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#include <MuonResiduals5DOFFitter.h>
Public Types | |
| enum | { kAlignX = 0, kAlignZ, kAlignPhiX, kAlignPhiY, kAlignPhiZ, kResidSigma, kResSlopeSigma, kAlpha, kResidGamma, kResSlopeGamma, kNPar } |
| enum | { kResid = 0, kResSlope, kPositionX, kPositionY, kAngleX, kAngleY, kRedChi2, kPz, kPt, kCharge, kNData } |
Public Member Functions | |
| void | correctBField () |
| bool | fit (Alignable *ali) |
| MuonResiduals5DOFFitter (int residualsModel, int minHits, int useResiduals, bool weightAlignment=true) | |
| int | ndata () |
| int | npar () |
| double | plot (std::string name, TFileDirectory *dir, Alignable *ali) |
| TTree * | readNtuple (std::string fname, unsigned int wheel, unsigned int station, unsigned int sector, unsigned int preselected=1) |
| double | sumofweights () |
| int | type () const |
| virtual | ~MuonResiduals5DOFFitter () |
Protected Member Functions | |
| void | inform (TMinuit *tMinuit) |
$Date: Fri Apr 17 15:29:54 CDT 2009
Definition at line 18 of file MuonResiduals5DOFFitter.h.
| anonymous enum |
| kAlignX | |
| kAlignZ | |
| kAlignPhiX | |
| kAlignPhiY | |
| kAlignPhiZ | |
| kResidSigma | |
| kResSlopeSigma | |
| kAlpha | |
| kResidGamma | |
| kResSlopeGamma | |
| kNPar |
Definition at line 21 of file MuonResiduals5DOFFitter.h.
{
kAlignX = 0,
kAlignZ,
kAlignPhiX,
kAlignPhiY,
kAlignPhiZ,
kResidSigma,
kResSlopeSigma,
kAlpha,
kResidGamma,
kResSlopeGamma,
kNPar
};
| anonymous enum |
Definition at line 35 of file MuonResiduals5DOFFitter.h.
| MuonResiduals5DOFFitter::MuonResiduals5DOFFitter | ( | int | residualsModel, |
| int | minHits, | ||
| int | useResiduals, | ||
| bool | weightAlignment = true |
||
| ) | [inline] |
Definition at line 49 of file MuonResiduals5DOFFitter.h.
: MuonResidualsFitter(residualsModel, minHits, useResiduals, weightAlignment) {}
| virtual MuonResiduals5DOFFitter::~MuonResiduals5DOFFitter | ( | ) | [inline, virtual] |
Definition at line 50 of file MuonResiduals5DOFFitter.h.
{}
| void MuonResiduals5DOFFitter::correctBField | ( | ) | [virtual] |
Implements MuonResidualsFitter.
Definition at line 135 of file MuonResiduals5DOFFitter.cc.
| bool MuonResiduals5DOFFitter::fit | ( | Alignable * | ali | ) | [virtual] |
Implements MuonResidualsFitter.
Definition at line 169 of file MuonResiduals5DOFFitter.cc.
References MuonResidualsFitter::dofit(), MuonResidualsFitter::fix(), i, UserOptions_cff::idx, MuonResidualsFitter::initialize_table(), MuonResidualsFitter::k0010, MuonResidualsFitter::k1010, MuonResidualsFitter::k1100, MuonResidualsFitter::k1110, MuonResidualsFitter::k1111, kAlignPhiX, kAlignPhiY, kAlignPhiZ, kAlignX, kAlignZ, kAlpha, MuonResidualsFitter::kPowerLawTails, MuonResidualsFitter::kPureGaussian2D, kResidGamma, kResidSigma, kResSlopeGamma, kResSlopeSigma, MuonResidualsFitter::kROOTVoigt, MuonResiduals5DOFFitter_FCN(), mergeVDriftHistosByStation::name, h::names, MuonResidualsFitter::residualsModel(), dqm_diff::start, launcher::step, relval_steps::steps, sumofweights(), and MuonResidualsFitter::useRes().
{
initialize_table(); // if not already initialized
sumofweights();
double res_std = 0.5;
double resslope_std = 0.005;
int nums[10] = {kAlignX, kAlignZ, kAlignPhiX, kAlignPhiY, kAlignPhiZ, kResidSigma, kResSlopeSigma, kAlpha, kResidGamma, kResSlopeGamma};
std::string names[10] = {"AlignX","AlignZ","AlignPhiX","AlignPhiY","AlignPhiZ", "ResidSigma","ResSlopeSigma", "Alpha", "ResidGamma","ResSlopeGamma"};
double starts[10] = {0., 0., 0., 0., 0., res_std, resslope_std, 0., 0.1*res_std, 0.1*resslope_std};
double steps[10] = {0.1, 0.1, 0.001, 0.001, 0.001, 0.001*res_std, 0.001*resslope_std, 0.001, 0.01*res_std, 0.01*resslope_std};
double lows[10] = {0., 0., 0., 0., 0., 0., 0., -1., 0., 0.};
double highs[10] = {0., 0., 0., 0., 0., 10., 0.1, 1., 0., 0.};
std::vector<int> num(nums, nums+5);
std::vector<std::string> name(names, names+5);
std::vector<double> start(starts, starts+5);
std::vector<double> step(steps, steps+5);
std::vector<double> low(lows, lows+5);
std::vector<double> high(highs, highs+5);
bool add_alpha = ( residualsModel() == kPureGaussian2D);
bool add_gamma = ( residualsModel() == kROOTVoigt || residualsModel() == kPowerLawTails);
int idx[4], ni = 0;
if (useRes() == k1111 || useRes() == k1110 || useRes() == k1010) {
for(ni=0; ni<2; ni++) idx[ni] = ni+5;
if (add_alpha) idx[ni++] = 7;
else if (add_gamma) for(; ni<4; ni++) idx[ni] = ni+6;
if (!add_alpha) fix(kAlpha);
}
else if (useRes() == k1100) {
idx[ni++] = 5;
if (add_gamma) idx[ni++] = 8;
fix(kResSlopeSigma);
fix(kAlpha);
}
else if (useRes() == k0010) {
idx[ni++] = 6;
if (add_gamma) idx[ni++] = 9;
fix(kResidSigma);
fix(kAlpha);
}
for (int i=0; i<ni; i++){
num.push_back(nums[idx[i]]);
name.push_back(names[idx[i]]);
start.push_back(starts[idx[i]]);
step.push_back(steps[idx[i]]);
low.push_back(lows[idx[i]]);
high.push_back(highs[idx[i]]);
}
return dofit(&MuonResiduals5DOFFitter_FCN, num, name, start, step, low, high);
}
| void MuonResiduals5DOFFitter::inform | ( | TMinuit * | tMinuit | ) | [protected, virtual] |
Implements MuonResidualsFitter.
Definition at line 141 of file MuonResiduals5DOFFitter.cc.
{
minuit = tMinuit;
}
| int MuonResiduals5DOFFitter::ndata | ( | ) | [inline, virtual] |
Implements MuonResidualsFitter.
Definition at line 60 of file MuonResiduals5DOFFitter.h.
References kNData.
{ return kNData; }
| int MuonResiduals5DOFFitter::npar | ( | ) | [inline, virtual] |
Implements MuonResidualsFitter.
Definition at line 54 of file MuonResiduals5DOFFitter.h.
References MuonResidualsFitter::kGaussPowerTails, kNPar, MuonResidualsFitter::kPowerLawTails, MuonResidualsFitter::kPureGaussian, MuonResidualsFitter::kPureGaussian2D, MuonResidualsFitter::kROOTVoigt, and MuonResidualsFitter::residualsModel().
Referenced by plot().
{
if (residualsModel() == kPureGaussian || residualsModel() == kPureGaussian2D || residualsModel() == kGaussPowerTails) return kNPar - 2;
else if (residualsModel() == kPowerLawTails) return kNPar;
else if (residualsModel() == kROOTVoigt) return kNPar;
else assert(false);
}
| double MuonResiduals5DOFFitter::plot | ( | std::string | name, |
| TFileDirectory * | dir, | ||
| Alignable * | ali | ||
| ) | [virtual] |
Implements MuonResidualsFitter.
Definition at line 226 of file MuonResiduals5DOFFitter.cc.
References a, b, MuonResidualsFitter::errorerror(), i, kAlignPhiX, kAlignPhiY, kAlignPhiZ, kAlignX, kAlignZ, kAlpha, kAngleX, kAngleY, MuonResidualsFitter::kGaussPowerTails, kPositionX, kPositionY, MuonResidualsFitter::kPowerLawTails, MuonResidualsFitter::kPureGaussian, MuonResidualsFitter::kPureGaussian2D, kRedChi2, kResid, kResidGamma, kResidSigma, kResSlope, kResSlopeGamma, kResSlopeSigma, MuonResidualsFitter::kROOTVoigt, AlignableSurface::length(), MuonResidualsFitter::m_weightAlignment, TFileDirectory::make(), MuonResidualsFitter_GaussPowerTails_TF1(), MuonResidualsFitter_powerLawTails_TF1(), MuonResidualsFitter_pureGaussian_TF1(), MuonResidualsFitter_ROOTVoigt_TF1(), npar(), NULL, funct::pow(), alignCSCRings::r, MuonResidualsFitter::residuals_begin(), MuonResidualsFitter::residuals_end(), MuonResidualsFitter::residualsModel(), sumofweights(), Alignable::surface(), MuonResidualsFitter::value(), CommonMethods::weight(), AlignableSurface::width(), and tablePrinter::width.
{
sumofweights();
double mean_residual = 0., mean_resslope = 0.;
double mean_trackx = 0., mean_tracky = 0., mean_trackdxdz = 0., mean_trackdydz = 0.;
double sum_w = 0.;
for (std::vector<double*>::const_iterator rit = residuals_begin(); rit != residuals_end(); ++rit)
{
const double redchi2 = (*rit)[kRedChi2];
double weight = 1./redchi2;
if (!m_weightAlignment) weight = 1.;
if (!m_weightAlignment || TMath::Prob(redchi2*6, 6) < 0.99) // no spikes allowed
{
double factor_w = 1./(sum_w + weight);
mean_residual = factor_w * (sum_w * mean_residual + weight * (*rit)[kResid]);
mean_resslope = factor_w * (sum_w * mean_resslope + weight * (*rit)[kResSlope]);
mean_trackx = factor_w * (sum_w * mean_trackx + weight * (*rit)[kPositionX]);
mean_tracky = factor_w * (sum_w * mean_tracky + weight * (*rit)[kPositionY]);
mean_trackdxdz = factor_w * (sum_w * mean_trackdxdz + weight * (*rit)[kAngleX]);
mean_trackdydz = factor_w * (sum_w * mean_trackdydz + weight * (*rit)[kAngleY]);
sum_w += weight;
}
}
std::string name_residual, name_resslope, name_residual_raw, name_resslope_raw, name_residual_cut, name_alpha;
std::string name_residual_trackx, name_resslope_trackx;
std::string name_residual_tracky, name_resslope_tracky;
std::string name_residual_trackdxdz, name_resslope_trackdxdz;
std::string name_residual_trackdydz, name_resslope_trackdydz;
name_residual = name + "_residual";
name_resslope = name + "_resslope";
name_residual_raw = name + "_residual_raw";
name_resslope_raw = name + "_resslope_raw";
name_residual_cut = name + "_residual_cut";
name_alpha = name + "_alpha";
name_residual_trackx = name + "_residual_trackx";
name_resslope_trackx = name + "_resslope_trackx";
name_residual_tracky = name + "_residual_tracky";
name_resslope_tracky = name + "_resslope_tracky";
name_residual_trackdxdz = name + "_residual_trackdxdz";
name_resslope_trackdxdz = name + "_resslope_trackdxdz";
name_residual_trackdydz = name + "_residual_trackdydz";
name_resslope_trackdydz = name + "_resslope_trackdydz";
double width = ali->surface().width();
double length = ali->surface().length();
int bins_residual = 150, bins_resslope = 100;
double min_residual = -75., max_residual = 75.;
double min_resslope = -50., max_resslope = 50.;
double min_trackx = -width/2., max_trackx = width/2.;
double min_tracky = -length/2., max_tracky = length/2.;
double min_trackdxdz = -1.5, max_trackdxdz = 1.5;
double min_trackdydz = -1.5, max_trackdydz = 1.5;
TH1F *hist_residual = dir->make<TH1F>(name_residual.c_str(), "", bins_residual, min_residual, max_residual);
TH1F *hist_resslope = dir->make<TH1F>(name_resslope.c_str(), "", bins_resslope, min_resslope, max_resslope);
TH1F *hist_residual_raw = dir->make<TH1F>(name_residual_raw.c_str(), "", bins_residual, min_residual, max_residual);
TH1F *hist_resslope_raw = dir->make<TH1F>(name_resslope_raw.c_str(), "", bins_resslope, min_resslope, max_resslope);
TH1F *hist_residual_cut = dir->make<TH1F>(name_residual_cut.c_str(), "", bins_residual, min_residual, max_residual);
TH2F *hist_alpha = dir->make<TH2F>(name_alpha.c_str(), "", 50, min_resslope, max_resslope, 50, -50., 50.);
TProfile *hist_residual_trackx = dir->make<TProfile>(name_residual_trackx.c_str(), "", 50, min_trackx, max_trackx, min_residual, max_residual);
TProfile *hist_resslope_trackx = dir->make<TProfile>(name_resslope_trackx.c_str(), "", 50, min_trackx, max_trackx, min_resslope, max_resslope);
TProfile *hist_residual_tracky = dir->make<TProfile>(name_residual_tracky.c_str(), "", 50, min_tracky, max_tracky, min_residual, max_residual);
TProfile *hist_resslope_tracky = dir->make<TProfile>(name_resslope_tracky.c_str(), "", 50, min_tracky, max_tracky, min_resslope, max_resslope);
TProfile *hist_residual_trackdxdz = dir->make<TProfile>(name_residual_trackdxdz.c_str(), "", 250, min_trackdxdz, max_trackdxdz, min_residual, max_residual);
TProfile *hist_resslope_trackdxdz = dir->make<TProfile>(name_resslope_trackdxdz.c_str(), "", 250, min_trackdxdz, max_trackdxdz, min_resslope, max_resslope);
TProfile *hist_residual_trackdydz = dir->make<TProfile>(name_residual_trackdydz.c_str(), "", 250, min_trackdydz, max_trackdydz, min_residual, max_residual);
TProfile *hist_resslope_trackdydz = dir->make<TProfile>(name_resslope_trackdydz.c_str(), "", 250, min_trackdydz, max_trackdydz, min_resslope, max_resslope);
hist_residual_trackx->SetAxisRange(-10., 10., "Y");
hist_resslope_trackx->SetAxisRange(-10., 10., "Y");
hist_residual_tracky->SetAxisRange(-10., 10., "Y");
hist_resslope_tracky->SetAxisRange(-10., 10., "Y");
hist_residual_trackdxdz->SetAxisRange(-10., 10., "Y");
hist_resslope_trackdxdz->SetAxisRange(-10., 10., "Y");
hist_residual_trackdydz->SetAxisRange(-10., 10., "Y");
hist_resslope_trackdydz->SetAxisRange(-10., 10., "Y");
name_residual += "_fit";
name_resslope += "_fit";
name_alpha += "_fit";
name_residual_trackx += "_fit";
name_resslope_trackx += "_fit";
name_residual_tracky += "_fit";
name_resslope_tracky += "_fit";
name_residual_trackdxdz += "_fit";
name_resslope_trackdxdz += "_fit";
name_residual_trackdydz += "_fit";
name_resslope_trackdydz += "_fit";
TF1 *fit_residual = NULL;
TF1 *fit_resslope = NULL;
if (residualsModel() == kPureGaussian || residualsModel() == kPureGaussian2D) {
fit_residual = new TF1(name_residual.c_str(), MuonResidualsFitter_pureGaussian_TF1, min_residual, max_residual, 3);
fit_residual->SetParameters(sum_of_weights * (max_residual - min_residual)/bins_residual, 10.*value(kAlignX), 10.*value(kResidSigma));
const double er_res[3] = {0., 10.*errorerror(kAlignX), 10.*errorerror(kResidSigma)};
fit_residual->SetParErrors(er_res);
fit_resslope = new TF1(name_resslope.c_str(), MuonResidualsFitter_pureGaussian_TF1, min_resslope, max_resslope, 3);
fit_resslope->SetParameters(sum_of_weights * (max_resslope - min_resslope)/bins_resslope, 1000.*value(kAlignPhiY), 1000.*value(kResSlopeSigma));
const double er_resslope[3] = {0., 1000.*errorerror(kAlignPhiY), 1000.*errorerror(kResSlopeSigma)};
fit_resslope->SetParErrors(er_resslope);
}
else if (residualsModel() == kPowerLawTails) {
fit_residual = new TF1(name_residual.c_str(), MuonResidualsFitter_powerLawTails_TF1, min_residual, max_residual, 4);
fit_residual->SetParameters(sum_of_weights * (max_residual - min_residual)/bins_residual, 10.*value(kAlignX), 10.*value(kResidSigma), 10.*value(kResidGamma));
fit_resslope = new TF1(name_resslope.c_str(), MuonResidualsFitter_powerLawTails_TF1, min_resslope, max_resslope, 4);
fit_resslope->SetParameters(sum_of_weights * (max_resslope - min_resslope)/bins_resslope, 1000.*value(kAlignPhiY), 1000.*value(kResSlopeSigma), 1000.*value(kResSlopeGamma));
}
else if (residualsModel() == kROOTVoigt) {
fit_residual = new TF1(name_residual.c_str(), MuonResidualsFitter_ROOTVoigt_TF1, min_residual, max_residual, 4);
fit_residual->SetParameters(sum_of_weights * (max_residual - min_residual)/bins_residual, 10.*value(kAlignX), 10.*value(kResidSigma), 10.*value(kResidGamma));
fit_resslope = new TF1(name_resslope.c_str(), MuonResidualsFitter_ROOTVoigt_TF1, min_resslope, max_resslope, 4);
fit_resslope->SetParameters(sum_of_weights * (max_resslope - min_resslope)/bins_resslope, 1000.*value(kAlignPhiY), 1000.*value(kResSlopeSigma), 1000.*value(kResSlopeGamma));
}
else if (residualsModel() == kGaussPowerTails) {
fit_residual = new TF1(name_residual.c_str(), MuonResidualsFitter_GaussPowerTails_TF1, min_residual, max_residual, 3);
fit_residual->SetParameters(sum_of_weights * (max_residual - min_residual)/bins_residual, 10.*value(kAlignX), 10.*value(kResidSigma));
fit_resslope = new TF1(name_resslope.c_str(), MuonResidualsFitter_GaussPowerTails_TF1, min_resslope, max_resslope, 3);
fit_resslope->SetParameters(sum_of_weights * (max_resslope - min_resslope)/bins_resslope, 1000.*value(kAlignPhiY), 1000.*value(kResSlopeSigma));
}
else { assert(false); }
fit_residual->SetLineColor(2); fit_residual->SetLineWidth(2); fit_residual->Write();
fit_resslope->SetLineColor(2); fit_resslope->SetLineWidth(2); fit_resslope->Write();
TF1 *fit_alpha = new TF1(name_alpha.c_str(), "[0] + x*[1]", min_resslope, max_resslope);
double a = 10.*value(kAlignX), b = 10.*value(kAlpha)/1000.;
if (residualsModel() == kPureGaussian2D)
{
double sx = 10.*value(kResidSigma), sy = 1000.*value(kResSlopeSigma), r = value(kAlpha);
a = mean_residual;
b = 0.;
if ( sx != 0. )
{
b = 1./(sy/sx*r);
a = - b * mean_resslope;
}
}
fit_alpha->SetParameters(a, b);
fit_alpha->SetLineColor(2); fit_alpha->SetLineWidth(2); fit_alpha->Write();
TProfile *fit_residual_trackx = dir->make<TProfile>(name_residual_trackx.c_str(), "", 50, min_trackx, max_trackx);
TProfile *fit_resslope_trackx = dir->make<TProfile>(name_resslope_trackx.c_str(), "", 50, min_trackx, max_trackx);
TProfile *fit_residual_tracky = dir->make<TProfile>(name_residual_tracky.c_str(), "", 50, min_tracky, max_tracky);
TProfile *fit_resslope_tracky = dir->make<TProfile>(name_resslope_tracky.c_str(), "", 50, min_tracky, max_tracky);
TProfile *fit_residual_trackdxdz = dir->make<TProfile>(name_residual_trackdxdz.c_str(), "", 250, min_trackdxdz, max_trackdxdz);
TProfile *fit_resslope_trackdxdz = dir->make<TProfile>(name_resslope_trackdxdz.c_str(), "", 250, min_trackdxdz, max_trackdxdz);
TProfile *fit_residual_trackdydz = dir->make<TProfile>(name_residual_trackdydz.c_str(), "", 250, min_trackdydz, max_trackdydz);
TProfile *fit_resslope_trackdydz = dir->make<TProfile>(name_resslope_trackdydz.c_str(), "", 250, min_trackdydz, max_trackdydz);
fit_residual_trackx->SetLineColor(2); fit_residual_trackx->SetLineWidth(2);
fit_resslope_trackx->SetLineColor(2); fit_resslope_trackx->SetLineWidth(2);
fit_residual_tracky->SetLineColor(2); fit_residual_tracky->SetLineWidth(2);
fit_resslope_tracky->SetLineColor(2); fit_resslope_tracky->SetLineWidth(2);
fit_residual_trackdxdz->SetLineColor(2); fit_residual_trackdxdz->SetLineWidth(2);
fit_resslope_trackdxdz->SetLineColor(2); fit_resslope_trackdxdz->SetLineWidth(2);
fit_residual_trackdydz->SetLineColor(2); fit_residual_trackdydz->SetLineWidth(2);
fit_resslope_trackdydz->SetLineColor(2); fit_resslope_trackdydz->SetLineWidth(2);
name_residual_trackx += "line";
name_resslope_trackx += "line";
name_residual_tracky += "line";
name_resslope_tracky += "line";
name_residual_trackdxdz += "line";
name_resslope_trackdxdz += "line";
name_residual_trackdydz += "line";
name_resslope_trackdydz += "line";
TF1 *fitline_residual_trackx = new TF1(name_residual_trackx.c_str(), residual_x_trackx_TF1, min_trackx, max_trackx, 12);
TF1 *fitline_resslope_trackx = new TF1(name_resslope_trackx.c_str(), residual_dxdz_trackx_TF1, min_trackx, max_trackx, 12);
TF1 *fitline_residual_tracky = new TF1(name_residual_tracky.c_str(), residual_x_tracky_TF1, min_tracky, max_tracky, 12);
TF1 *fitline_resslope_tracky = new TF1(name_resslope_tracky.c_str(), residual_dxdz_tracky_TF1, min_tracky, max_tracky, 12);
TF1 *fitline_residual_trackdxdz = new TF1(name_residual_trackdxdz.c_str(), residual_x_trackdxdz_TF1, min_trackdxdz, max_trackdxdz, 12);
TF1 *fitline_resslope_trackdxdz = new TF1(name_resslope_trackdxdz.c_str(), residual_dxdz_trackdxdz_TF1, min_trackdxdz, max_trackdxdz, 12);
TF1 *fitline_residual_trackdydz = new TF1(name_residual_trackdydz.c_str(), residual_x_trackdydz_TF1, min_trackdydz, max_trackdydz, 12);
TF1 *fitline_resslope_trackdydz = new TF1(name_resslope_trackdydz.c_str(), residual_dxdz_trackdydz_TF1, min_trackdydz, max_trackdydz, 12);
std::vector<TF1*> fitlines;
fitlines.push_back(fitline_residual_trackx);
fitlines.push_back(fitline_resslope_trackx);
fitlines.push_back(fitline_residual_tracky);
fitlines.push_back(fitline_resslope_tracky);
fitlines.push_back(fitline_residual_trackdxdz);
fitlines.push_back(fitline_resslope_trackdxdz);
fitlines.push_back(fitline_residual_trackdydz);
fitlines.push_back(fitline_resslope_trackdydz);
double fitparameters[12] = {value(kAlignX), 0., value(kAlignZ), value(kAlignPhiX), value(kAlignPhiY), value(kAlignPhiZ),
mean_trackx, mean_tracky, mean_trackdxdz, mean_trackdydz, value(kAlpha), mean_resslope};
if (residualsModel() == kPureGaussian2D) fitparameters[10] = 0.;
for(std::vector<TF1*>::const_iterator itr = fitlines.begin(); itr != fitlines.end(); itr++)
{
(*itr)->SetParameters(fitparameters);
(*itr)->SetLineColor(2);
(*itr)->SetLineWidth(2);
(*itr)->Write();
}
for (std::vector<double*>::const_iterator resiter = residuals_begin(); resiter != residuals_end(); ++resiter) {
const double resid = (*resiter)[kResid];
const double resslope = (*resiter)[kResSlope];
const double positionX = (*resiter)[kPositionX];
const double positionY = (*resiter)[kPositionY];
const double angleX = (*resiter)[kAngleX];
const double angleY = (*resiter)[kAngleY];
const double redchi2 = (*resiter)[kRedChi2];
double weight = 1./redchi2;
if (!m_weightAlignment) weight = 1.;
if (!m_weightAlignment || TMath::Prob(redchi2*8, 8) < 0.99) { // no spikes allowed
hist_alpha->Fill(1000.*resslope, 10.*resid);
double coeff = value(kAlpha);
if (residualsModel() == kPureGaussian || residualsModel() == kPureGaussian2D) coeff = 0.;
double geom_resid = residual_x(value(kAlignX), value(kAlignZ), value(kAlignPhiX), value(kAlignPhiY), value(kAlignPhiZ), positionX, positionY, angleX, angleY, coeff, resslope);
hist_residual->Fill(10.*(resid - geom_resid + value(kAlignX)), weight);
hist_residual_trackx->Fill(positionX, 10.*resid, weight);
hist_residual_tracky->Fill(positionY, 10.*resid, weight);
hist_residual_trackdxdz->Fill(angleX, 10.*resid, weight);
hist_residual_trackdydz->Fill(angleY, 10.*resid, weight);
fit_residual_trackx->Fill(positionX, 10.*geom_resid, weight);
fit_residual_tracky->Fill(positionY, 10.*geom_resid, weight);
fit_residual_trackdxdz->Fill(angleX, 10.*geom_resid, weight);
fit_residual_trackdydz->Fill(angleY, 10.*geom_resid, weight);
double geom_resslope = residual_dxdz(value(kAlignX), value(kAlignZ), value(kAlignPhiX), value(kAlignPhiY), value(kAlignPhiZ), positionX, positionY, angleX, angleY);
hist_resslope->Fill(1000.*(resslope - geom_resslope + value(kAlignPhiY)), weight);
hist_resslope_trackx->Fill(positionX, 1000.*resslope, weight);
hist_resslope_tracky->Fill(positionY, 1000.*resslope, weight);
hist_resslope_trackdxdz->Fill(angleX, 1000.*resslope, weight);
hist_resslope_trackdydz->Fill(angleY, 1000.*resslope, weight);
fit_resslope_trackx->Fill(positionX, 1000.*geom_resslope, weight);
fit_resslope_tracky->Fill(positionY, 1000.*geom_resslope, weight);
fit_resslope_trackdxdz->Fill(angleX, 1000.*geom_resslope, weight);
fit_resslope_trackdydz->Fill(angleY, 1000.*geom_resslope, weight);
}
hist_residual_raw->Fill(10.*resid);
hist_resslope_raw->Fill(1000.*resslope);
if (fabs(resslope) < 0.005) hist_residual_cut->Fill(10.*resid);
}
double chi2 = 0.;
double ndof = 0.;
for (int i = 1; i <= hist_residual->GetNbinsX(); i++) {
double xi = hist_residual->GetBinCenter(i);
double yi = hist_residual->GetBinContent(i);
double yerri = hist_residual->GetBinError(i);
double yth = fit_residual->Eval(xi);
if (yerri > 0.) {
chi2 += pow((yth - yi)/yerri, 2);
ndof += 1.;
}
}
for (int i = 1; i <= hist_resslope->GetNbinsX(); i++) {
double xi = hist_resslope->GetBinCenter(i);
double yi = hist_resslope->GetBinContent(i);
double yerri = hist_resslope->GetBinError(i);
double yth = fit_resslope->Eval(xi);
if (yerri > 0.) {
chi2 += pow((yth - yi)/yerri, 2);
ndof += 1.;
}
}
ndof -= npar();
return (ndof > 0. ? chi2 / ndof : -1.);
}
| TTree * MuonResiduals5DOFFitter::readNtuple | ( | std::string | fname, |
| unsigned int | wheel, | ||
| unsigned int | station, | ||
| unsigned int | sector, | ||
| unsigned int | preselected = 1 |
||
| ) |
Definition at line 502 of file MuonResiduals5DOFFitter.cc.
References MuonResidualsFitter::MuonAlignmentTreeRow::angle_x, MuonResidualsFitter::MuonAlignmentTreeRow::angle_y, f, MuonResidualsFitter::fill(), i, kAngleX, kAngleY, kCharge, kNData, kPositionX, kPositionY, kPt, kPz, kRedChi2, kResid, kResSlope, MuonResidualsFitter::MuonAlignmentTreeRow::pos_x, MuonResidualsFitter::MuonAlignmentTreeRow::pos_y, MuonResidualsFitter::MuonAlignmentTreeRow::pt, MuonResidualsFitter::MuonAlignmentTreeRow::pz, MuonResidualsFitter::MuonAlignmentTreeRow::q, alignCSCRings::r, MuonResidualsFitter::MuonAlignmentTreeRow::res_slope_x, MuonResidualsFitter::MuonAlignmentTreeRow::res_x, lumiQTWidget::t, and groupFilesInBlocks::tt.
{
TFile *f = new TFile(fname.c_str());
TTree *t = (TTree*)f->Get("mual_ttree");
// Create new temporary file
TFile *tmpf = new TFile("small_tree_fit.root","recreate");
assert(tmpf!=0);
// filter the tree (temporarily lives in the new file)
TTree *tt = t->CopyTree(Form("is_dt && ring_wheel==%d && station==%d && sector==%d && select==%d", wheel, station, sector, (bool)preselected));
MuonAlignmentTreeRow r;
tt->SetBranchAddress("res_x", &r.res_x);
tt->SetBranchAddress("res_slope_x", &r.res_slope_x);
tt->SetBranchAddress("pos_x", &r.pos_x);
tt->SetBranchAddress("pos_y", &r.pos_y);
tt->SetBranchAddress("angle_x", &r.angle_x);
tt->SetBranchAddress("angle_y", &r.angle_y);
tt->SetBranchAddress("pz", &r.pz);
tt->SetBranchAddress("pt", &r.pt);
tt->SetBranchAddress("q", &r.q);
Long64_t nentries = tt->GetEntries();
for (Long64_t i=0;i<nentries; i++)
{
tt->GetEntry(i);
double *rdata = new double[MuonResiduals5DOFFitter::kNData];
rdata[kResid] = r.res_x;
rdata[kResSlope] = r.res_slope_x;
rdata[kPositionX] = r.pos_x;
rdata[kPositionY] = r.pos_y;
rdata[kAngleX] = r.angle_x;
rdata[kAngleY] = r.angle_y;
rdata[kRedChi2] = 0.1;
rdata[kPz] = r.pz;
rdata[kPt] = r.pt;
rdata[kCharge] = r.q;
fill(rdata);
}
delete f;
//delete tmpf;
return tt;
}
| double MuonResiduals5DOFFitter::sumofweights | ( | ) | [virtual] |
Implements MuonResidualsFitter.
Definition at line 147 of file MuonResiduals5DOFFitter.cc.
References kRedChi2, MuonResidualsFitter::m_weightAlignment, MuonResidualsFitter::residuals_begin(), and MuonResidualsFitter::residuals_end().
Referenced by fit(), and plot().
{
sum_of_weights = 0.;
number_of_hits = 0.;
weight_alignment = m_weightAlignment;
for (std::vector<double*>::const_iterator resiter = residuals_begin(); resiter != residuals_end(); ++resiter) {
if (m_weightAlignment) {
double redchi2 = (*resiter)[MuonResiduals5DOFFitter::kRedChi2];
if (TMath::Prob(redchi2*8, 8) < 0.99) {
sum_of_weights += 1./redchi2;
number_of_hits += 1.;
}
}
else {
sum_of_weights += 1.;
number_of_hits += 1.;
}
}
return sum_of_weights;
}
| int MuonResiduals5DOFFitter::type | ( | ) | const [inline, virtual] |
Implements MuonResidualsFitter.
Definition at line 52 of file MuonResiduals5DOFFitter.h.
References MuonResidualsFitter::k5DOF.
{ return MuonResidualsFitter::k5DOF; }
1.7.3