN(MARKI_1976_I108144);
}