BOSS 7.0.8
BESIII Offline Software System
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HadronPrep Class Reference

#include <HadronPrep.h>

Public Member Functions

 HadronPrep ()
 
virtual ~HadronPrep ()
 
 HadronPrep (TString infile, int mcflag, int type, int bgbins, double upperbg, double lowerbg, int cosbins, double uppercos, double lowercos)
 
void FormatGraph (TGraphErrors *gr, int flag)
 
void bgCosThetaFits (TString particle, TFile *outfile, bool correct, std::string paramfile)
 
void bgFits (TString particle, TFile *outfile, bool correct, std::string paramfile)
 

Detailed Description

Definition at line 45 of file HadronPrep.h.

Constructor & Destructor Documentation

◆ HadronPrep() [1/2]

HadronPrep::HadronPrep ( )

Definition at line 3 of file HadronPrep.cc.

3 :
4 m_filename("widget.gen.root"),
5 m_mcFlag(1),
6 m_type(0),
7 m_bgbins(15),
8 m_upperbg(5.0),
9 m_lowerbg(0.1),
10 m_cosbins(18),
11 m_uppercos(0.93),
12 m_lowercos(0.0)
13{}

◆ ~HadronPrep()

virtual HadronPrep::~HadronPrep ( )
inlinevirtual

Definition at line 50 of file HadronPrep.h.

50{};

◆ HadronPrep() [2/2]

HadronPrep::HadronPrep ( TString  infile,
int  mcflag,
int  type,
int  bgbins,
double  upperbg,
double  lowerbg,
int  cosbins,
double  uppercos,
double  lowercos 
)

Definition at line 15 of file HadronPrep.cc.

15 {
16 m_filename = infile;
17 m_mcFlag = mcFlag;
18 m_type = type;
19 m_bgbins = bgbins;
20 m_upperbg = upperbg;
21 m_lowerbg = lowerbg;
22 m_cosbins = cosbins;
23 m_uppercos = uppercos;
24 m_lowercos = lowercos;
25}

Member Function Documentation

◆ bgCosThetaFits()

void HadronPrep::bgCosThetaFits ( TString  particle,
TFile *  outfile,
bool  correct,
std::string  paramfile 
)

Definition at line 55 of file HadronPrep.cc.

55 {
56
57 // supress TCanvas::Print messages
58 gErrorIgnoreLevel = kWarning;
59
60 m_gpar.setParameters(paramfile);
61
62 double mass = 0.0;
63 if( particle == "pion" ) mass = Widget::mpion;
64 else if( particle == "kaon" ) mass = Widget::mkaon;
65 else if( particle == "proton" ) mass = Widget::mproton;
66 else if( particle == "muon" ) mass = Widget::mmuon;
67 else if( particle == "electron" ) mass = Widget::melectron;
68 if( mass == 0.0 ) exit(1);
69
70 TFile* infile = new TFile(m_filename);
71 TTree* hadron = (TTree*)infile->Get("track");
72
73 std::cout << "HadronPrep: reading in file " << m_filename << std::endl;
74 std::cout << "\t beta-gamma range: " << m_lowerbg << " to " << m_upperbg << std::endl;
75 std::cout << "\t cos(theta) range: " << m_lowercos << " to " << m_uppercos << std::endl;
76
77 // --------------------------------------------------
78 // INITIALIZE CONTAINERS
79 // --------------------------------------------------
80
81 double dedxpub; // dE/dx without electron saturation correction
82 double dedx; // dE/dx with electron saturation correction
83 double p; // track momentum
84 double bg; // track beta-gamma
85 double costh; // cosine of track polar angle
86 double db; // the nearest distance to the IP in the xy plane
87 double dz; // the nearest distance to the IP in the z plane
88 double chiPi; // PID chi value
89 double eop; // energy over momentum in the calorimeter
90
91 // Belle II variables
92 int b2nhit; // number of hits on this track
93
94 // BES III variables
95 double b3nhit; // number of hits on this track
96
97 hadron->SetBranchAddress("dedx", &dedxpub);
98 hadron->SetBranchAddress("dedxsat", &dedx);
99 hadron->SetBranchAddress("pF", &p);
100 hadron->SetBranchAddress("costh", &costh);
101 hadron->SetBranchAddress("db", &db);
102 hadron->SetBranchAddress("dz", &dz);
103 hadron->SetBranchAddress("chiPi", &chiPi);
104 hadron->SetBranchAddress("eopst", &eop);
105
106 if( m_type == 0 )
107 hadron->SetBranchAddress("numGoodHits", &b3nhit);
108 else if( m_type == 1 )
109 hadron->SetBranchAddress("lNHitsUsed", &b2nhit);
110 // hadron->SetBranchAddress("numGoodLayerHits", &b2nhit);
111
112 double bgstep = (m_upperbg-m_lowerbg)/m_bgbins;
113 double cosstep = (m_uppercos-m_lowercos)/m_cosbins;
114
115 // Create the histograms to be fit (before correction)
116 TH1F* hdedx_costh[m_bgbins][m_cosbins];
117 TH1F* hdedx_costh_pub[m_bgbins][m_cosbins];
118 TH1F* hchi_costh[m_bgbins][m_cosbins];
119 TH1F* hchi_costh_pub[m_bgbins][m_cosbins];
120
121 // initialize the histograms
122 for( int i = 0; i < m_bgbins; ++i ){
123 for( int j = 0; j < m_cosbins; ++j ){
124 char histname[100],histname2[100],histname3[100],histname4[100],histname5[100];
125 sprintf(histname, "dedx_costh_p_%d_cos_%d",i,j);
126 sprintf(histname2, "chi_costh_p_%d_cos_%d",i,j);
127 sprintf(histname3, "chipub_costh_p_%d_cos_%d",i,j);
128 sprintf(histname4, "dedxpub_costh_p_%d_cos_%d",i,j);
129 sprintf(histname5, "dedxnew_costh_p_%d_cos_%d",i,j);
130
131
132 if( particle == "electron" ){
133 hdedx_costh[i][j] = new TH1F(histname,histname,200,0,2);
134 hchi_costh[i][j] = new TH1F(histname2,histname2,200,-2,2);
135 hchi_costh_pub[i][j] = new TH1F(histname3,histname3,200,-5,5);
136 hdedx_costh_pub[i][j] = new TH1F(histname4,histname4,200,0,2);
137 }
138 else if( particle == "proton" ){
139 if( i < 5 ){
140 hdedx_costh[i][j] = new TH1F(histname,histname,200,0,6);
141 hchi_costh[i][j] = new TH1F(histname2,histname2,200,-30,30);
142 hchi_costh_pub[i][j] = new TH1F(histname3,histname3,200,0,40);
143 hdedx_costh_pub[i][j] = new TH1F(histname4,histname4,200,0,6);
144 }
145 else if( i < 9 ){
146 hdedx_costh[i][j] = new TH1F(histname,histname,200,0,4);
147 hchi_costh[i][j] = new TH1F(histname2,histname2,200,-5,5);
148 hchi_costh_pub[i][j] = new TH1F(histname3,histname3,200,-20,20);
149 hdedx_costh_pub[i][j] = new TH1F(histname4,histname4,200,0,4);
150 }
151 else{
152 hdedx_costh[i][j] = new TH1F(histname,histname,200,0,2);
153 hchi_costh[i][j] = new TH1F(histname2,histname2,200,-5,5);
154 hchi_costh_pub[i][j] = new TH1F(histname3,histname3,200,-5,5);
155 hdedx_costh_pub[i][j] = new TH1F(histname4,histname4,200,0,2);
156 }
157 }
158 else if( i < 2 ){
159 hdedx_costh[i][j] = new TH1F(histname,histname,200,0,4);
160 hchi_costh[i][j] = new TH1F(histname2,histname2,200,-5,5);
161 hchi_costh_pub[i][j] = new TH1F(histname3,histname3,200,-5,5);
162 hdedx_costh_pub[i][j] = new TH1F(histname4,histname4,200,0,4);
163 }
164 else{
165 hdedx_costh[i][j] = new TH1F(histname,histname,200,0,2);
166 hchi_costh[i][j] = new TH1F(histname2,histname2,200,-5,5);
167 hchi_costh_pub[i][j] = new TH1F(histname3,histname3,200,-5,5);
168 hdedx_costh_pub[i][j] = new TH1F(histname4,histname4,200,0,2);
169 }
170 }
171 }
172
173 // Create some containers to calculate averages
174 double sumcos[m_bgbins][m_cosbins];
175 double sumsin[m_bgbins][m_cosbins];
176 double sumbg[m_bgbins][m_cosbins];
177 double sumressq[m_bgbins][m_cosbins];
178 int sumsize[m_bgbins][m_cosbins];
179 for( int i = 0; i < m_bgbins; ++i ){
180 for( int j = 0; j < m_cosbins; ++j ){
181 sumcos[i][j] = 0;
182 sumsin[i][j] = 0;
183 sumbg[i][j] = 0;
184 sumressq[i][j] = 0;
185 sumsize[i][j] = 0;
186 }
187 }
188
189 // Create some containers for means and errors
190 double means[m_bgbins][m_cosbins];
191 double errors[m_bgbins][m_cosbins];
192 double widths[m_bgbins][m_cosbins];
193 for( int i = 0; i < m_bgbins; ++i ){
194 for( int j = 0; j < m_cosbins; ++j ){
195 means[i][j] = 0;
196 errors[i][j] = 0;
197 widths[i][j] = 0;
198 }
199 }
200
201
202 // get the hadron saturation parameters
203 // if the parameters do not exist, use the values in the default constructor
204 m_hadsat.setParameters("sat-pars.fit.txt");
205
206 // --------------------------------------------------
207 // LOOP OVER EVENTS AND FILL CONTAINERS
208 // --------------------------------------------------
209
210 // Fill the histograms to be fitted
211 for( unsigned int index = 0; index < hadron->GetEntries(); ++index ){
212 hadron->GetEvent(index);
213
214 bg = fabs(p)/mass;
215 costh = fabs(costh);
216
217 int nhit;
218 if( m_type == 0 )
219 nhit = std::floor(b3nhit);
220 else if( m_type == 1 )
221 nhit = b2nhit;
222
223 // clean up bad events and restrict the momentum range
224 if( nhit < 0 || nhit > 100 || dedx <= 0 || costh != costh ||
225 bg <= m_lowerbg || bg >= m_upperbg || costh <= m_lowercos || costh >= m_uppercos )
226 continue;
227
228 // apply an E/p cut for pions
229 if( particle == "pion" && eop > 0.75 ) continue;
230
231 // use loose dE/dx restrictions to remove contaminations
232 if( particle == "proton" && (dedxpub < 0 || dedxpub > 100 || dedxpub < 0.85/fabs(p)) )
233 continue;
234 if( particle == "kaon" && dedxpub < 0.4/fabs(p) )
235 continue;
236
237 int bgBin = (int)((bg-m_lowerbg)/(m_upperbg-m_lowerbg) * m_bgbins);
238 int cosBin = (int)((costh-m_lowercos)/(m_uppercos-m_lowercos) * m_cosbins);
239
240 double dedx_pre = dedx;
241 double dedx_new = dedx_pre;
242 if( !m_mcFlag ) dedx_new = m_hadsat.D2I(costh,m_hadsat.I2D(costh,1.0)*dedx);
243 double dedx_cur = m_gpar.dedxPrediction(bg);
244 double dedx_res = m_gpar.sigmaPrediction(dedx_cur,nhit,sqrt(1-costh*costh));
245 if( dedx_res == 0 ){
246 std::cout << "RESOLUTION IS ZERO!!!" << std::endl;
247 continue;
248 }
249
250 double chi_new = (dedx_new-dedx_cur)/dedx_res;
251 if( particle == "electron" ) chi_new = (dedx_new-1)/dedx_res;
252 if( correct ) hdedx_costh[bgBin][cosBin]->Fill(dedx_new);
253 else hdedx_costh[bgBin][cosBin]->Fill(dedx_pre);
254
255 if( correct ) hchi_costh[bgBin][cosBin]->Fill(chi_new);
256 else hchi_costh[bgBin][cosBin]->Fill(chiPi);
257
258 hdedx_costh_pub[bgBin][cosBin]->Fill(dedxpub);
259 hchi_costh_pub[bgBin][cosBin]->Fill(chiPi);
260
261 // if( fabs(bg-(m_lowerbg+0.5*bgstep+bgBin*bgstep)) < 0.5*bgstep &&
262 // fabs(costh-(m_lowercos+0.5*cosstep+cosBin*cosstep)) < 0.5*cosstep ){
263 sumcos[bgBin][cosBin] += costh;
264 sumsin[bgBin][cosBin] += sqrt(1-costh*costh);
265 sumbg[bgBin][cosBin] += bg;
266 sumressq[bgBin][cosBin] += pow(dedx_res,2);
267 sumsize[bgBin][cosBin] += 1;
268 // }
269
270 }// end of event loop
271
272 // --------------------------------------------------
273 // FIT IN BINS OF BETA-GAMMA AND COS(THETA)
274 // --------------------------------------------------
275
276 // fit the histograms with Gaussian functions
277 // and extract the means and errors
278 TTree* satTree = new TTree(particle,"dE/dx means and errors");
279
280 double satbg; // beta-gamma value for this bin
281 double satcosth; // cos(theta) value for this bin
282 double satdedx; // mean dE/dx value for this bin
283 double saterror; // error on ^
284 double satbg_avg; // average beta-gamma value for this sample
285 double satcosth_avg; // average cos(theta) value for this sample
286 double satsinth_avg; // average sin(theta) value for this sample
287 double satdedxres_avg; // average dE/dx error squared for this sample
288 double satpubdedx; // mean "public" dE/dx value for this bin
289 double satpuberror; // error on ^
290 double satpubwidth; // width of ^ distribution
291 double satchi; // mean chi value for this bin
292 double satchierr; // error on ^
293 double satchiwidth; // width of ^ distribution
294 double satchipub; // mean "public" chi value for this bin
295 double satchipuberr; // error on ^
296 double satchipubwidth; // width of ^ distribution
297 double ratio; // ratio of the predicted mean to that of the average
298
299 satTree->Branch("bg",&satbg,"bg/D");
300 satTree->Branch("costh",&satcosth,"costh/D");
301 satTree->Branch("dedx",&satdedx,"dedx/D");
302 satTree->Branch("error",&saterror,"error/D");
303 satTree->Branch("bg_avg",&satbg_avg,"bg_avg/D");
304 satTree->Branch("costh_avg",&satcosth_avg,"costh_avg/D");
305 satTree->Branch("sinth_avg",&satsinth_avg,"sinth_avg/D");
306 satTree->Branch("dedxres_avg",&satdedxres_avg,"dedxres_avg/D");
307 satTree->Branch("dedx_pub",&satpubdedx,"dedx_pub/D");
308 satTree->Branch("dedxerr_pub",&satpuberror,"dedxerr_pub/D");
309 satTree->Branch("chi",&satchi,"chi/D");
310 satTree->Branch("chi_pub",&satchipub,"chi_pub/D");
311 satTree->Branch("sigma",&satchiwidth,"sigma/D");
312 satTree->Branch("sigma_pub",&satchipubwidth,"sigma_pub/D");
313 satTree->Branch("ratio",&ratio,"ratio/D");
314
315 // Fit the histograms
316 int fs1=0, fs2=0, fs3=0, fs4=0;
317 double dedxmax = 1.0, dedxmin = 1.0;
318 for( int i = 0; i < m_bgbins; ++i ){
319 for( int j = 0; j < m_cosbins; ++j ){
320
321 std::cout << "\t\t" << "i= " << i << " j= " << j << std::endl;
322 // fill some details for this bin
323 satbg = m_lowerbg+0.5*bgstep+i*bgstep;
324 satcosth = m_lowercos+0.5*cosstep+j*cosstep;
325
326 satbg_avg = sumbg[i][j]/sumsize[i][j];
327 satcosth_avg = sumcos[i][j]/sumsize[i][j];
328 satsinth_avg = sumsin[i][j]/sumsize[i][j];
329 satdedxres_avg = sumressq[i][j]/sumsize[i][j];
330
331 int fs;
332 // fit the dE/dx distribution in bins of beta-gamma and cosine
333 fs = hdedx_costh[i][j]->Fit("gaus","ql");
334 double mean = hdedx_costh[i][j]->GetFunction("gaus")->GetParameter(1);
335 double width = hdedx_costh[i][j]->GetFunction("gaus")->GetParameter(2);
336 // fs = hdedx_costh[i][j]->Fit("gaus","ql","",mean-2.5*width,mean+2.5*width);
337 fs = hdedx_costh[i][j]->Fit("gaus","l","",mean-2.5*width,mean+2.5*width);
338 if( fs != 0 ){
339 std::cout << "\t\t" <<"MEAN FIT STATUS " << fs << std::endl;
340 fs1++;
341 }
342
343 satdedx = hdedx_costh[i][j]->GetFunction("gaus")->GetParameter(1);
344 saterror = hdedx_costh[i][j]->GetFunction("gaus")->GetParError(1);
345 means[i][j] = satdedx;
346 errors[i][j] = saterror;
347 widths[i][j] = hdedx_costh[i][j]->GetFunction("gaus")->GetParameter(2);
348
349 if( satdedx > dedxmax ) dedxmax = satdedx;
350 if( satdedx < dedxmin ) dedxmin = satdedx;
351
352 // fit the dE/dx distribution without correction in bins of beta-gamma and cosine
353 fs = hdedx_costh_pub[i][j]->Fit("gaus","ql");
354 mean = hdedx_costh_pub[i][j]->GetFunction("gaus")->GetParameter(1);
355 width = hdedx_costh_pub[i][j]->GetFunction("gaus")->GetParameter(2);
356 // fs = hdedx_costh_pub[i][j]->Fit("gaus","ql","",mean-2.5*width,mean+2.5*width);
357 fs = hdedx_costh_pub[i][j]->Fit("gaus","ql","",mean-2.5*width,mean+2.5*width);
358 if( fs != 0 ){
359 std::cout << "\t\t" <<"MEAN PUB FIT STATUS " << fs << std::endl;
360 fs2++;
361 }
362
363 satpubdedx = hdedx_costh_pub[i][j]->GetFunction("gaus")->GetParameter(1);
364 satpuberror = hdedx_costh_pub[i][j]->GetFunction("gaus")->GetParError(1);
365 satpubwidth = hdedx_costh_pub[i][j]->GetFunction("gaus")->GetParameter(2);
366
367
368 // fit the chi distribution
369 fs = hchi_costh[i][j]->Fit("gaus","ql");
370 mean = hchi_costh[i][j]->GetFunction("gaus")->GetParameter(1);
371 width = hchi_costh[i][j]->GetFunction("gaus")->GetParameter(2);
372 fs = hchi_costh[i][j]->Fit("gaus","ql","",mean-2.5*width,mean+2.5*width);
373 if( fs != 0 ){
374 // std::cout << "\t\t" <<"CHI FIT STATUS " << fs << std::endl;
375 fs3++;
376 }
377
378 satchi = hchi_costh[i][j]->GetFunction("gaus")->GetParameter(1);
379 satchierr = hchi_costh[i][j]->GetFunction("gaus")->GetParError(1);
380 satchiwidth = hchi_costh[i][j]->GetFunction("gaus")->GetParameter(2);
381
382
383 // fit the chi distribution without correction
384 /*
385 fs = hchi_costh_pub[i][j]->Fit("gaus","ql");
386 mean = hchi_costh_pub[i][j]->GetFunction("gaus")->GetParameter(1);
387 width = hchi_costh_pub[i][j]->GetFunction("gaus")->GetParameter(2);
388 fs = hchi_costh_pub[i][j]->Fit("gaus","ql","",mean-2.5*width,mean+2.5*width);
389 if( fs != 0 ){
390 // std::cout << "\t\t" <<"CHI PUB FIT STATUS " << fs << std::endl;
391 fs4++;
392 }
393
394 satchipub = hchi_costh_pub[i][j]->GetFunction("gaus")->GetParameter(1);
395 satchipuberr = hchi_costh_pub[i][j]->GetFunction("gaus")->GetParError(1);
396 satchipubwidth = hchi_costh_pub[i][j]->GetFunction("gaus")->GetParameter(2);
397 */
398
399 // determine the ratio of the predicted mean at a given bg to that of the average
400 ratio = m_gpar.dedxPrediction(satbg_avg)/m_gpar.dedxPrediction(satbg);
401
402 // fill the tree for this bin
403 satTree->Fill();
404 }
405 }
406
407 if( fs1+fs2+fs3+fs4 != 0 ) std::cout << "FIT RESULTS: " << particle << std::endl;
408 if( fs1 != 0 ) std::cout << "\t\t" <<"MEAN FIT FAILS " << fs1 << std::endl;
409 if( fs2 != 0 ) std::cout << "\t\t" <<"MEAN PUB FIT FAILS " << fs2 << std::endl;
410 if( fs3 != 0 ) std::cout << "\t\t" <<"CHI FIT FAILS " << fs3 << std::endl;
411 if( fs4 != 0 ) std::cout << "\t\t" <<"CHI PUB FIT FAILS " << fs4 << std::endl;
412
413 std::string corname("uncorrected");
414 if( correct == true ) corname = "corrected";
415
416 // Print the histograms for quality control
417 TCanvas* ctmp = new TCanvas("tmp","tmp",900,900);
418 ctmp->Divide(3,3);
419 std::stringstream psname; psname << "plots/dedx_" << particle << "_" << corname << ".ps[";
420 ctmp->Print(psname.str().c_str());
421 psname.str(""); psname << "plots/dedx_" << particle << "_" << corname << ".ps";
422 for( int i = 0 ; i < m_bgbins; ++i ){
423 for( int j = 0; j < m_cosbins; ++j ){
424 ctmp->cd(j%9+1);
425 hdedx_costh[i][j]->Draw();
426 if((j+1)%9==0)
427 ctmp->Print(psname.str().c_str());
428 }
429 }
430 psname.str(""); psname << "plots/dedx_" << particle << "_" << corname << ".ps]";
431 ctmp->Print(psname.str().c_str());
432 delete ctmp;
433
434
435 // Print the histograms for quality control
436 TCanvas* ctmp2 = new TCanvas("tmp2","tmp2",900,900);
437 ctmp2->Divide(3,3);
438 psname.str(""); psname << "plots/dedx_" << particle << "_pub_" << corname << ".ps[";
439 ctmp2->Print(psname.str().c_str());
440 psname.str(""); psname << "plots/dedx_" << particle << "_pub_" << corname << ".ps";
441 for( int i = 0 ; i < m_bgbins; ++i ){
442 for( int j = 0; j < m_cosbins; ++j ){
443 ctmp2->cd(j%9+1);
444 hdedx_costh_pub[i][j]->Draw();
445 if((j+1)%9==0)
446 ctmp2->Print(psname.str().c_str());
447 }
448 }
449 psname.str(""); psname << "plots/dedx_" << particle << "_pub_" << corname << ".ps]";
450 ctmp2->Print(psname.str().c_str());
451 delete ctmp2;
452
453
454 // Print the histograms for quality control
455 TCanvas* ctmp3 = new TCanvas("tmp3","tmp3",900,900);
456 ctmp3->Divide(3,3);
457 psname.str(""); psname << "plots/chi_" << particle << "_" << corname << ".ps[";
458 ctmp3->Print(psname.str().c_str());
459 psname.str(""); psname << "plots/chi_" << particle << "_" << corname << ".ps";
460 for( int i = 0 ; i < m_bgbins; ++i ){
461 for( int j = 0; j < m_cosbins; ++j ){
462 ctmp3->cd(j%9+1);
463 hchi_costh[i][j]->Draw();
464 if((j+1)%9==0)
465 ctmp3->Print(psname.str().c_str());
466 }
467 }
468 psname.str(""); psname << "plots/chi_" << particle << "_" << corname << ".ps]";
469 ctmp3->Print(psname.str().c_str());
470 delete ctmp3;
471
472
473 // Print the histograms for quality control
474 TCanvas* ctmp4 = new TCanvas("tmp4","tmp4",900,900);
475 ctmp4->Divide(3,3);
476 psname.str(""); psname << "plots/chi_" << particle << "_pub_" << corname << ".ps[";
477 ctmp4->Print(psname.str().c_str());
478 psname.str(""); psname << "plots/chi_" << particle << "_pub_" << corname << ".ps";
479 for( int i = 0 ; i < m_bgbins; ++i ){
480 for( int j = 0; j < m_cosbins; ++j ){
481 ctmp4->cd(j%9+1);
482 hchi_costh_pub[i][j]->Draw();
483 if((j+1)%9==0)
484 ctmp4->Print(psname.str().c_str());
485 }
486 }
487 psname.str(""); psname << "plots/chi_" << particle << "_pub_" << corname << ".ps]";
488 ctmp4->Print(psname.str().c_str());
489 delete ctmp4;
490
491 double cbcenters[m_cosbins], cberrors[m_cosbins];
492 for( int j = 0; j < m_cosbins; ++j ){
493 cbcenters[j] = m_lowercos+0.5*cosstep+j*cosstep;
494 cberrors[j] = 0;
495 }
496
497 // Plot the dE/dx means vs. cos(theta) for validation
498 TGraphErrors gdedx_costh[m_bgbins];
499 for( int i = 0; i < m_bgbins; ++i ){
500 char graphname[100];
501 satbg = m_lowerbg+0.5*bgstep+i*bgstep;
502 sprintf(graphname, "dedx_costh_p_%d",i);
503 gdedx_costh[i] = TGraphErrors(m_cosbins,cbcenters,means[i],cberrors,errors[i]);
504 }
505 TH1F* base = new TH1F("base","dE/dx vs. cos(#theta);cos(#theta);dE/dx",100,0,1.0);
506 base->GetXaxis()->SetTitleOffset(1.5);
507 base->SetMaximum(dedxmax*1.1);
508 base->SetMinimum(dedxmin*0.9);
509 base->SetStats(0);
510
511 // Print the histograms for quality control
512 TCanvas* ctmp6 = new TCanvas("tmp6","tmp6",900,900);
513 base->DrawCopy();
514 for( int i = 0 ; i < m_bgbins; ++i ){
515 gdedx_costh[i].SetMarkerSize(0.8);
516 gdedx_costh[i].SetMarkerColor(50+i);
517 gdedx_costh[i].SetLineColor(50+i);
518 gdedx_costh[i].DrawClone("same");
519 }
520 psname.str(""); psname << "plots/costh_" << particle << "_" << corname << ".eps";
521 ctmp6->SaveAs(psname.str().c_str());
522 delete ctmp6;
523
524 std::cout << "HadronPrep: saving output to " << outfile->GetName() << std::endl;
525
526 // write out the data to file
527 outfile->cd();
528 satTree->Write();
529
530 delete base;
531 for( int i = 0; i < m_bgbins; ++i ){
532 for( int j = 0; j < m_cosbins; ++j ){
533 delete hdedx_costh[i][j];
534 delete hdedx_costh_pub[i][j];
535 delete hchi_costh[i][j];
536 delete hchi_costh_pub[i][j];
537 }
538 }
539 infile->Close();
540}
double mass
sprintf(cut,"kal_costheta0_em>-0.93&&kal_costheta0_em<0.93&&kal_pxy0_em>=0.05+%d*0.1&&kal_pxy0_em<0.15+%d*0.1&&NGch>=2", j, j)
double I2D(double cosTheta, double I, double alpha, double gamma, double delta, double power, double ratio) const
double D2I(double cosTheta, double D, double alpha, double gamma, double delta, double power, double ratio) const
void setParameters(double par[])
void setParameters(std::string infile)
double sigmaPrediction(double dedx, double nhit, double sin)
float bg

Referenced by HadronInterface::PrepareSample().

◆ bgFits()

void HadronPrep::bgFits ( TString  particle,
TFile *  outfile,
bool  correct,
std::string  paramfile 
)

Definition at line 544 of file HadronPrep.cc.

544 {
545
546 // supress TCanvas::Print messages
547 gErrorIgnoreLevel = kWarning;
548
549 m_gpar.setParameters(paramfile);
550
551 double mass = 0.0;
552 if( particle == "pion" ) mass = Widget::mpion;
553 else if( particle == "kaon" ) mass = Widget::mkaon;
554 else if( particle == "proton" ) mass = Widget::mproton;
555 else if( particle == "muon" ) mass = Widget::mmuon;
556 else if( particle == "electron" ) mass = Widget::melectron;
557 if( mass == 0.0 ) exit(1);
558
559 TFile* infile = new TFile(m_filename);
560 TTree* hadron = (TTree*)infile->Get("track");
561
562 std::cout << "HadronPrep: reading in file " << m_filename << std::endl;
563 std::cout << "\t beta-gamma range: " << m_lowerbg << " to " << m_upperbg << std::endl;
564
565 // --------------------------------------------------
566 // INITIALIZE CONTAINERS
567 // --------------------------------------------------
568
569 double dedxpub; // dE/dx without electron saturation correction
570 double dedx; // dE/dx with electron saturation correction
571 double p; // track momentum
572 double bg; // track beta-gamma
573 double costh; // cosine of track polar angle
574 double db; // the nearest distance to the IP in the xy plane
575 double dz; // the nearest distance to the IP in the z plane
576 double chiPi; // PID chi value
577 double eop; // energy over momentum in the calorimeter
578
579 // Belle II variables
580 int b2nhit; // number of hits on this track
581
582 // BES III variables
583 double b3nhit; // number of hits on this track
584
585 hadron->SetBranchAddress("dedx", &dedxpub);
586 hadron->SetBranchAddress("dedxsat", &dedx);
587 hadron->SetBranchAddress("pF", &p);
588 hadron->SetBranchAddress("costh", &costh);
589 hadron->SetBranchAddress("db", &db);
590 hadron->SetBranchAddress("dz", &dz);
591 hadron->SetBranchAddress("chiPi", &chiPi);
592 hadron->SetBranchAddress("eopst", &eop);
593
594 if( m_type == 0 )
595 hadron->SetBranchAddress("numGoodHits", &b3nhit);
596 else if( m_type == 1 )
597 hadron->SetBranchAddress("lNHitsUsed", &b2nhit);
598 // hadron->SetBranchAddress("numGoodLayerHits", &b2nhit);
599
600 double bgstep = (m_upperbg-m_lowerbg)/m_bgbins;
601
602 // Create the histograms to be fit (before correction)
603 TH1F* hdedx_bg[m_bgbins];
604 TH1F* hdedx_bg_pub[m_bgbins];
605 TH1F* hchi_bg[m_bgbins];
606 TH1F* hchi_bg_pub[m_bgbins];
607 TH1F* hsigma_bg[m_bgbins];
608
609 // initialize the histograms
610 for( int i = 0; i < m_bgbins; ++i ){
611 char histname[100], histname2[100], histname3[100];
612 char histname4[100], histname5[100], histname6[100];
613 sprintf(histname, "dedx_bg_%d",i);
614 sprintf(histname2, "chi_bg_%d",i);
615 sprintf(histname3, "chipub_bg_%d",i);
616 sprintf(histname4, "dedxpub_bg_%d",i);
617 sprintf(histname5, "dedxnew_bg_%d",i);
618 sprintf(histname6, "sigma_bg_%d",i);
619
620 if( particle == "electron" ){
621 hdedx_bg[i] = new TH1F(histname,histname,200,0,2);
622 hchi_bg[i] = new TH1F(histname2,histname2,200,-2,2);
623 hchi_bg_pub[i] = new TH1F(histname3,histname3,200,-5,5);
624 hdedx_bg_pub[i] = new TH1F(histname4,histname4,200,0,2);
625 }
626 else if( particle == "proton" ){
627 if( i < 5 ){
628 hdedx_bg[i] = new TH1F(histname,histname,200,0,6);
629 hchi_bg[i] = new TH1F(histname2,histname2,200,-30,30);
630 hchi_bg_pub[i] = new TH1F(histname3,histname3,200,0,40);
631 hdedx_bg_pub[i] = new TH1F(histname4,histname4,200,0,6);
632 }
633 else if( i < 9 ){
634 hdedx_bg[i] = new TH1F(histname,histname,200,0,4);
635 hchi_bg[i] = new TH1F(histname2,histname2,200,-5,5);
636 hchi_bg_pub[i] = new TH1F(histname3,histname3,200,-20,20);
637 hdedx_bg_pub[i] = new TH1F(histname4,histname4,200,0,4);
638 }
639 else{
640 hdedx_bg[i] = new TH1F(histname,histname,200,0,2);
641 hchi_bg[i] = new TH1F(histname2,histname2,200,-5,5);
642 hchi_bg_pub[i] = new TH1F(histname3,histname3,200,-5,5);
643 hdedx_bg_pub[i] = new TH1F(histname4,histname4,200,0,2);
644 }
645 }
646 else if( i < 2 ){
647 hdedx_bg[i] = new TH1F(histname,histname,200,0,4);
648 hchi_bg[i] = new TH1F(histname2,histname2,200,-5,5);
649 hchi_bg_pub[i] = new TH1F(histname3,histname3,200,-20,20);
650 hdedx_bg_pub[i] = new TH1F(histname4,histname4,200,0,4);
651 }
652 else{
653 hdedx_bg[i] = new TH1F(histname,histname,200,0,2);
654 hchi_bg[i] = new TH1F(histname2,histname2,200,-5,5);
655 hchi_bg_pub[i] = new TH1F(histname3,histname3,100,-5,5);
656 hdedx_bg_pub[i] = new TH1F(histname4,histname4,200,0,2);
657 }
658 hsigma_bg[i] = new TH1F(histname6,histname6,100,-3,3);
659 }
660
661 // create some containers to calculate averages
662 double sumcos[m_bgbins];
663 double sumsin[m_bgbins];
664 double sumbg[m_bgbins];
665 double sumressq[m_bgbins];
666 int sumsize[m_bgbins];
667 for( int i = 0; i < m_bgbins; ++i ){
668 sumcos[i] = 0;
669 sumsin[i] = 0;
670 sumbg[i] = 0;
671 sumressq[i] = 0;
672 sumsize[i] = 0;
673 }
674
675 // create some containers for means and errors
676 double means[m_bgbins];
677 double errors[m_bgbins];
678 double widths[m_bgbins];
679 for( int i = 0; i < m_bgbins; ++i ){
680 means[i] = 0;
681 errors[i] = 0;
682 widths[i] = 0;
683 }
684
685 // create some containers for checking the residual saturation vs. cos(theta)
686 const int cosbins = 20;
687 const double cosstep = 2.0 / cosbins;
688 double cosArray[cosbins], cosArrayErr[cosbins];
689 for( int i = 0; i < cosbins; ++i ){
690 cosArray[i] = -1 + (i*cosstep + cosstep/2.0);
691 cosArrayErr[i] = 0.0;
692 }
693
694 TH1F* hchi_costh_all[2][cosbins];
695 TH1F* hchi_costh_0[2][cosbins];
696 TH1F* hchi_costh_1[2][cosbins];
697 TH1F* hchi_costh_2[2][cosbins];
698
699 for( int i = 0; i < cosbins; ++i ){
700 char histname[100], histname0[100], histname1[100], histname2[100];
701 sprintf(histname, "chi_costh_pos_%d",i);
702 sprintf(histname0, "chi_costh0_pos_%d",i);
703 sprintf(histname1, "chi_costh1_pos_%d",i);
704 sprintf(histname2, "chi_costh2_pos_%d",i);
705
706 hchi_costh_all[0][i] = new TH1F(histname,histname,100,-5,5);
707 hchi_costh_0[0][i] = new TH1F(histname0,histname0,100,-5,5);
708 hchi_costh_1[0][i] = new TH1F(histname1,histname1,100,-5,5);
709 hchi_costh_2[0][i] = new TH1F(histname2,histname2,100,-5,5);
710
711 sprintf(histname, "chi_costh_neg_%d",i);
712 sprintf(histname0, "chi_costh0_neg_%d",i);
713 sprintf(histname1, "chi_costh1_neg_%d",i);
714 sprintf(histname2, "chi_costh2_neg_%d",i);
715
716 hchi_costh_all[1][i] = new TH1F(histname,histname,100,-5,5);
717 hchi_costh_0[1][i] = new TH1F(histname0,histname0,100,-5,5);
718 hchi_costh_1[1][i] = new TH1F(histname1,histname1,100,-5,5);
719 hchi_costh_2[1][i] = new TH1F(histname2,histname2,100,-5,5);
720 }
721
722 // get the hadron saturation parameters
723 // if the parameters do not exist, use the values in the default constructor
724 m_hadsat.setParameters("sat-pars.fit.txt");
725
726 // --------------------------------------------------
727 // LOOP OVER EVENTS AND FILL CONTAINERS
728 // --------------------------------------------------
729
730 // Fill the histograms to be fitted
731 for( unsigned int index = 0; index < hadron->GetEntries(); ++index ){
732 hadron->GetEvent(index);
733
734 int charge = (p < 0)? 1 : 0;
735 bg = fabs(p)/mass;
736
737 int nhit;
738 if( m_type == 0 )
739 nhit = std::floor(b3nhit);
740 else if( m_type == 1 )
741 nhit = b2nhit;
742
743 // clean up bad events and restrict the momentum range
744 if( nhit < 0 || nhit > 100 || dedx <= 0 || costh != costh ||
745 bg <= m_lowerbg || bg >= m_upperbg )
746 continue;
747
748 // apply an E/p cut for pions
749 if( particle == "pion" && eop > 0.75 ) continue;
750
751 // use loose dE/dx restrictions to remove contaminations
752 if( particle == "proton" && (dedxpub < 0 || dedxpub > 100 || dedxpub < 0.85/fabs(p)) )
753 continue;
754 if( particle == "kaon" && dedxpub < 0.4/fabs(p) )
755 continue;
756
757 int bgBin = (int)((bg-m_lowerbg)/(m_upperbg-m_lowerbg) * m_bgbins);
758
759 double dedx_pre = dedx;
760 double dedx_new = dedx_pre;
761 if( !m_mcFlag ) dedx_new = m_hadsat.D2I(costh,m_hadsat.I2D(costh,1.0)*dedx);
762 double dedx_cur = m_gpar.dedxPrediction(bg);
763 double dedx_res = m_gpar.sigmaPrediction(dedx_cur,nhit,sqrt(1-costh*costh));
764
765 double chi_new = (dedx_new-dedx_cur)/dedx_res;
766 if( particle == "electron" ) chi_new = (dedx_new-1)/dedx_res;
767 double res_cor = m_gpar.resPrediction(nhit,sqrt(1-costh*costh));
768 int i = (int) ( (fabs(bg)-m_lowerbg)/bgstep );
769 hsigma_bg[i]->Fill((dedx_new-dedx_cur)/res_cor);
770
771 if( correct ) hdedx_bg[bgBin]->Fill(dedx_new);
772 else hdedx_bg[bgBin]->Fill(dedx_pre);
773 hdedx_bg_pub[bgBin]->Fill(dedxpub);
774 if( correct ) hchi_bg[bgBin]->Fill(chi_new);
775 hchi_bg_pub[bgBin]->Fill(chiPi);
776
777 sumcos[bgBin] += costh;
778 sumsin[bgBin] += sqrt(1-costh*costh);
779 sumbg[bgBin] += bg;
780 sumressq[bgBin] += pow(dedx_res,2);
781 sumsize[bgBin] += 1;
782
783 // make histograms of dE/dx vs. cos(theta) for validation
784 int icos = (int)((costh+1)/cosstep);
785 hchi_costh_all[charge][icos]->Fill(chi_new);
786 if( bgBin < int(m_bgbins/3) )
787 hchi_costh_0[charge][icos]->Fill(chi_new);
788 else if( bgBin < 2*int(m_bgbins/3) )
789 hchi_costh_1[charge][icos]->Fill(chi_new);
790 else
791 hchi_costh_2[charge][icos]->Fill(chi_new);
792
793 }// end of event loop
794
795 // --------------------------------------------------
796 // FIT IN BINS OF BETA-GAMMA
797 // --------------------------------------------------
798
799 // fit the histograms with Gaussian functions
800 // and extract the means and errors
801 TTree* satTree = new TTree(particle,"dE/dx means and errors");
802
803 double satbg; // beta-gamma value for this bin
804 double satcosth; // cos(theta) value for this bin
805 double satdedx; // mean dE/dx value for this bin
806 double saterror; // error on ^
807 double satbg_avg; // average beta-gamma value for this sample
808 double satcosth_avg; // average cos(theta) value for this sample
809 double satsinth_avg; // average sin(theta) value for this sample
810 double satdedxres_avg; // average dE/dx error squared for this sample
811 double satpubdedx; // mean "public" dE/dx value for this bin
812 double satpuberror; // error on ^
813 double satpubwidth; // width of ^ distribution
814 double satchi; // mean chi value for this bin
815 double satchierr; // error on ^
816 double satchiwidth; // width of ^ distribution
817 double satchipub; // mean "public" chi value for this bin
818 double satchipuberr; // error on ^
819 double satchipubwidth; // width of ^ distribution
820 double ratio; // ratio of the predicted mean to that of the average
821
822 satTree->Branch("bg",&satbg,"bg/D");
823 satTree->Branch("costh",&satcosth,"costh/D");
824 satTree->Branch("dedx",&satdedx,"dedx/D");
825 satTree->Branch("error",&saterror,"error/D");
826 satTree->Branch("bg_avg",&satbg_avg,"bg_avg/D");
827 satTree->Branch("costh_avg",&satcosth_avg,"costh_avg/D");
828 satTree->Branch("sinth_avg",&satsinth_avg,"sinth_avg/D");
829 satTree->Branch("dedxres_avg",&satdedxres_avg,"dedxres_avg/D");
830 satTree->Branch("dedx_pub",&satpubdedx,"dedx_pub/D");
831 satTree->Branch("dedxerr_pub",&satpuberror,"dedxerr_pub/D");
832 satTree->Branch("chi",&satchi,"chi/D");
833 satTree->Branch("chi_pub",&satchipub,"chi_pub/D");
834 satTree->Branch("sigma",&satchiwidth,"sigma/D");
835 satTree->Branch("sigma_pub",&satchipubwidth,"sigma_pub/D");
836 satTree->Branch("ratio",&ratio,"ratio/D");
837
838 // Fit the histograms
839 for( int i = 0; i < m_bgbins; ++i ){
840
841 // fill some details for this bin
842 satbg = m_lowerbg+0.5*bgstep+i*bgstep;
843
844 satbg_avg = sumbg[i]/sumsize[i];
845 satcosth_avg = sumcos[i]/sumsize[i];
846 satsinth_avg = sumsin[i]/sumsize[i];
847 // satdedxres_avg = sumressq[i]/sumsize[i];
848
849 hsigma_bg[i]->Fit("gaus","ql");
850 satdedxres_avg = hsigma_bg[i]->GetFunction("gaus")->GetParameter(2);
851
852 int fs;
853
854 // fit the dE/dx distribution in bins of beta-gamma
855 fs = hdedx_bg[i]->Fit("gaus","ql");
856 if( fs != 0 ) std::cout << "\t\t" <<"MEAN FIT STATUS " << fs << std::endl;
857 double mean = hdedx_bg[i]->GetFunction("gaus")->GetParameter(1);
858 double width = hdedx_bg[i]->GetFunction("gaus")->GetParameter(2);
859 fs = hdedx_bg[i]->Fit("gaus","ql","",mean-2.5*width,mean+2.5*width);
860 if( fs != 0 ) std::cout << "\t\t" <<"MEAN FIT STATUS " << fs << std::endl;
861
862 satdedx = hdedx_bg[i]->GetFunction("gaus")->GetParameter(1);
863 saterror = hdedx_bg[i]->GetFunction("gaus")->GetParError(1);
864 means[i] = satdedx;
865 errors[i] = saterror;
866 widths[i] = hdedx_bg[i]->GetFunction("gaus")->GetParameter(2);
867
868
869 // fit the dE/dx distribution without correction in bins of beta-gamma
870 fs = hdedx_bg_pub[i]->Fit("gaus","ql");
871 if( fs != 0 ) std::cout << "\t\t" <<"MEAN PUB FIT STATUS " << fs << std::endl;
872 mean = hdedx_bg_pub[i]->GetFunction("gaus")->GetParameter(1);
873 width = hdedx_bg_pub[i]->GetFunction("gaus")->GetParameter(2);
874 fs = hdedx_bg_pub[i]->Fit("gaus","ql","",mean-2.5*width,mean+2.5*width);
875 if( fs != 0 ) std::cout << "\t\t" <<"MEAN PUB FIT STATUS " << fs << std::endl;
876
877 satpubdedx = hdedx_bg_pub[i]->GetFunction("gaus")->GetParameter(1);
878 satpuberror = hdedx_bg_pub[i]->GetFunction("gaus")->GetParError(1);
879 satpubwidth = hdedx_bg_pub[i]->GetFunction("gaus")->GetParameter(2);
880
881
882 // fit the chi distribution
883 fs = hchi_bg[i]->Fit("gaus","ql");
884 if( fs != 0 ) std::cout << "\t\t" <<"CHI FIT STATUS " << fs << std::endl;
885 mean = hchi_bg[i]->GetFunction("gaus")->GetParameter(1);
886 width = hchi_bg[i]->GetFunction("gaus")->GetParameter(2);
887 fs = hchi_bg[i]->Fit("gaus","ql","",mean-2.5*width,mean+2.5*width);
888 if( fs != 0 ) std::cout << "\t\t" <<"CHI FIT STATUS " << fs << std::endl;
889
890 satchi = hchi_bg[i]->GetFunction("gaus")->GetParameter(1);
891 satchierr = hchi_bg[i]->GetFunction("gaus")->GetParError(1);
892 satchiwidth = hchi_bg[i]->GetFunction("gaus")->GetParameter(2);
893
894
895 // fit the chi distribution without correction
896 /*
897 fs = hchi_bg_pub[i]->Fit("gaus","ql");
898 if( fs != 0 ) std::cout << "\t\t" <<"CHI PUB FIT STATUS " << fs << std::endl;
899 mean = hchi_bg_pub[i]->GetFunction("gaus")->GetParameter(1);
900 width = hchi_bg_pub[i]->GetFunction("gaus")->GetParameter(2);
901 fs = hchi_bg_pub[i]->Fit("gaus","ql","",mean-2.5*width,mean+2.5*width);
902 if( fs != 0 ) std::cout << "\t\t" <<"CHI PUB FIT STATUS " << fs << std::endl;
903
904 satchipub = hchi_bg_pub[i]->GetFunction("gaus")->GetParameter(1);
905 satchipuberr = hchi_bg_pub[i]->GetFunction("gaus")->GetParError(1);
906 satchipubwidth = hchi_bg_pub[i]->GetFunction("gaus")->GetParameter(2);
907 */
908
909 // determine the ratio of the predicted mean at a given bg to that of the average
910 ratio = m_gpar.dedxPrediction(satbg_avg)/m_gpar.dedxPrediction(satbg);
911
912 // fill the tree for this bin
913 satTree->Fill();
914 }
915
916 std::string corname("uncorrected");
917 if( correct == true ) corname = "corrected";
918
919 // Print the histograms for quality control
920 TCanvas* ctmp = new TCanvas("tmp","tmp",900,900);
921 ctmp->Divide(3,3);
922 std::stringstream psname; psname << "plots/dedx_" << particle << "_" << corname << ".ps[";
923 ctmp->Print(psname.str().c_str());
924 psname.str(""); psname << "plots/dedx_" << particle << "_" << corname << ".ps";
925 for( int i = 0 ; i < m_bgbins; ++i ){
926 ctmp->cd(i%9+1);
927 hdedx_bg[i]->Draw();
928 if((i+1)%9==0)
929 ctmp->Print(psname.str().c_str());
930 }
931 psname.str(""); psname << "plots/dedx_" << particle << "_" << corname << ".ps]";
932 ctmp->Print(psname.str().c_str());
933 delete ctmp;
934
935 std::cout << "HadronPrep: saving output to " << outfile->GetName() << std::endl;
936
937 // write out the data to file
938 outfile->cd();
939 satTree->Write();
940
941 std::cout << "making validation plots..." << std::endl;
942
943 // --------------------------------------------------
944 // FIT IN BINS OF COS(THETA) FOR VALIDATION
945 // --------------------------------------------------
946
947 double chicos[2][cosbins], sigmacos[2][cosbins];
948 double chicoserr[2][cosbins], sigmacoserr[2][cosbins];
949
950 double chicos0[2][cosbins], sigmacos0[2][cosbins];
951 double chicos0err[2][cosbins], sigmacos0err[2][cosbins];
952
953 double chicos1[2][cosbins], sigmacos1[2][cosbins];
954 double chicos1err[2][cosbins], sigmacos1err[2][cosbins];
955
956 double chicos2[2][cosbins], sigmacos2[2][cosbins];
957 double chicos2err[2][cosbins], sigmacos2err[2][cosbins];
958
959 for( int c = 0; c < 2; ++c ){
960 for( int i = 0; i < cosbins; ++i ){
961 if( hchi_costh_all[c][i]->Integral(1,100) == 0 ) continue;
962 hchi_costh_all[c][i]->Fit("gaus","ql");
963 chicos[c][i] = hchi_costh_all[c][i]->GetFunction("gaus")->GetParameter(1);
964 chicoserr[c][i] = hchi_costh_all[c][i]->GetFunction("gaus")->GetParError(1);
965 sigmacos[c][i] = hchi_costh_all[c][i]->GetFunction("gaus")->GetParameter(2);
966 sigmacoserr[c][i] = hchi_costh_all[c][i]->GetFunction("gaus")->GetParError(2);
967 }
968 for( int i = 0; i < cosbins; ++i ){
969 if( hchi_costh_0[c][i]->Integral(1,100) == 0 ) continue;
970 hchi_costh_0[c][i]->Fit("gaus","ql");
971 chicos0[c][i] = hchi_costh_0[c][i]->GetFunction("gaus")->GetParameter(1);
972 chicos0err[c][i] = hchi_costh_0[c][i]->GetFunction("gaus")->GetParError(1);
973 sigmacos0[c][i] = hchi_costh_0[c][i]->GetFunction("gaus")->GetParameter(2);
974 sigmacos0err[c][i] = hchi_costh_0[c][i]->GetFunction("gaus")->GetParError(2);
975 }
976 for( int i = 0; i < cosbins; ++i ){
977 if( hchi_costh_1[c][i]->Integral(1,100) == 0 ) continue;
978 hchi_costh_1[c][i]->Fit("gaus","ql");
979 chicos1[c][i] = hchi_costh_1[c][i]->GetFunction("gaus")->GetParameter(1);
980 chicos1err[c][i] = hchi_costh_1[c][i]->GetFunction("gaus")->GetParError(1);
981 sigmacos1[c][i] = hchi_costh_1[c][i]->GetFunction("gaus")->GetParameter(2);
982 sigmacos1err[c][i] = hchi_costh_1[c][i]->GetFunction("gaus")->GetParError(2);
983 }
984 for( int i = 0; i < cosbins; ++i ){
985 if( hchi_costh_2[c][i]->Integral(1,100) == 0 ) continue;
986 hchi_costh_2[c][i]->Fit("gaus","ql");
987 chicos2[c][i] = hchi_costh_2[c][i]->GetFunction("gaus")->GetParameter(1);
988 chicos2err[c][i] = hchi_costh_2[c][i]->GetFunction("gaus")->GetParError(1);
989 sigmacos2[c][i] = hchi_costh_2[c][i]->GetFunction("gaus")->GetParameter(2);
990 sigmacos2err[c][i] = hchi_costh_2[c][i]->GetFunction("gaus")->GetParError(2);
991 }
992 }
993
994 // Print the histograms for quality control
995 TCanvas* ctmp2 = new TCanvas("tmp2","tmp2",900,900);
996 ctmp2->Divide(3,3);
997 psname.str(""); psname << "plots/chivscos_fits_" << particle << ".ps[";
998 ctmp2->Print(psname.str().c_str());
999 psname.str(""); psname << "plots/chivscos_fits_" << particle << ".ps";
1000 for( int i = 0 ; i < cosbins; ++i ){
1001 ctmp2->cd(i%9+1);
1002 hchi_costh_all[0][i]->Draw();
1003 hchi_costh_all[1][i]->SetMarkerColor(kRed);
1004 hchi_costh_all[1][i]->Draw("same");
1005 if((i+1)%9==0)
1006 ctmp2->Print(psname.str().c_str());
1007 }
1008 psname.str(""); psname << "plots/chivscos_fits_" << particle << ".ps]";
1009 ctmp2->Print(psname.str().c_str());
1010 delete ctmp2;
1011
1012 TGraphErrors* grchicos = new TGraphErrors(cosbins,cosArray,chicos[0],cosArrayErr,chicoserr[0]);
1013 TGraphErrors* grchicos0 = new TGraphErrors(cosbins,cosArray,chicos0[0],cosArrayErr,chicos0err[0]);
1014 TGraphErrors* grchicos1 = new TGraphErrors(cosbins,cosArray,chicos1[0],cosArrayErr,chicos1err[0]);
1015 TGraphErrors* grchicos2 = new TGraphErrors(cosbins,cosArray,chicos2[0],cosArrayErr,chicos2err[0]);
1016
1017 TGraphErrors* grchicosn = new TGraphErrors(cosbins,cosArray,chicos[1],cosArrayErr,chicoserr[1]);
1018 TGraphErrors* grchicos0n = new TGraphErrors(cosbins,cosArray,chicos0[1],cosArrayErr,chicos0err[1]);
1019 TGraphErrors* grchicos1n = new TGraphErrors(cosbins,cosArray,chicos1[1],cosArrayErr,chicos1err[1]);
1020 TGraphErrors* grchicos2n = new TGraphErrors(cosbins,cosArray,chicos2[1],cosArrayErr,chicos2err[1]);
1021
1022 TGraphErrors* grsigmacos = new TGraphErrors(cosbins,cosArray,sigmacos[0],cosArrayErr,sigmacoserr[0]);
1023 TGraphErrors* grsigmacos0 = new TGraphErrors(cosbins,cosArray,sigmacos0[0],cosArrayErr,sigmacos0err[0]);
1024 TGraphErrors* grsigmacos1 = new TGraphErrors(cosbins,cosArray,sigmacos1[0],cosArrayErr,sigmacos1err[0]);
1025 TGraphErrors* grsigmacos2 = new TGraphErrors(cosbins,cosArray,sigmacos2[0],cosArrayErr,sigmacos2err[0]);
1026
1027 TGraphErrors* grsigmacosn = new TGraphErrors(cosbins,cosArray,sigmacos[1],cosArrayErr,sigmacoserr[1]);
1028 TGraphErrors* grsigmacos0n = new TGraphErrors(cosbins,cosArray,sigmacos0[1],cosArrayErr,sigmacos0err[1]);
1029 TGraphErrors* grsigmacos1n = new TGraphErrors(cosbins,cosArray,sigmacos1[1],cosArrayErr,sigmacos1err[1]);
1030 TGraphErrors* grsigmacos2n = new TGraphErrors(cosbins,cosArray,sigmacos2[1],cosArrayErr,sigmacos2err[1]);
1031
1032 TLine* line0 = new TLine(-1,0,1,0);
1033 line0->SetLineStyle(kDashed);
1034 line0->SetLineColor(kRed);
1035 TLine* line1 = new TLine(-1,1,1,1);
1036 line1->SetLineStyle(kDashed);
1037 line1->SetLineColor(kRed);
1038
1039 TString ptype("");
1040 if( particle == "pion" ) ptype += "#pi";
1041 else if( particle == "kaon" ) ptype += "K";
1042 else if( particle == "proton" ) ptype += "p";
1043 else if( particle == "muon" ) ptype += "#mu";
1044 else if( particle == "electron" ) ptype += "e";
1045
1046 TLegend* lchi = new TLegend(0.6,0.75,0.8,0.85);
1047 lchi->SetBorderSize(0);
1048 lchi->SetFillColor(0);
1049 lchi->AddEntry(grchicos,ptype+"^{+}","p");
1050 lchi->AddEntry(grchicosn,ptype+"^{-}","p");
1051 TCanvas* cchi = new TCanvas("cchi","cchi",700,600);
1052
1053 FormatGraph(grchicos,0);
1054 FormatGraph(grchicosn,1);
1055 grchicos->Draw("AP");
1056 grchicosn->Draw("P,same");
1057 line0->Draw("same");
1058 lchi->Draw("same");
1059 cchi->SaveAs("plots/chiall"+particle+".eps");
1060
1061 FormatGraph(grchicos0,0);
1062 FormatGraph(grchicos0n,1);
1063 grchicos0->Draw("AP");
1064 grchicos0n->Draw("P,same");
1065 line0->Draw("same");
1066 lchi->Draw("same");
1067 cchi->SaveAs("plots/chi0"+particle+".eps");
1068
1069 FormatGraph(grchicos1,0);
1070 FormatGraph(grchicos1n,1);
1071 grchicos1->Draw("AP");
1072 grchicos1n->Draw("P,same");
1073 line0->Draw("same");
1074 lchi->Draw("same");
1075 cchi->SaveAs("plots/chi1"+particle+".eps");
1076
1077 FormatGraph(grchicos2,0);
1078 FormatGraph(grchicos2n,1);
1079 grchicos2->Draw("AP");
1080 grchicos2n->Draw("P,same");
1081 line0->Draw("same");
1082 lchi->Draw("same");
1083 cchi->SaveAs("plots/chi2"+particle+".eps");
1084
1085 FormatGraph(grsigmacos,2);
1086 FormatGraph(grsigmacosn,1);
1087 grsigmacos->Draw("AP");
1088 grsigmacosn->Draw("P,same");
1089 line1->Draw("same");
1090 lchi->Draw("same");
1091 cchi->SaveAs("plots/sigmaall"+particle+".eps");
1092
1093 FormatGraph(grsigmacos0,2);
1094 FormatGraph(grsigmacos0n,1);
1095 grsigmacos0->Draw("AP");
1096 grsigmacos0n->Draw("P,same");
1097 line1->Draw("same");
1098 lchi->Draw("same");
1099 cchi->SaveAs("plots/sigma0"+particle+".eps");
1100
1101 FormatGraph(grsigmacos1,2);
1102 FormatGraph(grsigmacos1n,1);
1103 grsigmacos1->Draw("AP");
1104 grsigmacos1n->Draw("P,same");
1105 line1->Draw("same");
1106 lchi->Draw("same");
1107 cchi->SaveAs("plots/sigma1"+particle+".eps");
1108
1109 FormatGraph(grsigmacos2,2);
1110 FormatGraph(grsigmacos2n,1);
1111 grsigmacos2->Draw("AP");
1112 grsigmacos2n->Draw("P,same");
1113 line1->Draw("same");
1114 lchi->Draw("same");
1115 cchi->SaveAs("plots/sigma2"+particle+".eps");
1116
1117 for( int i = 0; i < 2; ++i ){
1118 for( int j = 0; j < cosbins; ++j ){
1119 delete hchi_costh_all[i][j];
1120 delete hchi_costh_0[i][j];
1121 delete hchi_costh_1[i][j];
1122 delete hchi_costh_2[i][j];
1123 }
1124 }
1125
1126 delete grchicos;
1127 delete grchicos0;
1128 delete grchicos1;
1129 delete grchicos2;
1130
1131 delete grchicosn;
1132 delete grchicos0n;
1133 delete grchicos1n;
1134 delete grchicos2n;
1135
1136 delete grsigmacos;
1137 delete grsigmacos0;
1138 delete grsigmacos1;
1139 delete grsigmacos2;
1140
1141 delete grsigmacosn;
1142 delete grsigmacos0n;
1143 delete grsigmacos1n;
1144 delete grsigmacos2n;
1145
1146 delete line0;
1147 delete line1;
1148
1149 delete lchi;
1150 delete cchi;
1151}
curve Fill()
string::const_iterator ptype
Definition: EvtMTree.hh:19
void FormatGraph(TGraphErrors *gr, int flag)
Definition: HadronPrep.cc:28
double resPrediction(double nhit, double sin)
float charge

Referenced by HadronInterface::PrepareResults().

◆ FormatGraph()

void HadronPrep::FormatGraph ( TGraphErrors *  gr,
int  flag 
)

Definition at line 28 of file HadronPrep.cc.

28 {
29 if( flag == 0 ){
30 gr->SetTitle(";cos(#theta);#chi_{mean}");
31 gr->SetMarkerStyle(24);
32 gr->SetMarkerColor(2);
33 gr->SetMarkerSize(.7);
34 gr->SetMaximum(1);
35 gr->SetMinimum(-1);
36 gr->GetXaxis()->SetRangeUser(-1,1);
37 }
38 else if( flag == 1 ){
39 gr->SetMarkerStyle(22);
40 gr->SetMarkerColor(9);
41 gr->SetMarkerSize(.7);
42 }
43 else if( flag == 2 ){
44 gr->SetTitle(";cos(#theta);#sigma");
45 gr->SetMarkerStyle(24);
46 gr->SetMarkerColor(2);
47 gr->SetMarkerSize(.7);
48 gr->SetMaximum(2);
49 gr->SetMinimum(0);
50 gr->GetXaxis()->SetRangeUser(-1,1);
51 }
52}
TGraph * gr

Referenced by bgFits().


The documentation for this class was generated from the following files: