doc/v628/fit2dHist_8C_source.html

/// \file

/// \ingroup tutorial_fit

/// \notebook

///

/// Example to fit two histograms at the same time via the Fitter class

///

/// To execute this tutorial, you can do:

///

/// ~~~{.cpp}

/// root > .x fit2dHist.C  (executing via CINT, slow)

/// ~~~

///

///   or

/// ~~~{.cpp}

/// root > .x fit2dHist.C+     (executing via ACLIC , fast, with Minuit)

/// root > .x fit2dHist.C+(2)  (executing via ACLIC , fast, with Minuit2)

/// ~~~

///

///   or using the option to fit independently the 2 histos

/// ~~~{.cpp}

/// root > .x fit2dHist.C+(10) (via ACLIC, fast, independent fits with Minuit)

/// root > .x fit2dHist.C+(12) (via ACLIC, fast, independent fits with Minuit2)

/// ~~~

///

/// Note that you can also execute this script in batch with eg,

/// ~~~{.cpp}

///  root -b -q "fit2dHist.C+(12)"

/// ~~~

///

/// or execute interactively from the shell

/// ~~~{.cpp}

///  root fit2dHist.C+

///  root "fit2dHist.C+(12)"

/// ~~~

///

/// \macro_image

/// \macro_output

/// \macro_code

///

/// \authors: Lorenzo Moneta, Rene Brun 18/01/2006


#include "TH2D.h"

#include "TF2.h"

#include "TCanvas.h"

#include "TStyle.h"

#include "TRandom3.h"

#include "Fit/Fitter.h"

#include "TList.h"


#include <iostream>


double gauss2D(double *x, double *par) {

   double z1 = double((x[0]-par[1])/par[2]);

   double z2 = double((x[1]-par[3])/par[4]);

   return par[0]*exp(-0.5*(z1*z1+z2*z2));

}

double my2Dfunc(double *x, double *par) {

   return gauss2D(x,&par[0]) + gauss2D(x,&par[5]);

}


class MyFcn {

 public:

   TH2D *h1 = nullptr;

   TH2D *h2 = nullptr;

   int npfits = 0;


   MyFcn(TH2D * _h1, TH2D * _h2) :

    h1(_h1), h2(_h2) {}


   double operator()(const double *p) {


   TAxis *xaxis1  = h1->GetXaxis();

   TAxis *yaxis1  = h1->GetYaxis();

   TAxis *xaxis2  = h2->GetXaxis();

   TAxis *yaxis2  = h2->GetYaxis();


   int nbinX1 = h1->GetNbinsX();

   int nbinY1 = h1->GetNbinsY();

   int nbinX2 = h2->GetNbinsX();

   int nbinY2 = h2->GetNbinsY();


   double chi2 = 0;

   double x[2];

   double tmp;

   npfits = 0;

   for (int ix = 1; ix <= nbinX1; ++ix) {

      x[0] = xaxis1->GetBinCenter(ix);

      for (int iy = 1; iy <= nbinY1; ++iy) {

         if ( h1->GetBinError(ix,iy) > 0 ) {

         x[1] = yaxis1->GetBinCenter(iy);

         tmp = (h1->GetBinContent(ix,iy) - my2Dfunc(x,(double*) p))/h1->GetBinError(ix,iy);

         chi2 += tmp*tmp;

         npfits++;

         }

      }

   }

   for (int ix = 1; ix <= nbinX2; ++ix) {

      x[0] = xaxis2->GetBinCenter(ix);

      for (int iy = 1; iy <= nbinY2; ++iy) {

         if ( h2->GetBinError(ix,iy) > 0 ) {

         x[1] = yaxis2->GetBinCenter(iy);

         tmp = (h2->GetBinContent(ix,iy) - my2Dfunc(x,(double *) p))/h2->GetBinError(ix,iy);

         chi2 += tmp*tmp;

         npfits++;

         }

      }

   }

   return chi2;

}

};


void FillHisto(TH2D * h, int n, double * p) {


   const double mx1 = p[1];

   const double my1 = p[3];

   const double sx1 = p[2];

   const double sy1 = p[4];

   const double mx2 = p[6];

   const double my2 = p[8];

   const double sx2 = p[7];

   const double sy2 = p[9];

   //const double w1 = p[0]*sx1*sy1/(p[5]*sx2*sy2);

   const double w1 = 0.5;


   double x, y;

   for (int i = 0; i < n; ++i) {

      // generate randoms with larger Gaussians

      gRandom->Rannor(x,y);


      double r = gRandom->Rndm(1);

      if (r < w1) {

         x = x*sx1 + mx1;

         y = y*sy1 + my1;

      }

      else {

         x = x*sx2 + mx2;

         y = y*sy2 + my2;

      }

      h->Fill(x,y);


   }

}


int fit2dHist(int option=1) {


   // create two histograms


   int nbx1 = 50;

   int nby1 = 50;

   int nbx2 = 50;

   int nby2 = 50;

   double xlow1 = 0.;

   double ylow1 = 0.;

   double xup1 = 10.;

   double yup1 = 10.;

   double xlow2 = 5.;

   double ylow2 = 5.;

   double xup2 = 20.;

   double yup2 = 20.;


   auto h1 = new TH2D("h1","core",nbx1,xlow1,xup1,nby1,ylow1,yup1);

   auto h2 = new TH2D("h2","tails",nbx2,xlow2,xup2,nby2,ylow2,yup2);


   double iniParams[10] = { 100, 6., 2., 7., 3, 100, 12., 3., 11., 2. };

   // create fit function

   TF2 * func = new TF2("func",my2Dfunc,xlow2,xup2,ylow2,yup2, 10);

   func->SetParameters(iniParams);


   // fill Histos

   int n1 = 1000000;

   int n2 = 1000000;

   FillHisto(h1,n1,iniParams);

   FillHisto(h2,n2,iniParams);


   // scale histograms to same heights (for fitting)

   double dx1 = (xup1-xlow1)/double(nbx1);

   double dy1 = (yup1-ylow1)/double(nby1);

   double dx2 = (xup2-xlow2)/double(nbx2);

   double dy2 = (yup2-ylow2)/double(nby2);

   // scale histo 2 to scale of 1

   h2->Sumw2();

   h2->Scale(  ( double(n1) * dx1 * dy1 )  / ( double(n2) * dx2 * dy2 ) );


   bool global = false;

   if (option > 10) global = true;

   // do global combined fit

   if (global) {

      // fill data structure for fit (coordinates + values + errors)

      std::cout << "Do global fit" << std::endl;

      // fit now all the function together


      ROOT::Fit::Fitter fitter;

      //The default minimizer is Minuit, you can also try Minuit2


      MyFcn myFcn(h1,h2);

      fitter.SetFCN(10, myFcn);

      if (option%10 == 2) fitter.Config().SetMinimizer("Minuit2");


      // set parameter initial value, name and step size

      for (int i = 0; i < 10; ++i) {

         fitter.Config().ParSettings(i) = ROOT::Fit::ParameterSettings(func->GetParName(i), func->GetParameter(i), 0.01);

      }


      bool ret = fitter.FitFCN();

      if (!ret) {

         Error("fit2DHist","Fit Failed to converge");

         return -1;

      }


      //get result

      double minParams[10];

      double parErrors[10];

      for (int i = 0; i < 10; ++i) {

         minParams[i] = fitter.Result().Parameter(i);

         parErrors[i] = fitter.Result().Error(i);

      }

      double chi2 = fitter.Result().MinFcnValue();

      double edm = fitter.Result().Edm();

      int npfits = myFcn.npfits;


      func->SetParameters(minParams);

      func->SetParErrors(parErrors);

      func->SetChisquare(chi2);

      int ndf = npfits - fitter.Result().NFreeParameters();

      func->SetNDF(ndf);


      // add to list of functions

      h1->GetListOfFunctions()->Add(func);

      h2->GetListOfFunctions()->Add(func);

   }

   else {

      // fit independently

      h1->Fit(func);

      h2->Fit(func);

   }


   // Create a new canvas.

   TCanvas * c1 = new TCanvas("c1","Two HIstogram Fit example",100,10,900,800);

   c1->Divide(2,2);

   gStyle->SetOptFit();

   gStyle->SetStatY(0.6);


   c1->cd(1);

   h1->Draw();

   func->SetRange(xlow1,ylow1,xup1,yup1);

   func->DrawCopy("cont1 same");

   c1->cd(2);

   h1->Draw("lego");

   func->DrawCopy("surf1 same");

   c1->cd(3);

   func->SetRange(xlow2,ylow2,xup2,yup2);

   h2->Draw();

   func->DrawCopy("cont1 same");

   c1->cd(4);

   h2->Draw("lego");

   gPad->SetLogz();

   func->Draw("surf1 same");


   return 0;

}

Fitter.h

h
#define h(i)
Definition RSha256.hxx:106

TCanvas.h

Error
void Error(const char *location, const char *msgfmt,...)
Use this function in case an error occurred.
Definition TError.cxx:197

TF2.h

p
winID h TVirtualViewer3D TVirtualGLPainter p
Definition TGWin32VirtualGLProxy.cxx:51

option
Option_t Option_t option
Definition TGWin32VirtualXProxy.cxx:44

r
Option_t Option_t TPoint TPoint const char GetTextMagnitude GetFillStyle GetLineColor GetLineWidth GetMarkerStyle GetTextAlign GetTextColor GetTextSize void char Point_t Rectangle_t WindowAttributes_t Float_t r
Definition TGWin32VirtualXProxy.cxx:168

TH2D.h

TList.h

operator()
TRObject operator()(const T1 &t1) const
Definition TRFunctionImport__oprtr.h:14

TRandom3.h

gRandom
R__EXTERN TRandom * gRandom
Definition TRandom.h:62

TStyle.h

gStyle
R__EXTERN TStyle * gStyle
Definition TStyle.h:414

gPad
#define gPad
Definition TVirtualPad.h:303

ROOT::Fit::FitConfig::SetMinimizer
void SetMinimizer(const char *type, const char *algo=nullptr)
set minimizer type
Definition FitConfig.h:181

ROOT::Fit::FitConfig::ParSettings
const ParameterSettings & ParSettings(unsigned int i) const
get the parameter settings for the i-th parameter (const method)
Definition FitConfig.h:76

ROOT::Fit::FitResult::Error
double Error(unsigned int i) const
parameter error by index
Definition FitResult.h:177

ROOT::Fit::FitResult::MinFcnValue
double MinFcnValue() const
Return value of the objective function (chi2 or likelihood) used in the fit.
Definition FitResult.h:111

ROOT::Fit::FitResult::Edm
double Edm() const
Expected distance from minimum.
Definition FitResult.h:117

ROOT::Fit::FitResult::NFreeParameters
unsigned int NFreeParameters() const
get total number of free parameters
Definition FitResult.h:125

ROOT::Fit::FitResult::Parameter
double Parameter(unsigned int i) const
parameter value by index
Definition FitResult.h:172

ROOT::Fit::Fitter
Fitter class, entry point for performing all type of fits.
Definition Fitter.h:77

ROOT::Fit::Fitter::FitFCN
bool FitFCN(unsigned int npar, Function &fcn, const double *params=0, unsigned int dataSize=0, bool chi2fit=false)
Fit using the a generic FCN function as a C++ callable object implementing double () (const double *)...
Definition Fitter.h:659

ROOT::Fit::Fitter::SetFCN
bool SetFCN(unsigned int npar, Function &fcn, const double *params=0, unsigned int dataSize=0, bool chi2fit=false)
Set a generic FCN function as a C++ callable object implementing double () (const double *) Note that...
Definition Fitter.h:666

ROOT::Fit::Fitter::Result
const FitResult & Result() const
get fit result
Definition Fitter.h:418

ROOT::Fit::Fitter::Config
const FitConfig & Config() const
access to the fit configuration (const method)
Definition Fitter.h:446

ROOT::Fit::ParameterSettings
Class, describing value, limits and step size of the parameters Provides functionality also to set/re...
Definition ParameterSettings.h:36

TAxis
Class to manage histogram axis.
Definition TAxis.h:30

TAxis::GetBinCenter
virtual Double_t GetBinCenter(Int_t bin) const
Return center of bin.
Definition TAxis.cxx:478

TCanvas
The Canvas class.
Definition TCanvas.h:23

TF1::SetNDF
virtual void SetNDF(Int_t ndf)
Set the number of degrees of freedom ndf should be the number of points used in a fit - the number of...
Definition TF1.cxx:3417

TF1::SetChisquare
virtual void SetChisquare(Double_t chi2)
Definition TF1.h:617

TF1::SetParErrors
virtual void SetParErrors(const Double_t *errors)
Set errors for all active parameters when calling this function, the array errors must have at least ...
Definition TF1.cxx:3482

TF1::GetParName
virtual const char * GetParName(Int_t ipar) const
Definition TF1.h:534

TF1::SetParameters
virtual void SetParameters(const Double_t *params)
Definition TF1.h:649

TF1::GetParameter
virtual Double_t GetParameter(Int_t ipar) const
Definition TF1.h:517

TF2
A 2-Dim function with parameters.
Definition TF2.h:29

TF2::DrawCopy
TF1 * DrawCopy(Option_t *option="") const override
Draw a copy of this function with its current attributes-*.
Definition TF2.cxx:286

TF2::Draw
void Draw(Option_t *option="") override
Draw this function with its current attributes.
Definition TF2.cxx:259

TF2::SetRange
void SetRange(Double_t xmin, Double_t xmax) override
Initialize the upper and lower bounds to draw the function.
Definition TF2.h:148

TH1::GetNbinsY
virtual Int_t GetNbinsY() const
Definition TH1.h:296

TH1::GetBinError
virtual Double_t GetBinError(Int_t bin) const
Return value of error associated to bin number bin.
Definition TH1.cxx:8929

TH1::GetXaxis
TAxis * GetXaxis()
Definition TH1.h:322

TH1::Fit
virtual TFitResultPtr Fit(const char *formula, Option_t *option="", Option_t *goption="", Double_t xmin=0, Double_t xmax=0)
Fit histogram with function fname.
Definition TH1.cxx:3894

TH1::GetNbinsX
virtual Int_t GetNbinsX() const
Definition TH1.h:295

TH1::GetYaxis
TAxis * GetYaxis()
Definition TH1.h:323

TH1::Draw
void Draw(Option_t *option="") override
Draw this histogram with options.
Definition TH1.cxx:3060

TH1::GetListOfFunctions
TList * GetListOfFunctions() const
Definition TH1.h:242

TH1::GetBinContent
virtual Double_t GetBinContent(Int_t bin) const
Return content of bin number bin.
Definition TH1.cxx:5025

TH1::Scale
virtual void Scale(Double_t c1=1, Option_t *option="")
Multiply this histogram by a constant c1.
Definition TH1.cxx:6586

TH1::Sumw2
virtual void Sumw2(Bool_t flag=kTRUE)
Create structure to store sum of squares of weights.
Definition TH1.cxx:8886

TH2D
2-D histogram with a double per channel (see TH1 documentation)}
Definition TH2.h:300

TH2::GetBinContent
Double_t GetBinContent(Int_t binx, Int_t biny) const override
Definition TH2.h:89

TList::Add
void Add(TObject *obj) override
Definition TList.h:81

TRandom::Rndm
Double_t Rndm() override
Machine independent random number generator.
Definition TRandom.cxx:552

TRandom::Rannor
virtual void Rannor(Float_t &a, Float_t &b)
Return 2 numbers distributed following a gaussian with mean=0 and sigma=1.
Definition TRandom.cxx:500

TStyle::SetStatY
void SetStatY(Float_t y=0)
Definition TStyle.h:382

TStyle::SetOptFit
void SetOptFit(Int_t fit=1)
The type of information about fit parameters printed in the histogram statistics box can be selected ...
Definition TStyle.cxx:1542

double

ROOT::VecOps::exp
RVec< PromoteType< T > > exp(const RVec< T > &v)
Definition RVec.hxx:1785

y
Double_t y[n]
Definition legend1.C:17

c1
return c1
Definition legend1.C:41

x
Double_t x[n]
Definition legend1.C:17

n
const Int_t n
Definition legend1.C:16

h1
TH1F * h1
Definition legend1.C:5