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rs401d_FeldmanCousins.C
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1/// \file
2/// \ingroup tutorial_roostats
3/// \notebook
4/// Neutrino Oscillation Example from Feldman & Cousins
5///
6/// This tutorial shows a more complex example using the FeldmanCousins utility
7/// to create a confidence interval for a toy neutrino oscillation experiment.
8/// The example attempts to faithfully reproduce the toy example described in Feldman & Cousins'
9/// original paper, Phys.Rev.D57:3873-3889,1998.
10///
11/// \macro_image
12/// \macro_output
13/// \macro_code
14///
15/// \author Kyle Cranmer
16
17#include "RooGlobalFunc.h"
26
27#include "RooDataSet.h"
28#include "RooDataHist.h"
29#include "RooRealVar.h"
30#include "RooConstVar.h"
31#include "RooAddition.h"
32#include "RooProduct.h"
33#include "RooProdPdf.h"
34#include "RooAddPdf.h"
35
36#include "TROOT.h"
37#include "RooPolynomial.h"
38#include "RooRandom.h"
39
40#include "RooNLLVar.h"
41#include "RooProfileLL.h"
42
43#include "RooPlot.h"
44
45#include "TCanvas.h"
46#include "TH1F.h"
47#include "TH2F.h"
48#include "TTree.h"
49#include "TMarker.h"
50#include "TStopwatch.h"
51
52#include <iostream>
53
54// PDF class created for this macro
55#if !defined(__CINT__) || defined(__MAKECINT__)
56#include "../tutorials/roostats/NuMuToNuE_Oscillation.h"
57#include "../tutorials/roostats/NuMuToNuE_Oscillation.cxx" // so that it can be executed directly
58#else
59#include "../tutorials/roostats/NuMuToNuE_Oscillation.cxx+" // so that it can be executed directly
60#endif
61
62// use this order for safety on library loading
63using namespace RooFit;
64using namespace RooStats;
65
66void rs401d_FeldmanCousins(bool doFeldmanCousins = false, bool doMCMC = true)
67{
68
69 // to time the macro
70 TStopwatch t;
71 t.Start();
72
73 // Taken from Feldman & Cousins paper, Phys.Rev.D57:3873-3889,1998.
74 // e-Print: physics/9711021 (see page 13.)
75 //
76 // Quantum mechanics dictates that the probability of such a transformation is given by the formula
77 // $P (\nu\mu \rightarrow \nu e ) = sin^2 (2\theta) sin^2 (1.27 \Delta m^2 L /E )$
78 // where P is the probability for a $\nu\mu$ to transform into a $\nu e$ , L is the distance in km between
79 // the creation of the neutrino from meson decay and its interaction in the detector, E is the
80 // neutrino energy in GeV, and $\Delta m^2 = |m^2 - m^2 |$ in $(eV/c^2 )^2$ .
81 //
82 // To demonstrate how this works in practice, and how it compares to alternative approaches
83 // that have been used, we consider a toy model of a typical neutrino oscillation experiment.
84 // The toy model is defined by the following parameters: Mesons are assumed to decay to
85 // neutrinos uniformly in a region 600 m to 1000 m from the detector. The expected background
86 // from conventional $\nu e$ interactions and misidentified $\nu\mu$ interactions is assumed to be 100
87 // events in each of 5 energy bins which span the region from 10 to 60 GeV. We assume that
88 // the $\nu\mu$ flux is such that if $P (\nu\mu \rightarrow \nu e ) = 0.01$ averaged over any bin, then that bin
89 // would
90 // have an expected additional contribution of 100 events due to $\nu\mu \rightarrow \nu e$ oscillations.
91
92 // Make signal model model
93 RooRealVar E("E", "", 15, 10, 60, "GeV");
94 RooRealVar L("L", "", .800, .600, 1.0, "km"); // need these units in formula
95 RooRealVar deltaMSq("deltaMSq", "#Delta m^{2}", 40, 1, 300, "eV/c^{2}");
96 RooRealVar sinSq2theta("sinSq2theta", "sin^{2}(2#theta)", .006, .0, .02);
97 // RooRealVar deltaMSq("deltaMSq","#Delta m^{2}",40,20,70,"eV/c^{2}");
98 // RooRealVar sinSq2theta("sinSq2theta","sin^{2}(2#theta)", .006,.001,.01);
99 // PDF for oscillation only describes deltaMSq dependence, sinSq2theta goes into sigNorm
100 // 1) The code for this PDF was created by issuing these commands
101 // root [0] RooClassFactory x
102 // root [1] x.makePdf("NuMuToNuE_Oscillation","L,E,deltaMSq","","pow(sin(1.27*deltaMSq*L/E),2)")
103 NuMuToNuE_Oscillation PnmuTone("PnmuTone", "P(#nu_{#mu} #rightarrow #nu_{e}", L, E, deltaMSq);
104
105 // only E is observable, so create the signal model by integrating out L
106 RooAbsPdf *sigModel = PnmuTone.createProjection(L);
107
108 // create $ \int dE' dL' P(E',L' | \Delta m^2)$.
109 // Given RooFit will renormalize the PDF in the range of the observables,
110 // the average probability to oscillate in the experiment's acceptance
111 // needs to be incorporated into the extended term in the likelihood.
112 // Do this by creating a RooAbsReal representing the integral and divide by
113 // the area in the E-L plane.
114 // The integral should be over "primed" observables, so we need
115 // an independent copy of PnmuTone not to interfere with the original.
116
117 // Independent copy for Integral
118 RooRealVar EPrime("EPrime", "", 15, 10, 60, "GeV");
119 RooRealVar LPrime("LPrime", "", .800, .600, 1.0, "km"); // need these units in formula
120 NuMuToNuE_Oscillation PnmuTonePrime("PnmuTonePrime", "P(#nu_{#mu} #rightarrow #nu_{e}", LPrime, EPrime, deltaMSq);
121 RooAbsReal *intProbToOscInExp = PnmuTonePrime.createIntegral(RooArgSet(EPrime, LPrime));
122
123 // Getting the flux is a bit tricky. It is more clear to include a cross section term that is not
124 // explicitly referred to in the text, eg.
125 // number events in bin = flux * cross-section for nu_e interaction in E bin * average prob nu_mu osc. to nu_e in bin
126 // let maxEventsInBin = flux * cross-section for nu_e interaction in E bin
127 // maxEventsInBin * 1% chance per bin = 100 events / bin
128 // therefore maxEventsInBin = 10,000.
129 // for 5 bins, this means maxEventsTot = 50,000
130 RooConstVar maxEventsTot("maxEventsTot", "maximum number of sinal events", 50000);
131 RooConstVar inverseArea("inverseArea", "1/(#Delta E #Delta L)",
132 1. / (EPrime.getMax() - EPrime.getMin()) / (LPrime.getMax() - LPrime.getMin()));
133
134 // $sigNorm = maxEventsTot \cdot \int dE dL \frac{P_{oscillate\ in\ experiment}}{Area} \cdot {sin}^2(2\theta)$
135 RooProduct sigNorm("sigNorm", "", RooArgSet(maxEventsTot, *intProbToOscInExp, inverseArea, sinSq2theta));
136 // bkg = 5 bins * 100 events / bin
137 RooConstVar bkgNorm("bkgNorm", "normalization for background", 500);
138
139 // flat background (0th order polynomial, so no arguments for coefficients)
140 RooPolynomial bkgEShape("bkgEShape", "flat bkg shape", E);
141
142 // total model
143 RooAddPdf model("model", "", RooArgList(*sigModel, bkgEShape), RooArgList(sigNorm, bkgNorm));
144
145 // for debugging, check model tree
146 // model.printCompactTree();
147 // model.graphVizTree("model.dot");
148
149 // turn off some messages
153
154 // --------------------------------------
155 // n events in data to data, simply sum of sig+bkg
156 Int_t nEventsData = bkgNorm.getVal() + sigNorm.getVal();
157 cout << "generate toy data with nEvents = " << nEventsData << endl;
158 // adjust random seed to get a toy dataset similar to one in paper.
159 // Found by trial and error (3 trials, so not very "fine tuned")
161 // create a toy dataset
162 RooDataSet *data = model.generate(RooArgSet(E), nEventsData);
163
164 // --------------------------------------
165 // make some plots
166 TCanvas *dataCanvas = new TCanvas("dataCanvas");
167 dataCanvas->Divide(2, 2);
168
169 // plot the PDF
170 dataCanvas->cd(1);
171 TH1 *hh = PnmuTone.createHistogram("hh", E, Binning(40), YVar(L, Binning(40)), Scaling(kFALSE));
172 hh->SetLineColor(kBlue);
173 hh->SetTitle("True Signal Model");
174 hh->Draw("surf");
175
176 // plot the data with the best fit
177 dataCanvas->cd(2);
178 RooPlot *Eframe = E.frame();
179 data->plotOn(Eframe);
180 model.fitTo(*data, Extended());
181 model.plotOn(Eframe);
182 model.plotOn(Eframe, Components(*sigModel), LineColor(kRed));
183 model.plotOn(Eframe, Components(bkgEShape), LineColor(kGreen));
184 model.plotOn(Eframe);
185 Eframe->SetTitle("toy data with best fit model (and sig+bkg components)");
186 Eframe->Draw();
187
188 // plot the likelihood function
189 dataCanvas->cd(3);
190 RooNLLVar nll("nll", "nll", model, *data, Extended());
191 RooProfileLL pll("pll", "", nll, RooArgSet(deltaMSq, sinSq2theta));
192 // TH1* hhh = nll.createHistogram("hhh",sinSq2theta,Binning(40),YVar(deltaMSq,Binning(40))) ;
193 TH1 *hhh = pll.createHistogram("hhh", sinSq2theta, Binning(40), YVar(deltaMSq, Binning(40)), Scaling(kFALSE));
194 hhh->SetLineColor(kBlue);
195 hhh->SetTitle("Likelihood Function");
196 hhh->Draw("surf");
197
198 dataCanvas->Update();
199
200 // --------------------------------------------------------------
201 // show use of Feldman-Cousins utility in RooStats
202 // set the distribution creator, which encodes the test statistic
203 RooArgSet parameters(deltaMSq, sinSq2theta);
204 RooWorkspace *w = new RooWorkspace();
205
206 ModelConfig modelConfig;
207 modelConfig.SetWorkspace(*w);
208 modelConfig.SetPdf(model);
209 modelConfig.SetParametersOfInterest(parameters);
210
211 RooStats::FeldmanCousins fc(*data, modelConfig);
212 fc.SetTestSize(.1); // set size of test
213 fc.UseAdaptiveSampling(true);
214 fc.SetNBins(10); // number of points to test per parameter
215
216 // use the Feldman-Cousins tool
217 ConfInterval *interval = 0;
218 if (doFeldmanCousins)
219 interval = fc.GetInterval();
220
221 // ---------------------------------------------------------
222 // show use of ProfileLikeihoodCalculator utility in RooStats
223 RooStats::ProfileLikelihoodCalculator plc(*data, modelConfig);
224 plc.SetTestSize(.1);
225
226 ConfInterval *plcInterval = plc.GetInterval();
227
228 // --------------------------------------------
229 // show use of MCMCCalculator utility in RooStats
230 MCMCInterval *mcInt = NULL;
231
232 if (doMCMC) {
233 // turn some messages back on
236
237 TStopwatch mcmcWatch;
238 mcmcWatch.Start();
239
240 RooArgList axisList(deltaMSq, sinSq2theta);
241 MCMCCalculator mc(*data, modelConfig);
242 mc.SetNumIters(5000);
243 mc.SetNumBurnInSteps(100);
244 mc.SetUseKeys(true);
245 mc.SetTestSize(.1);
246 mc.SetAxes(axisList); // set which is x and y axis in posterior histogram
247 // mc.SetNumBins(50);
248 mcInt = (MCMCInterval *)mc.GetInterval();
249
250 mcmcWatch.Stop();
251 mcmcWatch.Print();
252 }
253 // -------------------------------
254 // make plot of resulting interval
255
256 dataCanvas->cd(4);
257
258 // first plot a small dot for every point tested
259 if (doFeldmanCousins) {
260 RooDataHist *parameterScan = (RooDataHist *)fc.GetPointsToScan();
261 TH2F *hist = (TH2F *)parameterScan->createHistogram("sinSq2theta:deltaMSq", 30, 30);
262 // hist->Draw();
263 TH2F *forContour = (TH2F *)hist->Clone();
264
265 // now loop through the points and put a marker if it's in the interval
266 RooArgSet *tmpPoint;
267 // loop over points to test
268 for (Int_t i = 0; i < parameterScan->numEntries(); ++i) {
269 // get a parameter point from the list of points to test.
270 tmpPoint = (RooArgSet *)parameterScan->get(i)->clone("temp");
271
272 if (interval) {
273 if (interval->IsInInterval(*tmpPoint)) {
274 forContour->SetBinContent(
275 hist->FindBin(tmpPoint->getRealValue("sinSq2theta"), tmpPoint->getRealValue("deltaMSq")), 1);
276 } else {
277 forContour->SetBinContent(
278 hist->FindBin(tmpPoint->getRealValue("sinSq2theta"), tmpPoint->getRealValue("deltaMSq")), 0);
279 }
280 }
281
282 delete tmpPoint;
283 }
284
285 if (interval) {
286 Double_t level = 0.5;
287 forContour->SetContour(1, &level);
288 forContour->SetLineWidth(2);
289 forContour->SetLineColor(kRed);
290 forContour->Draw("cont2,same");
291 }
292 }
293
294 MCMCIntervalPlot *mcPlot = NULL;
295 if (mcInt) {
296 cout << "MCMC actual confidence level: " << mcInt->GetActualConfidenceLevel() << endl;
297 mcPlot = new MCMCIntervalPlot(*mcInt);
298 mcPlot->SetLineColor(kMagenta);
299 mcPlot->Draw();
300 }
301 dataCanvas->Update();
302
303 LikelihoodIntervalPlot plotInt((LikelihoodInterval *)plcInterval);
304 plotInt.SetTitle("90% Confidence Intervals");
305 if (mcInt)
306 plotInt.Draw("same");
307 else
308 plotInt.Draw();
309 dataCanvas->Update();
310
311 /// print timing info
312 t.Stop();
313 t.Print();
314}
int Int_t
Definition RtypesCore.h:45
const Bool_t kFALSE
Definition RtypesCore.h:92
double Double_t
Definition RtypesCore.h:59
const Bool_t kTRUE
Definition RtypesCore.h:91
@ kRed
Definition Rtypes.h:66
@ kGreen
Definition Rtypes.h:66
@ kMagenta
Definition Rtypes.h:66
@ kBlue
Definition Rtypes.h:66
static struct mg_connection * fc(struct mg_context *ctx)
Definition civetweb.c:3728
Double_t getRealValue(const char *name, Double_t defVal=0, Bool_t verbose=kFALSE) const
Get value of a RooAbsReal stored in set with given name.
TH1 * createHistogram(const char *name, const RooAbsRealLValue &xvar, const RooCmdArg &arg1=RooCmdArg::none(), const RooCmdArg &arg2=RooCmdArg::none(), const RooCmdArg &arg3=RooCmdArg::none(), const RooCmdArg &arg4=RooCmdArg::none(), const RooCmdArg &arg5=RooCmdArg::none(), const RooCmdArg &arg6=RooCmdArg::none(), const RooCmdArg &arg7=RooCmdArg::none(), const RooCmdArg &arg8=RooCmdArg::none()) const
Calls createHistogram(const char *name, const RooAbsRealLValue& xvar, const RooLinkedList& argList) c...
virtual RooPlot * plotOn(RooPlot *frame, const RooCmdArg &arg1=RooCmdArg::none(), const RooCmdArg &arg2=RooCmdArg::none(), const RooCmdArg &arg3=RooCmdArg::none(), const RooCmdArg &arg4=RooCmdArg::none(), const RooCmdArg &arg5=RooCmdArg::none(), const RooCmdArg &arg6=RooCmdArg::none(), const RooCmdArg &arg7=RooCmdArg::none(), const RooCmdArg &arg8=RooCmdArg::none()) const
virtual RooAbsPdf * createProjection(const RooArgSet &iset)
Return a p.d.f that represent a projection of this p.d.f integrated over given observables.
RooAbsReal is the common abstract base class for objects that represent a real value and implements f...
Definition RooAbsReal.h:61
RooAbsReal * createIntegral(const RooArgSet &iset, const RooCmdArg &arg1, const RooCmdArg &arg2=RooCmdArg::none(), const RooCmdArg &arg3=RooCmdArg::none(), const RooCmdArg &arg4=RooCmdArg::none(), const RooCmdArg &arg5=RooCmdArg::none(), const RooCmdArg &arg6=RooCmdArg::none(), const RooCmdArg &arg7=RooCmdArg::none(), const RooCmdArg &arg8=RooCmdArg::none()) const
Create an object that represents the integral of the function over one or more observables listed in ...
RooAddPdf is an efficient implementation of a sum of PDFs of the form.
Definition RooAddPdf.h:32
RooArgList is a container object that can hold multiple RooAbsArg objects.
Definition RooArgList.h:21
RooArgSet is a container object that can hold multiple RooAbsArg objects.
Definition RooArgSet.h:29
TObject * clone(const char *newname) const override
Definition RooArgSet.h:83
RooConstVar represent a constant real-valued object.
Definition RooConstVar.h:26
The RooDataHist is a container class to hold N-dimensional binned data.
Definition RooDataHist.h:37
Int_t numEntries() const override
Return the number of bins.
const RooArgSet * get() const override
Get bin centre of current bin.
Definition RooDataHist.h:74
RooDataSet is a container class to hold unbinned data.
Definition RooDataSet.h:33
void setStreamStatus(Int_t id, Bool_t active)
(De)Activate stream with given unique ID
static RooMsgService & instance()
Return reference to singleton instance.
Class RooNLLVar implements a -log(likelihood) calculation from a dataset and a PDF.
Definition RooNLLVar.h:30
A RooPlot is a plot frame and a container for graphics objects within that frame.
Definition RooPlot.h:44
void SetTitle(const char *name)
Set the title of the RooPlot to 'title'.
Definition RooPlot.cxx:1242
virtual void Draw(Option_t *options=0)
Draw this plot and all of the elements it contains.
Definition RooPlot.cxx:691
RooPolynomial implements a polynomial p.d.f of the form.
A RooProduct represents the product of a given set of RooAbsReal objects.
Definition RooProduct.h:29
Class RooProfileLL implements the profile likelihood estimator for a given likelihood and set of para...
static TRandom * randomGenerator()
Return a pointer to a singleton random-number generator implementation.
Definition RooRandom.cxx:53
RooRealVar represents a variable that can be changed from the outside.
Definition RooRealVar.h:39
ConfInterval is an interface class for a generic interval in the RooStats framework.
virtual Bool_t IsInInterval(const RooArgSet &) const =0
check if given point is in the interval
The FeldmanCousins class (like the Feldman-Cousins technique) is essentially a specific configuration...
This class provides simple and straightforward utilities to plot a LikelihoodInterval object.
LikelihoodInterval is a concrete implementation of the RooStats::ConfInterval interface.
Bayesian Calculator estimating an interval or a credible region using the Markov-Chain Monte Carlo me...
This class provides simple and straightforward utilities to plot a MCMCInterval object.
void SetLineColor(Color_t color)
void Draw(const Option_t *options=NULL)
MCMCInterval is a concrete implementation of the RooStats::ConfInterval interface.
virtual Double_t GetActualConfidenceLevel()
virtual Double_t GetKeysPdfCutoff() { return fKeysCutoff; }
ModelConfig is a simple class that holds configuration information specifying how a model should be u...
Definition ModelConfig.h:30
virtual void SetWorkspace(RooWorkspace &ws)
Definition ModelConfig.h:66
virtual void SetParametersOfInterest(const RooArgSet &set)
Specify parameters of interest.
virtual void SetPdf(const RooAbsPdf &pdf)
Set the Pdf, add to the the workspace if not already there.
Definition ModelConfig.h:81
The ProfileLikelihoodCalculator is a concrete implementation of CombinedCalculator (the interface cla...
The RooWorkspace is a persistable container for RooFit projects.
virtual void SetLineWidth(Width_t lwidth)
Set the line width.
Definition TAttLine.h:43
virtual void SetLineColor(Color_t lcolor)
Set the line color.
Definition TAttLine.h:40
The Canvas class.
Definition TCanvas.h:23
TVirtualPad * cd(Int_t subpadnumber=0) override
Set current canvas & pad.
Definition TCanvas.cxx:708
void Update() override
Update canvas pad buffers.
Definition TCanvas.cxx:2504
TH1 is the base class of all histogram classes in ROOT.
Definition TH1.h:58
virtual void SetTitle(const char *title)
See GetStatOverflows for more information.
Definition TH1.cxx:6678
TObject * Clone(const char *newname=0) const
Make a complete copy of the underlying object.
Definition TH1.cxx:2740
virtual void SetContour(Int_t nlevels, const Double_t *levels=0)
Set the number and values of contour levels.
Definition TH1.cxx:8331
virtual void Draw(Option_t *option="")
Draw this histogram with options.
Definition TH1.cxx:3073
virtual Int_t FindBin(Double_t x, Double_t y=0, Double_t z=0)
Return Global bin number corresponding to x,y,z.
Definition TH1.cxx:3680
2-D histogram with a float per channel (see TH1 documentation)}
Definition TH2.h:251
virtual void SetBinContent(Int_t bin, Double_t content)
Set bin content.
Definition TH2.cxx:2507
void Divide(Int_t nx=1, Int_t ny=1, Float_t xmargin=0.01, Float_t ymargin=0.01, Int_t color=0) override
Automatic pad generation by division.
Definition TPad.cxx:1177
virtual void SetSeed(ULong_t seed=0)
Set the random generator seed.
Definition TRandom.cxx:608
Stopwatch class.
Definition TStopwatch.h:28
void Start(Bool_t reset=kTRUE)
Start the stopwatch.
void Stop()
Stop the stopwatch.
void Print(Option_t *option="") const
Print the real and cpu time passed between the start and stop events.
RooCmdArg Scaling(Bool_t flag)
RooCmdArg YVar(const RooAbsRealLValue &var, const RooCmdArg &arg=RooCmdArg::none())
RooCmdArg Extended(Bool_t flag=kTRUE)
RooCmdArg Binning(const RooAbsBinning &binning)
RooCmdArg Components(const RooArgSet &compSet)
RooCmdArg LineColor(Color_t color)
RooArgList L(const RooAbsArg &v1)
The namespace RooFit contains mostly switches that change the behaviour of functions of PDFs (or othe...
Namespace for the RooStats classes.
Definition Asimov.h:19
constexpr Double_t E()
Base of natural log:
Definition TMath.h:96