////////////////////////////////////////////////////////////////////////// // // 'MULTIDIMENSIONAL MODELS' RooFit tutorial macro #306 // // Complete example with use of conditional p.d.f. with per-event errors // // // // 07/2008 - Wouter Verkerke // ///////////////////////////////////////////////////////////////////////// #ifndef __CINT__ #include "RooGlobalFunc.h" #endif #include "RooRealVar.h" #include "RooDataSet.h" #include "RooGaussian.h" #include "RooGaussModel.h" #include "RooDecay.h" #include "RooLandau.h" #include "RooPlot.h" #include "TCanvas.h" #include "TH2D.h" using namespace RooFit ; class TestBasic306 : public RooFitTestUnit { public: TestBasic306(TFile* refFile, Bool_t writeRef, Int_t verbose) : RooFitTestUnit("Conditional use of per-event error p.d.f. F(t|dt)",refFile,writeRef,verbose) {} ; Bool_t testCode() { // B - p h y s i c s p d f w i t h p e r - e v e n t G a u s s i a n r e s o l u t i o n // ---------------------------------------------------------------------------------------------- // Observables RooRealVar dt("dt","dt",-10,10) ; RooRealVar dterr("dterr","per-event error on dt",0.01,10) ; // Build a gaussian resolution model scaled by the per-event error = gauss(dt,bias,sigma*dterr) RooRealVar bias("bias","bias",0,-10,10) ; RooRealVar sigma("sigma","per-event error scale factor",1,0.1,10) ; RooGaussModel gm("gm1","gauss model scaled bt per-event error",dt,bias,sigma,dterr) ; // Construct decay(dt) (x) gauss1(dt|dterr) RooRealVar tau("tau","tau",1.548) ; RooDecay decay_gm("decay_gm","decay",dt,tau,gm,RooDecay::DoubleSided) ; // C o n s t r u c t f a k e ' e x t e r n a l ' d a t a w i t h p e r - e v e n t e r r o r // ------------------------------------------------------------------------------------------------------ // Use landau p.d.f to get somewhat realistic distribution with long tail RooLandau pdfDtErr("pdfDtErr","pdfDtErr",dterr,RooConst(1),RooConst(0.25)) ; RooDataSet* expDataDterr = pdfDtErr.generate(dterr,10000) ; // S a m p l e d a t a f r o m c o n d i t i o n a l d e c a y _ g m ( d t | d t e r r ) // --------------------------------------------------------------------------------------------- // Specify external dataset with dterr values to use decay_dm as conditional p.d.f. RooDataSet* data = decay_gm.generate(dt,ProtoData(*expDataDterr)) ; // F i t c o n d i t i o n a l d e c a y _ d m ( d t | d t e r r ) // --------------------------------------------------------------------- // Specify dterr as conditional observable decay_gm.fitTo(*data,ConditionalObservables(dterr)) ; // P l o t c o n d i t i o n a l d e c a y _ d m ( d t | d t e r r ) // --------------------------------------------------------------------- // Make two-dimensional plot of conditional p.d.f in (dt,dterr) TH1* hh_decay = decay_gm.createHistogram("hh_decay",dt,Binning(50),YVar(dterr,Binning(50))) ; hh_decay->SetLineColor(kBlue) ; // Plot decay_gm(dt|dterr) at various values of dterr RooPlot* frame = dt.frame(Title("Slices of decay(dt|dterr) at various dterr")) ; for (Int_t ibin=0 ; ibin<100 ; ibin+=20) { dterr.setBin(ibin) ; decay_gm.plotOn(frame,Normalization(5.),Name(Form("curve_slice_%d",ibin))) ; } // Make projection of data an dt RooPlot* frame2 = dt.frame(Title("Projection of decay(dt|dterr) on dt")) ; data->plotOn(frame2) ; // Make projection of decay(dt|dterr) on dt. // // Instead of integrating out dterr, make a weighted average of curves // at values dterr_i as given in the external dataset. // (The kTRUE argument bins the data before projection to speed up the process) decay_gm.plotOn(frame2,ProjWData(*expDataDterr,kTRUE)) ; regTH(hh_decay,"rf306_model2d") ; regPlot(frame,"rf306_plot1") ; regPlot(frame2,"rf306_plot2") ; delete expDataDterr ; delete data ; return kTRUE ; } } ;