BOSS 7.1.0
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KalFitTrack.cxx
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1
2//#include "TrackUtil/Helix.h"
10#include "GaudiKernel/Bootstrap.h"
11#include "CLHEP/Matrix/Vector.h"
12#include "CLHEP/Matrix/Matrix.h"
13#include "CLHEP/Matrix/SymMatrix.h"
14#include "CLHEP/Vector/ThreeVector.h"
15#include "CLHEP/Units/PhysicalConstants.h"
16#include "Math/Point3Dfwd.h"
17#include "Math/Point3D.h"
18#include "Math/Vector3D.h"
19
20using namespace ROOT::Math;
21
22using namespace KalmanFit;
23
24using namespace CLHEP;
25
26
27// for debug purpose .
30int KalFitTrack::numf_ = 0;
32double KalFitTrack::Bznom_ = 10;
36// Mdc factors :
39double KalFitTrack::chi2_hitf_ = 1000;
40double KalFitTrack::chi2_hits_ = 1000;
42//double KalFitTrack::chi2_hitf_ = DBL_MAX;
43int KalFitTrack::lead_ = 2;
44int KalFitTrack::back_ = 1;
45// attention resolflag !!!
48// chi2 cut set :
50//int KalFitTrack::LR_ = 0;
51int KalFitTrack::LR_ = 1;
52
53
54double KalFitTrack::dchi2cutf_anal[43] = {0.};
55double KalFitTrack::dchi2cuts_anal[43] = {0.};
56double KalFitTrack::dchi2cutf_calib[43] = {0.};
57double KalFitTrack::dchi2cuts_calib[43] = {0.};
58
59
60///
62
63
64const double KalFitTrack::MASS[NMASS] = { 0.000510999,
65 0.105658,
66 0.139568,
67 0.493677,
68 0.938272 };
69const double
70M_PI2 = 2. * M_PI;
71
72const double
73M_PI4 = 4. * M_PI;
74
75const double
76M_PI8 = 8. * M_PI;
77
78
79
80// constructor
82 const HepVector& a,
83 const HepSymMatrix& Ea,
84 unsigned int m, double chisq, unsigned int nhits)
85: Helix(pivot, a, Ea), type_(0), insist_(0), chiSq_(0),
86 nchits_(0), nster_(0), ncath_(0),
87 ndf_back_(0), chiSq_back_(0), pathip_(0),
88 path_rd_(0), path_ab_(0), tof_(0), dchi2_max_(0), r_max_(0),
89 tof_kaon_(0), tof_proton_(0), pat1_(0), pat2_(0), layer_prec_(0),
90 trasan_id_(0), nhit_r_(0), nhit_z_(0),pathSM_(0),tof2_(0)
91{
92 memset(PathL_, 0, sizeof(PathL_));
93 l_mass_ = m;
94 if (m < NMASS) mass_ = MASS[m];
95 else mass_ = MASS[2];
96 r0_ = fabs(center().perp() - fabs(radius()));
97 //bFieldZ(Bznom_);
98 Bznom_=bFieldZ(); // 2012-09-13 wangll
100}
101
102// destructor
104{
105 // delete all objects
106
107}
108
110{
111 pivot_last_ = pivot();
112 a_last_ = a();
113 Ea_last_ = Ea();
114}
115
117{
118 pivot_forMdc_ = pivot();
119 a_forMdc_ = a();
120 Ea_forMdc_ = Ea();
121}
122
124{
125 double m_rad = radius();
126 double l = center().perp();
127
128 double cosPhi = (m_rad * m_rad + l * l - r * r) / (2 * m_rad * l);
129
130 if(cosPhi < -1 || cosPhi > 1) return 0;
131
132 double dPhi = center().phi() - acos(cosPhi) - phi0();
133
134 if(dPhi < -M_PI) dPhi += 2 * M_PI;
135
136 return dPhi;
137}
138
140 double y) const
141{
142 HepPoint3D xc = plane * center();
143 double r = radius();
144 double d = r * r - (y - xc.y()) * (y - xc.y());
145 if(d < 0) return 0;
146
147 double xx = xc.x();
148 if(xx > 0) xx -= sqrt(d);
149 else xx += sqrt(d);
150
151 double l = (plane.inverse() *
152 HepPoint3D(xx, y, 0)).perp();
153
154 return intersect_cylinder(l);
155}
156
158 double x) const
159{
160 HepPoint3D xc = plane * center();
161 double r = radius();
162 double d = r * r - (x - xc.x()) * (x - xc.x());
163 if(d < 0) return 0;
164
165 double yy = xc.y();
166 if(yy > 0) yy -= sqrt(d);
167 else yy += sqrt(d);
168
169 double l = (plane.inverse() *
170 HepPoint3D(x, yy, 0)).perp();
171
172 return intersect_cylinder(l);
173}
174
176{
177 if (tanl() != 0 && radius() != 0)
178 return (pivot().z() + dz() - z) / (radius() * tanl());
179 else return 0;
180}
181
182void KalFitTrack::ms(double path,
183 const KalFitMaterial& material, int index)
184{
185 HepSymMatrix ea = Ea();
186 //cout<<"ms():path "<<path<<endl;
187 //cout<<"ms():ea before: "<<ea<<endl;
188 double k = kappa();
189 double t = tanl();
190 double t2 = t * t;
191 double pt2 = 1 + t2;
192 double k2 = k * k;
193
194 double pmag = 1 / fabs(k) * sqrt(pt2);
195 double dth = material.mcs_angle(mass_, path, pmag);
196 double dth2 = dth * dth;
197 double pt2dth2 = pt2 * dth2;
198
199 ea[1][1] += pt2dth2;
200 ea[2][2] += k2 * t2 * dth2;
201 ea[2][4] += k * t * pt2dth2;
202 ea[4][4] += pt2 * pt2dth2;
203
204 ea[3][3] += dth2 * path * path /3 / (1 + t2);
205 ea[3][4] += dth2 * path/2 * sqrt(1 + t2);
206 ea[3][2] += dth2 * t / sqrt(1 + t2) * k * path/2;
207 ea[0][0] += dth2 * path * path/3;
208 ea[0][1] += dth2 * sqrt(1 + t2) * path/2;
209
210 Ea(ea);
211 //cout<<"ms():ms angle in this: "<<dth<<endl;
212 //cout<<"ms():ea after: "<<Ea()<<endl;
213 if (index < 0) {
214 double x0 = material.X0();
215 if (x0) path_rd_ += path/x0;
216 }
217}
218
219void KalFitTrack::msgasmdc(double path, int index)
220{
221 double k = kappa();
222 double t = tanl();
223 double t2 = t * t;
224 double k2 = k * k;
225
226 double pmag = ( 1 / fabs(k) ) * sqrt(1 + t2);
227 double psq = pmag*pmag;
228 /*
229 double Zprims = 3/2*0.076 + 0.580/9.79*4.99*(4.99+1) +
230 0.041/183.85*74*(74+1) + 0.302/26.98 * 13 * (13+1);
231 double chicc = 0.00039612 * sqrt(Zprims * 0.001168);
232 double dth = 2.557 * chicc * sqrt(path * (mass_*mass_ + psq)) / psq;
233 */
234
235 //std::cout<<" mdcGasRadlen: "<<mdcGasRadlen_<<std::endl;
236 double pathx = path/mdcGasRadlen_;
237 double dth = 0.0136* sqrt(pathx * (mass_*mass_ + psq))/psq
238 *(1 + 0.038 * log(pathx));;
239 HepSymMatrix ea = Ea();
240#ifdef YDEBUG
241 cout<<"msgasmdc():path "<<path<<" pathx "<<pathx<<endl;
242 cout<<"msgasmdc():dth "<<dth<<endl;
243 cout<<"msgasmdc():ea before: "<<ea<<endl;
244#endif
245 double dth2 = dth * dth;
246
247 ea[1][1] += (1 + t2) * dth2;
248 ea[2][2] += k2 * t2 * dth2;
249 ea[2][4] += k * t * (1 + t2) * dth2;
250 ea[4][4] += (1 + t2) * (1 + t2) * dth2;
251
252 // additionnal terms (terms proportional to l and l^2)
253
254 ea[3][3] += dth2 * path * path /3 / (1 + t2);
255 ea[3][4] += dth2 * path/2 * sqrt(1 + t2);
256 ea[3][2] += dth2 * t / sqrt(1 + t2) * k * path/2;
257 ea[0][0] += dth2 * path * path/3;
258 ea[0][1] += dth2 * sqrt(1 + t2) * path/2;
259
260 Ea(ea);
261#ifdef YDEBUG
262 cout<<"msgasmdc():ea after: "<<Ea()<<endl;
263#endif
264 if (index < 0) {
265 pathip_ += path;
266 // RMK : put by hand, take care !!
267 double x0 = mdcGasRadlen_; // for the Mdc gas
268 path_rd_ += path/x0;
269 tof(path);
270#ifdef YDEBUG
271 cout<<"ms...pathip..."<<pathip_<<endl;
272#endif
273 }
274}
275
276void KalFitTrack::eloss(double path,
277 const KalFitMaterial& material, int index)
278{
279#ifdef YDEBUG
280 cout<<"eloss():ea before: "<<Ea()<<endl;
281#endif
282 HepVector v_a = a();
283 double v_a_2_2 = v_a[2] * v_a[2];
284 double v_a_4_2 = v_a[4] * v_a[4];
285 double pmag = 1 / fabs(v_a[2]) * sqrt(1 + v_a_4_2);
286 double psq = pmag * pmag;
287 double E = sqrt(mass_ * mass_ + psq);
288 double dE = material.dE(mass_, path, pmag);
289 //std::cout<<" eloss(): dE: "<<dE<<std::endl;//wangll
290
291 if (index > 0)
292 psq += dE * (dE + 2 * sqrt(mass_ * mass_ + psq));
293 else {
294 double dE_max = E - mass_;
295 if( dE<dE_max ) psq += dE * (dE - 2 * sqrt(mass_ * mass_ + psq));
296 else psq=-1.0;
297 }
298
299 if (tofall_ && index < 0){
300 // Kaon case :
301 if (p_kaon_ > 0){
302 double psq_kaon = p_kaon_ * p_kaon_;
303 double dE_kaon = material.dE(MASS[3], path, p_kaon_);
304 psq_kaon += dE_kaon * (dE_kaon -
305 2 * sqrt(MASS[3] * MASS[3] + psq_kaon));
306 if (psq_kaon < 0) psq_kaon = 0;
307 p_kaon_ = sqrt(psq_kaon);
308 }
309 // Proton case :
310 if (p_proton_ > 0){
311 double psq_proton = p_proton_ * p_proton_;
312 double dE_proton = material.dE(MASS[4], path, p_proton_);
313 psq_proton += dE_proton * (dE_proton -
314 2 * sqrt(MASS[4] * MASS[4] + psq_proton));
315 if (psq_proton < 0) psq_proton = 0;
316 p_proton_ = sqrt(psq_proton);
317 }
318 }
319
320 double dpt;
321 //cout<<"eloss(): psq = "<<psq<<endl;//wangll
322 if(psq < 0) dpt = 9999;
323 else dpt = v_a[2] * pmag / sqrt(psq);
324 //cout<<"eloss():k: "<<v_a[2]<<" k' "<<dpt<<endl;//wangll
325#ifdef YDEBUG
326 cout<<"eloss():k: "<<v_a[2]<<" k' "<<dpt<<endl;
327#endif
328 // attempt to take account of energy loss for error matrix
329
330 HepSymMatrix ea = Ea();
331 double r_E_prim = (E + dE)/E;
332
333 // 1/ Straggling in the energy loss :
334 if (strag_){
335 double del_E(0);
336 if(l_mass_==0) {
337 del_E = dE*factor_strag_;
338 } else {
339 del_E = material.del_E(mass_, path, pmag);
340 }
341
342 ea[2][2] += (v_a[2] * v_a[2]) * E * E * del_E * del_E / (psq*psq);
343 }
344
345 // Effect of the change of curvature (just variables change):
346 double dpt2 = dpt*dpt;
347 double A = dpt*dpt2/(v_a_2_2*v_a[2])*r_E_prim;
348 double B = v_a[4]/(1+v_a_4_2)*
349 dpt*(1-dpt2/v_a_2_2*r_E_prim);
350
351 double ea_2_0 = A*ea[2][0] + B*ea[4][0];
352 double ea_2_1 = A*ea[2][1] + B*ea[4][1];
353 double ea_2_2 = A*A*ea[2][2] + 2*A*B*ea[2][4] + B*B*ea[4][4];
354 double ea_2_3 = A*ea[2][3] + B*ea[4][3];
355 double ea_2_4 = A*ea[2][4] + B*ea[4][4];
356
357 v_a[2] = dpt;
358 a(v_a);
359
360 ea[2][0] = ea_2_0;
361 //std::cout<<"ea[2][0] is "<<ea[2][0]<<" ea(3,1) is "<<ea(3,1)<<std::endl;
362 ea[2][1] = ea_2_1;
363 //std::cout<<"ea[2][2] is "<<ea[2][2]<<" ea(3,3) is "<<ea(3,3)<<std::endl;
364 ea[2][2] = ea_2_2;
365 ea[2][3] = ea_2_3;
366 ea[2][4] = ea_2_4;
367
368 Ea(ea);
369 //cout<<"eloss():dE: "<<dE<<endl;
370 //cout<<"eloss():A: "<<A<<" B: "<<B<<endl;
371 //cout<<"eloss():ea after: "<<Ea()<<endl;
372 r0_ = fabs(center().perp() - fabs(radius()));
373}
374
376{
377 unsigned int nhit = HitsMdc_.size();
378 Helix tracktest = *(Helix*)this;
379 int ind = 0;
380 double* Rad = new double[nhit];
381 double* Ypos = new double[nhit];
382 for( unsigned i=0 ; i < nhit; i++ ){
383
384 HepPoint3D fwd(HitsMdc_[i].wire().fwd());
385 HepPoint3D bck(HitsMdc_[i].wire().bck());
386 Hep3Vector wire = (CLHEP::Hep3Vector)fwd -(CLHEP::Hep3Vector)bck;
387
388 // Modification for stereo wires :
389 Helix work = tracktest;
390 work.ignoreErrorMatrix();
391 work.pivot((fwd + bck) * .5);
392 HepPoint3D x0 = (work.x(0).z() - bck.z())
393 / wire.z() * wire + bck;
394
395 tracktest.pivot(x0);
396 Rad[ind] = tracktest.x(0).perp();
397 Ypos[ind] = x0.y();
398 ind++;
399 //cout<<"Ypos: "<<Ypos[ind-1]<<endl;
400 }
401
402 // Reorder...
403 if (index < 0)
404 for(int j, k = nhit - 1; k >= 0; k = j){
405 j = -1;
406 for(int i = 1; i <= k; i++)
407 if(Rad[i - 1] > Rad[i]){
408 j = i - 1;
409 std::swap(Rad[i], Rad[j]);
410 std::swap(HitsMdc_[i], HitsMdc_[j]);
411 }
412 }
413 if (index > 0)
414 for(int j, k = nhit - 1; k >= 0; k = j){
415 j = -1;
416 for(int i = 1; i <= k; i++)
417 if(Rad[i - 1] < Rad[i]){
418 j = i - 1;
419 std::swap(Rad[i], Rad[j]);
420 std::swap(HitsMdc_[i], HitsMdc_[j]);
421 }
422 }
423 if (index == 0)
424 for(int j, k = nhit - 1; k >= 0; k = j){
425 j = -1;
426 for(int i = 1; i <= k; i++)
427 if(Ypos[i - 1] > Ypos[i]){
428 j = i - 1;
429 std::swap(Ypos[i], Ypos[j]);
430 std::swap(HitsMdc_[i], HitsMdc_[j]);
431 }
432 }
433 delete [] Rad;
434 delete [] Ypos;
435}
436
438 for(int it=0; it<HitsMdc().size()-1; it++){
439 if(HitsMdc_[it].wire().layer().layerId() == HitsMdc_[it+1].wire().layer().layerId())
440 {
441 if((kappa()<0)&&(HitsMdc_[it].wire().localId() > HitsMdc_[it+1].wire().localId())){
442 std::swap(HitsMdc_[it], HitsMdc_[it+1]);
443 }
444 if((kappa()>0)&&(HitsMdc_[it].wire().localId() < HitsMdc_[it+1].wire().localId())){
445 std::swap(HitsMdc_[it], HitsMdc_[it+1]);
446 }
447 }
448 }
449}
450
451
453{
454 unsigned int nhit = HitsMdc_.size();
455 int Num[50] = {0};
456 for( unsigned i=0 ; i < nhit; i++ )
457 Num[HitsMdc_[i].wire().layer().layerId()]++;
458 for( unsigned i=0 ; i < nhit; i++ )
459 if (Num[HitsMdc_[i].wire().layer().layerId()]>2)
460 HitsMdc_[i].chi2(-2);
461}
462
463
464double KalFitTrack::smoother_Mdc(KalFitHitMdc& HitMdc, Hep3Vector& meas, KalFitHelixSeg& seg, double& dchi2, int csmflag)
465{
466 //
467 double lr = HitMdc.LR();
468 // For taking the propagation delay into account :
469 int wire_ID = HitMdc.wire().geoID(); // from 0 to 6796
470 int layerid = HitMdc.wire().layer().layerId();
471 double entrangle = HitMdc.rechitptr()->getEntra();
472 if (wire_ID<0 || wire_ID>6796){ //bes
473 std::cout << "KalFitTrack : wire_ID problem : " << wire_ID << std::endl;
474 return 0;
475 }
476
477 double x[3] ={pivot().x(), pivot().y(), pivot().z()};
478 double pmom[3] ={momentum().x(), momentum().y(), momentum().z()};
479
480 double tofest(0);
481 double dd(0.);
482 double phi = fmod(phi0() + M_PI4, M_PI2);
483 double csf0 = cos(phi);
484 double snf0 = (1. - csf0) * (1. + csf0);
485 snf0 = sqrt((snf0 > 0.) ? snf0 : 0.);
486 if(phi > M_PI) snf0 = - snf0;
487
488 if (Tof_correc_) {
489 Hep3Vector ip(0, 0, 0);
490 Helix work = *(Helix*)this;
491 work.ignoreErrorMatrix();
492 work.pivot(ip);
493 double phi_ip = work.phi0();
494 if (fabs(phi - phi_ip) > M_PI) {
495 if (phi > phi_ip) phi -= 2 * M_PI;
496 else phi_ip -= 2 * M_PI;
497 }
498 double t = tanl();
499 double l = fabs(radius() * (phi - phi_ip) * sqrt(1 + t * t));
500 double pmag( sqrt( 1.0 + t*t ) / kappa());
501 double mass_over_p( mass_ / pmag );
502 double beta( 1.0 / sqrt( 1.0 + mass_over_p * mass_over_p ) );
503 tofest = l / ( 29.9792458 * beta );
504 if(csmflag==1 && HitMdc.wire().y()>0.) tofest= -1. * tofest;
505 }
506
507 const HepSymMatrix& ea = Ea();
508 const HepVector& v_a = a();
509
510 HepPoint3D pivot_work = pivot();
511
512 double dchi2R(99999999), dchi2L(99999999);
513
514 HepVector v_H(5, 0);
515 v_H[0] = -csf0 * meas.x() - snf0 * meas.y();
516 v_H[3] = -meas.z();
517 HepMatrix v_HT = v_H.T();
518
519 double estim = (v_HT * v_a)[0];
520 HepVector ea_v_H = ea * v_H;
521 HepMatrix ea_v_HT = (ea_v_H).T();
522 HepVector v_H_T_ea_v_H = v_HT * ea_v_H;
523
524 HepSymMatrix eaNew(5);
525 HepVector aNew(5);
526
527 //double time = HitMdc.tdc();
528 // if (Tof_correc_)
529 // time -= tofest;
530
531 double drifttime = getDriftTime(HitMdc , tofest);
532 //cout<<"drifttime = "<<drifttime<<endl;
533 seg.dt(drifttime);
534 double ddl = getDriftDist(HitMdc, drifttime, 0);
535 double ddr = getDriftDist(HitMdc, drifttime, 1);
536 /*cout<<endl<<" $$$ smoother_Mdc():: "<<endl;//wangll
537 cout<<"pivot = "<<pivot()<<endl;//wangll
538 cout<<"helix = "<<a()<<endl;//wangll
539 cout<<"drifttime = "<<drifttime<<endl;//wangll
540 cout<<"ddl, ddr = "<<ddl<<", "<<ddr<<endl;//wangll
541 */
542 double erddl = getSigma( HitMdc, a()[4], 0, ddl);
543 double erddr = getSigma( HitMdc, a()[4], 1, ddr);
544
545 // double dd = 1.0e-4 * 40.0 * time;
546 double dmeas2[2] = { 0.1*ddl, 0.1*ddr }; //millimeter to centimeter
547 double er_dmeas2[2] = {0. , 0.};
548 if(resolflag_== 1) {
549 er_dmeas2[0] = 0.1*erddl;
550 er_dmeas2[1] = 0.1*erddr;
551 }
552 else if(resolflag_ == 0) {
553 //int layid = HitMdc.wire().layer().layerId();
554 //double sigma = getSigma(layid, dd);
555 //er_dmeas2[0] = er_dmeas2[1] = sigma;
556 }
557
558 // Left hypothesis :
559 if (lr == -1) {
560 double er_dmeasL, dmeasL;
561 if(Tof_correc_) {
562 dmeasL = (-1.0)*dmeas2[0]; // the dmeas&erdmeas calculated by myself
563 er_dmeasL = er_dmeas2[0];
564 } else {
565 dmeasL = (-1.0)*fabs(HitMdc.dist()[0]); // the dmeas&erdmeas calculated by track-finding algorithm
566 er_dmeasL = HitMdc.erdist()[0];
567 }
568
569 double AL = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasL*er_dmeasL);
570 eaNew.assign(ea - ea_v_H * AL * ea_v_HT);
571 double RkL = 1 - (v_H_T_ea_v_H)[0] * AL;
572 if(0. == RkL) RkL = 1.e-4;
573
574 HepVector diffL = ea_v_H * AL * (dmeasL - estim);
575 aNew = v_a + diffL;
576 double sigL = (dmeasL - (v_HT * aNew)[0]);
577 dchi2L = (sigL*sigL) / (RkL * er_dmeasL*er_dmeasL);
578 } else if (lr == 1) {
579 // Right hypothesis :
580
581 double er_dmeasR, dmeasR;
582 if(Tof_correc_) {
583 dmeasR = dmeas2[1];
584 er_dmeasR = er_dmeas2[1];
585 } else {
586 dmeasR = fabs(HitMdc.dist()[1]);
587 er_dmeasR = HitMdc.erdist()[1];
588 }
589
590
591 double AR = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasR*er_dmeasR);
592 eaNew.assign(ea - ea_v_H * AR * ea_v_HT);
593 double RkR = 1 - (v_H_T_ea_v_H)[0] * AR;
594 if(0. == RkR) RkR = 1.e-4;
595
596 HepVector diffR = ea_v_H * AR * (dmeasR - estim);
597 aNew = v_a + diffR;
598 double sigR = (dmeasR- (v_HT * aNew)[0]);
599 dchi2R = (sigR*sigR) / (RkR * er_dmeasR*er_dmeasR);
600 }
601
602 // Update Kalman result :
603#ifdef YDEBUG
604 cout<<"in smoother_Mdc: lr= "<<lr<<" a: "<<v_a<<" a_NEW: "<<aNew<<endl;
605#endif
606 double dchi2_loc(0);
607 if ((dchi2R < dchi2cuts_anal[layerid] && lr == 1) ||
608 (dchi2L < dchi2cuts_anal[layerid] && lr == -1)) {
609 ndf_back_++;
610 int chge(1);
611 if ( !( aNew[2] && fabs(aNew[2]-a()[2]) < 1.0 ) ) chge=0;
612 if (lr == 1) {
613 chiSq_back_ += dchi2R;
614 dchi2_loc = dchi2R;
615 dd = 0.1*ddr;
616 } else if (lr == -1) {
617 chiSq_back_ += dchi2L;
618 dchi2_loc = dchi2L;
619 dd = -0.1*ddl;
620 }
621 if (chge){
622 a(aNew);
623 Ea(eaNew);
624 }
625 }
626 dchi2=dchi2_loc;
627
628 seg.doca_include(fabs((v_HT*a())[0]));
629 seg.doca_exclude(fabs(estim));
630 /// move the pivot of the helixseg to IP(0,0,0)
631 Hep3Vector ip(0, 0, 0);
632 KalFitTrack helixNew1(pivot_work, a(), Ea(), 0, 0, 0);
633 helixNew1.pivot(ip);
634 HepVector a_temp1 = helixNew1.a();
635 HepSymMatrix ea_temp1 = helixNew1.Ea();
636 seg.Ea(ea_temp1);
637 seg.a(a_temp1);
638 seg.Ea_include(ea_temp1);
639 seg.a_include(a_temp1);
640
641 KalFitTrack helixNew2(pivot_work, v_a, ea, 0, 0, 0);
642 helixNew2.pivot(ip);
643 HepVector a_temp2 = helixNew2.a();
644 HepSymMatrix ea_temp2 = helixNew2.Ea();
645 seg.Ea_exclude(ea_temp2);
646 seg.a_exclude(a_temp2);
647
648 seg.tof(tofest);
649 seg.dd(dd);
650
651 return chiSq_back_;
652}
653
654// Smoothing procedure in Mdc cosmic align
655// RMK attention for the case chi2R = chi2L during forward filter !
656double KalFitTrack::smoother_Mdc_csmalign(KalFitHelixSeg& seg, Hep3Vector& meas,int& flg, int csmflag )
657{
658
659
660 HepPoint3D ip(0., 0., 0.);
661 // attention! we should not to decide the left&right in the smoother process,
662 // because we choose the left&right of hits from the filter process.
663
664 KalFitHitMdc* HitMdc = seg.HitMdc();
665 double lr = HitMdc->LR();
666
667 // For taking the propagation delay into account :
668 int layerid = (*HitMdc).wire().layer().layerId();
669 int wire_ID = HitMdc->wire().geoID();
670 double entrangle = HitMdc->rechitptr()->getEntra();
671
672 if (wire_ID<0 || wire_ID>6796){ //bes
673 std::cout << "KalFitTrack : wire_ID problem : " << wire_ID << std::endl;
674 return 0;
675 }
676
677 double x[3] ={pivot().x(), pivot().y(), pivot().z()};
678 double pmom[3] ={momentum().x(), momentum().y(), momentum().z()};
679 double dd(0.);
680 double tofest(0);
681 double phi = fmod(phi0() + M_PI4, M_PI2);
682 double csf0 = cos(phi);
683 double snf0 = (1. - csf0) * (1. + csf0);
684 snf0 = sqrt((snf0 > 0.) ? snf0 : 0.);
685 if(phi > M_PI) snf0 = - snf0;
686
687 if (Tof_correc_) {
688 Hep3Vector ip(0, 0, 0);
689 Helix work = *(Helix*)this;
690 work.ignoreErrorMatrix();
691 work.pivot(ip);
692 double phi_ip = work.phi0();
693 if (fabs(phi - phi_ip) > M_PI) {
694 if (phi > phi_ip) phi -= 2 * M_PI;
695 else phi_ip -= 2 * M_PI;
696 }
697 double t = tanl();
698 double l = fabs(radius() * (phi - phi_ip) * sqrt(1 + t * t));
699 double pmag( sqrt( 1.0 + t*t ) / kappa());
700 double mass_over_p( mass_ / pmag );
701 double beta( 1.0 / sqrt( 1.0 + mass_over_p * mass_over_p ) );
702 tofest = l / ( 29.9792458 * beta );
703 if(csmflag==1 && (*HitMdc).wire().y()>0.) tofest= -1. * tofest;
704 }
705
706 const HepSymMatrix& ea = Ea();
707 const HepVector& v_a = a();
708
709
710 HepPoint3D pivot_work = pivot();
711
712 /*
713 HepVector a_work = a();
714 HepSymMatrix ea_work = Ea();
715
716 KalFitTrack helix_work(pivot_work, a_work, ea_work, 0, 0, 0);
717 helix_work.pivot(ip);
718
719 HepVector a_temp = helix_work.a();
720 HepSymMatrix ea_temp = helix_work.Ea();
721
722 seg.Ea_pre_bwd(ea_temp);
723 seg.a_pre_bwd(a_temp);
724
725 */
726
727 seg.a_pre_bwd(a());
728 seg.Ea_pre_bwd(Ea());
729
730 double dchi2R(99999999), dchi2L(99999999);
731 HepVector v_H(5, 0);
732 v_H[0] = -csf0 * meas.x() - snf0 * meas.y();
733 v_H[3] = -meas.z();
734 HepMatrix v_HT = v_H.T();
735
736 double estim = (v_HT * v_a)[0];
737 HepVector ea_v_H = ea * v_H;
738 HepMatrix ea_v_HT = (ea_v_H).T();
739 HepVector v_H_T_ea_v_H = v_HT * ea_v_H;
740 HepSymMatrix eaNew(5);
741 HepVector aNew(5);
742 double time = (*HitMdc).tdc();
743
744 //seg.dt(time);
745 // if (Tof_correc_)
746 // {
747 // time -= tofest;
748 // seg.dt(time);
749 // }
750 // double dd = 1.0e-4 * 40.0 * time;
751 // seg.dd(dd);
752
753 double drifttime = getDriftTime(*HitMdc , tofest);
754 seg.dt(drifttime);
755 double ddl = getDriftDist(*HitMdc, drifttime, 0 );
756 double ddr = getDriftDist(*HitMdc, drifttime, 1 );
757 double erddl = getSigma( *HitMdc, a()[4], 0, ddl);
758 double erddr = getSigma( *HitMdc, a()[4], 1, ddr);
759
760 double dmeas2[2] = { 0.1*ddl, 0.1*ddr }; // millimeter to centimeter
761 double er_dmeas2[2] = {0., 0.};
762 if(resolflag_ == 1) {
763 er_dmeas2[0] = 0.1*erddl;
764 er_dmeas2[1] = 0.1*erddr;
765 }else if(resolflag_ == 0)
766 {
767 }
768
769 // Left hypothesis :
770 if (lr == -1) {
771 double er_dmeasL, dmeasL;
772 if(Tof_correc_) {
773 dmeasL = (-1.0)*dmeas2[0];
774 er_dmeasL = er_dmeas2[0];
775 } else {
776 dmeasL = (-1.0)*fabs((*HitMdc).dist()[0]);
777 er_dmeasL = (*HitMdc).erdist()[0];
778 }
779
780
781 //if(layerid < 4) er_dmeasL*=2.0;
782
783 double AL = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasL*er_dmeasL);
784 eaNew.assign(ea - ea_v_H * AL * ea_v_HT);
785 double RkL = 1 - (v_H_T_ea_v_H)[0] * AL;
786 if(0. == RkL) RkL = 1.e-4;
787
788 HepVector diffL = ea_v_H * AL * (dmeasL - estim);
789 aNew = v_a + diffL;
790 double sigL = (dmeasL - (v_HT * aNew)[0]);
791 dchi2L = (sigL*sigL) / (RkL * er_dmeasL*er_dmeasL);
792 } else if (lr == 1) {
793 // Right hypothesis :
794
795 double er_dmeasR, dmeasR;
796 if(Tof_correc_) {
797 dmeasR = dmeas2[1];
798 er_dmeasR = er_dmeas2[1];
799 } else {
800 dmeasR = fabs((*HitMdc).dist()[1]);
801 er_dmeasR = (*HitMdc).erdist()[1];
802 }
803
804
805 //if(layerid < 4) er_dmeasR*=2.0;
806
807
808 double AR = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasR*er_dmeasR);
809 eaNew.assign(ea - ea_v_H * AR * ea_v_HT);
810 double RkR = 1 - (v_H_T_ea_v_H)[0] * AR;
811 if(0. == RkR) RkR = 1.e-4;
812
813 HepVector diffR = ea_v_H * AR * (dmeasR - estim);
814 aNew = v_a + diffR;
815 double sigR = (dmeasR- (v_HT * aNew)[0]);
816 dchi2R = (sigR*sigR) / (RkR * er_dmeasR*er_dmeasR);
817 }
818
819 // Update Kalman result :
820#ifdef YDEBUG
821 cout<<"in smoother_Mdc: lr= "<<lr<<" a: "<<v_a<<" a_NEW: "<<aNew<<endl;
822#endif
823 double dchi2_loc(0);
824 if ((dchi2R < dchi2cuts_calib[layerid] && lr == 1) ||
825 (dchi2L < dchi2cuts_calib[layerid] && lr == -1)) {
826
827 ndf_back_++;
828 flg = 1;
829 int chge(1);
830 if (!(aNew[2] && fabs(aNew[2]-a()[2]) < 1.0)) chge = 0;
831 if (lr == 1) {
832 chiSq_back_ += dchi2R;
833 dchi2_loc = dchi2R;
834 dd = 0.1*ddr;
835 // if(debug_ ==4) std::cout<<"in smoother "<<std::endl;
836
837 } else if (lr == -1) {
838 chiSq_back_ += dchi2L;
839 dchi2_loc = dchi2L;
840 dd = -0.1*ddl;
841
842 }
843 if (chge){
844 a(aNew);
845 Ea(eaNew);
846 }
847
848 seg.a_filt_bwd(aNew);
849 seg.Ea_filt_bwd(eaNew);
850
851 HepVector a_pre_fwd_temp=seg.a_pre_fwd();
852 if( (a_pre_fwd_temp[1]-seg.a_pre_bwd()[1]) > 3. * M_PI /2.) a_pre_fwd_temp[1]-= M_PI2;
853 if( (a_pre_fwd_temp[1]-seg.a_pre_bwd()[1]) < -3. * M_PI /2. ) a_pre_fwd_temp[1]+= M_PI2;
854
855 seg.a_pre_fwd(a_pre_fwd_temp);
856
857 HepVector a_pre_filt_temp=seg.a_filt_fwd();
858 if( (a_pre_filt_temp[1]-seg.a_pre_bwd()[1]) > 3. * M_PI /2. ) a_pre_filt_temp[1] -= M_PI2;
859 if( (a_pre_filt_temp[1]-seg.a_pre_bwd()[1]) < -3. * M_PI /2.) a_pre_filt_temp[1] += M_PI2;
860 seg.a_filt_fwd(a_pre_filt_temp);
861
862 /*
863 KalFitTrack helixNew(pivot_work, aNew, eaNew, 0, 0, 0);
864 helixNew.pivot(ip);
865 a_temp = helixNew.a();
866 ea_temp = helixNew.Ea();
867 seg.Ea_filt_bwd(ea_temp);
868 seg.a_filt_bwd(a_temp);
869 */
870
871 int inv;
872
873 if(debug_ == 4){
874 std::cout<<"seg.Ea_pre_bwd().inverse(inv) ..."<<seg.Ea_pre_bwd().inverse(inv)<<std::endl;
875 std::cout<<"seg.Ea_pre_fwd().inverse(inv) ..."<<seg.Ea_pre_fwd().inverse(inv)<<std::endl;
876 }
877
878 HepSymMatrix Ea_pre_comb = (seg.Ea_pre_bwd().inverse(inv)+seg.Ea_pre_fwd().inverse(inv)).inverse(inv);
879 seg.Ea_exclude(Ea_pre_comb);
880
881
882 if(debug_ == 4) {
883 std::cout<<"Ea_pre_comb_ ... "<<Ea_pre_comb<<std::endl;
884 std::cout<<"seg.a_pre_bwd()..."<<seg.a_pre_bwd()<<std::endl;
885 std::cout<<"seg.a_pre_fwd()..."<<seg.a_pre_fwd()<<std::endl;
886 }
887 HepVector a_pre_comb = Ea_pre_comb*((seg.Ea_pre_bwd().inverse(inv))*seg.a_pre_bwd()+(seg.Ea_pre_fwd().inverse(inv))*seg.a_pre_fwd());
888 seg.a_exclude(a_pre_comb);
889
890 if(debug_ == 4) {
891 std::cout<<"seg.Ea_filt_fwd()..."<<seg.Ea_filt_fwd()<<std::endl;
892 std::cout<<"seg.Ea_filt_fwd().inverse(inv)..."<<seg.Ea_filt_fwd().inverse(inv)<<std::endl;
893 }
894 seg.Ea((seg.Ea_filt_fwd().inverse(inv)+seg.Ea_pre_bwd().inverse(inv)).inverse(inv));
895 seg.Ea_include((seg.Ea_filt_fwd().inverse(inv)+seg.Ea_pre_bwd().inverse(inv)).inverse(inv));
896
897 if(debug_ == 4) {
898 std::cout<<"seg.Ea() is ..."<<seg.Ea()<<std::endl;
899 std::cout<<"seg.Ea_filt_fwd().inverse(inv)*seg.a_filt_fwd() ..."<<seg.Ea_filt_fwd().inverse(inv)*seg.a_filt_fwd()<<std::endl;
900 std::cout<<"seg.Ea_pre_bwd().inverse(inv)*seg.a_pre_bwd() ... "<<seg.Ea_pre_bwd().inverse(inv)*seg.a_pre_bwd()<<std::endl;
901 }
902
903 seg.a(seg.Ea()*(seg.Ea_filt_fwd().inverse(inv)*seg.a_filt_fwd()+seg.Ea_pre_bwd().inverse(inv)*seg.a_pre_bwd()));
904 seg.a_include(seg.Ea()*(seg.Ea_filt_fwd().inverse(inv)*seg.a_filt_fwd()+seg.Ea_pre_bwd().inverse(inv)*seg.a_pre_bwd()));
905
906 if(inv != 0) {
907 //std::cout<<"ERROR OCCUR WHEN INVERSE MATRIX !"<<std::endl;
908 }
909
910 seg.residual_exclude(dd - (v_HT*a_pre_comb)[0]);
911 seg.residual_include(dd - (v_HT*seg.a())[0]);
912 seg.doca_exclude(fabs((v_HT*a_pre_comb)[0]));
913 seg.doca_include(fabs((v_HT*seg.a())[0]));
914
915 if(debug_ == 4){
916 std::cout<<"the dd in smoother_Mdc is "<<dd
917 <<" the (v_HT*a_pre_comb)[0] is "<<(v_HT*a_pre_comb)[0]<<std::endl;
918 }
919
920 //compare the two method to calculate the include doca value :
921 if(debug_ == 4){
922 std::cout<<"method 1 ..."<<sqrt(seg.a()[0]*seg.a()[0]+seg.a()[3]*seg.a()[3])<<std::endl;
923 std::cout<<"method 2 ..."<<fabs((v_HT*seg.a())[0])<<std::endl;
924 }
925
926
927 /// move the pivot of the helixseg to IP(0,0,0)
928 KalFitTrack helixNew1(pivot_work, seg.a(), seg.Ea(), 0, 0, 0);
929 helixNew1.pivot(ip);
930 HepVector a_temp1 = helixNew1.a();
931 HepSymMatrix ea_temp1 = helixNew1.Ea();
932 seg.Ea(ea_temp1);
933 seg.a(a_temp1);
934 seg.Ea_include(ea_temp1);
935 seg.a_include(a_temp1);
936
937 KalFitTrack helixNew2(pivot_work, seg.a_exclude(), seg.Ea_exclude(), 0, 0, 0);
938 helixNew2.pivot(ip);
939 HepVector a_temp2 = helixNew2.a();
940 HepSymMatrix ea_temp2 = helixNew2.Ea();
941 seg.Ea_exclude(ea_temp2);
942 seg.a_exclude(a_temp2);
943
944 seg.tof(tofest);
945 seg.dd(dd);
946
947 }
948 return chiSq_back_;
949}
950
951// Smoothing procedure in Mdc calib
952// RMK attention for the case chi2R = chi2L during forward filter !
953double KalFitTrack::smoother_Mdc(KalFitHelixSeg& seg, Hep3Vector& meas,int& flg, int csmflag )
954{
955
956
957 HepPoint3D ip(0., 0., 0.);
958 // attention! we should not to decide the left&right in the smoother process,
959 // because we choose the left&right of hits from the filter process.
960
961 KalFitHitMdc* HitMdc = seg.HitMdc();
962 double lr = HitMdc->LR();
963
964 // For taking the propagation delay into account :
965 int layerid = (*HitMdc).wire().layer().layerId();
966 int wire_ID = HitMdc->wire().geoID();
967 double entrangle = HitMdc->rechitptr()->getEntra();
968
969 if (wire_ID<0 || wire_ID>6796){ //bes
970 std::cout << "KalFitTrack : wire_ID problem : " << wire_ID << std::endl;
971 return 0;
972 }
973
974 double x[3] ={pivot().x(), pivot().y(), pivot().z()};
975 double pmom[3] ={momentum().x(), momentum().y(), momentum().z()};
976 double dd(0.);
977 double tofest(0);
978 double phi = fmod(phi0() + M_PI4, M_PI2);
979 double csf0 = cos(phi);
980 double snf0 = (1. - csf0) * (1. + csf0);
981 snf0 = sqrt((snf0 > 0.) ? snf0 : 0.);
982 if(phi > M_PI) snf0 = - snf0;
983
984 if (Tof_correc_) {
985 Hep3Vector ip(0, 0, 0);
986 Helix work = *(Helix*)this;
987 work.ignoreErrorMatrix();
988 work.pivot(ip);
989 double phi_ip = work.phi0();
990 if (fabs(phi - phi_ip) > M_PI) {
991 if (phi > phi_ip) phi -= 2 * M_PI;
992 else phi_ip -= 2 * M_PI;
993 }
994 double t = tanl();
995 double l = fabs(radius() * (phi - phi_ip) * sqrt(1 + t * t));
996 double pmag( sqrt( 1.0 + t*t ) / kappa());
997 double mass_over_p( mass_ / pmag );
998 double beta( 1.0 / sqrt( 1.0 + mass_over_p * mass_over_p ) );
999 tofest = l / ( 29.9792458 * beta );
1000 if(csmflag==1 && (*HitMdc).wire().y()>0.) tofest= -1. * tofest;
1001 }
1002
1003 const HepSymMatrix& ea = Ea();
1004 const HepVector& v_a = a();
1005
1006
1007
1008 HepPoint3D pivot_work = pivot();
1009
1010 /*
1011 HepVector a_work = a();
1012 HepSymMatrix ea_work = Ea();
1013
1014 KalFitTrack helix_work(pivot_work, a_work, ea_work, 0, 0, 0);
1015 helix_work.pivot(ip);
1016
1017 HepVector a_temp = helix_work.a();
1018 HepSymMatrix ea_temp = helix_work.Ea();
1019
1020 seg.Ea_pre_bwd(ea_temp);
1021 seg.a_pre_bwd(a_temp);
1022
1023 */
1024
1025 seg.a_pre_bwd(a());
1026 seg.Ea_pre_bwd(Ea());
1027
1028 double dchi2R(99999999), dchi2L(99999999);
1029 HepVector v_H(5, 0);
1030 v_H[0] = -csf0 * meas.x() - snf0 * meas.y();
1031 v_H[3] = -meas.z();
1032 HepMatrix v_HT = v_H.T();
1033
1034 double estim = (v_HT * v_a)[0];
1035 HepVector ea_v_H = ea * v_H;
1036 HepMatrix ea_v_HT = (ea_v_H).T();
1037 HepVector v_H_T_ea_v_H = v_HT * ea_v_H;
1038 HepSymMatrix eaNew(5);
1039 HepVector aNew(5);
1040 double time = (*HitMdc).tdc();
1041
1042 //seg.dt(time);
1043 // if (Tof_correc_)
1044 // {
1045 // time -= tofest;
1046 // seg.dt(time);
1047 // }
1048 // double dd = 1.0e-4 * 40.0 * time;
1049 // seg.dd(dd);
1050
1051 double drifttime = getDriftTime(*HitMdc , tofest);
1052 seg.dt(drifttime);
1053 double ddl = getDriftDist(*HitMdc, drifttime, 0 );
1054 double ddr = getDriftDist(*HitMdc, drifttime, 1 );
1055 double erddl = getSigma( *HitMdc, a()[4], 0, ddl);
1056 double erddr = getSigma( *HitMdc, a()[4], 1, ddr);
1057
1058 double dmeas2[2] = { 0.1*ddl, 0.1*ddr }; // millimeter to centimeter
1059 double er_dmeas2[2] = {0., 0.};
1060 if(resolflag_ == 1) {
1061 er_dmeas2[0] = 0.1*erddl;
1062 er_dmeas2[1] = 0.1*erddr;
1063 }else if(resolflag_ == 0)
1064 {
1065 }
1066
1067 // Left hypothesis :
1068 if (lr == -1) {
1069 double er_dmeasL, dmeasL;
1070 if(Tof_correc_) {
1071 dmeasL = (-1.0)*dmeas2[0];
1072 er_dmeasL = er_dmeas2[0];
1073 } else {
1074 dmeasL = (-1.0)*fabs((*HitMdc).dist()[0]);
1075 er_dmeasL = (*HitMdc).erdist()[0];
1076 }
1077
1078
1079 //if(layerid < 4) er_dmeasL*=2.0;
1080
1081 double AL = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasL*er_dmeasL);
1082 eaNew.assign(ea - ea_v_H * AL * ea_v_HT);
1083 double RkL = 1 - (v_H_T_ea_v_H)[0] * AL;
1084 if(0. == RkL) RkL = 1.e-4;
1085
1086 HepVector diffL = ea_v_H * AL * (dmeasL - estim);
1087 aNew = v_a + diffL;
1088 double sigL = (dmeasL - (v_HT * aNew)[0]);
1089 dchi2L = (sigL*sigL) / (RkL * er_dmeasL*er_dmeasL);
1090 } else if (lr == 1) {
1091 // Right hypothesis :
1092
1093 double er_dmeasR, dmeasR;
1094 if(Tof_correc_) {
1095 dmeasR = dmeas2[1];
1096 er_dmeasR = er_dmeas2[1];
1097 } else {
1098 dmeasR = fabs((*HitMdc).dist()[1]);
1099 er_dmeasR = (*HitMdc).erdist()[1];
1100 }
1101
1102
1103 //if(layerid < 4) er_dmeasR*=2.0;
1104
1105
1106 double AR = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasR*er_dmeasR);
1107 eaNew.assign(ea - ea_v_H * AR * ea_v_HT);
1108 double RkR = 1 - (v_H_T_ea_v_H)[0] * AR;
1109 if(0. == RkR) RkR = 1.e-4;
1110
1111 HepVector diffR = ea_v_H * AR * (dmeasR - estim);
1112 aNew = v_a + diffR;
1113 double sigR = (dmeasR- (v_HT * aNew)[0]);
1114 dchi2R = (sigR*sigR) / (RkR * er_dmeasR*er_dmeasR);
1115 }
1116
1117 // Update Kalman result :
1118#ifdef YDEBUG
1119 cout<<"in smoother_Mdc: lr= "<<lr<<" a: "<<v_a<<" a_NEW: "<<aNew<<endl;
1120#endif
1121 double dchi2_loc(0);
1122 if ((dchi2R < dchi2cuts_calib[layerid] && lr == 1) ||
1123 (dchi2L < dchi2cuts_calib[layerid] && lr == -1)) {
1124
1125 ndf_back_++;
1126 flg = 1;
1127 int chge(1);
1128 if (!(aNew[2] && fabs(aNew[2]-a()[2]) < 1.0)) chge = 0;
1129 if (lr == 1) {
1130 chiSq_back_ += dchi2R;
1131 dchi2_loc = dchi2R;
1132 dd = 0.1*ddr;
1133 // if(debug_ ==4) std::cout<<"in smoother "<<std::endl;
1134
1135 } else if (lr == -1) {
1136 chiSq_back_ += dchi2L;
1137 dchi2_loc = dchi2L;
1138 dd = -0.1*ddl;
1139
1140 }
1141 if (chge){
1142 a(aNew);
1143 Ea(eaNew);
1144 }
1145
1146 seg.a_filt_bwd(aNew);
1147 seg.Ea_filt_bwd(eaNew);
1148
1149 HepVector a_pre_fwd_temp=seg.a_pre_fwd();
1150 if( (a_pre_fwd_temp[1]-seg.a_pre_bwd()[1]) > 3. * M_PI /2.) a_pre_fwd_temp[1]-= M_PI2;
1151 if( (a_pre_fwd_temp[1]-seg.a_pre_bwd()[1]) < -3. * M_PI /2. ) a_pre_fwd_temp[1]+= M_PI2;
1152
1153 seg.a_pre_fwd(a_pre_fwd_temp);
1154
1155 HepVector a_pre_filt_temp=seg.a_filt_fwd();
1156 if( (a_pre_filt_temp[1]-seg.a_pre_bwd()[1]) > 3. * M_PI /2. ) a_pre_filt_temp[1] -= M_PI2;
1157 if( (a_pre_filt_temp[1]-seg.a_pre_bwd()[1]) < -3. * M_PI /2.) a_pre_filt_temp[1] += M_PI2;
1158 seg.a_filt_fwd(a_pre_filt_temp);
1159
1160 /*
1161 KalFitTrack helixNew(pivot_work, aNew, eaNew, 0, 0, 0);
1162 helixNew.pivot(ip);
1163 a_temp = helixNew.a();
1164 ea_temp = helixNew.Ea();
1165 seg.Ea_filt_bwd(ea_temp);
1166 seg.a_filt_bwd(a_temp);
1167 */
1168
1169 int inv;
1170
1171 if(debug_ == 4){
1172 std::cout<<"seg.Ea_pre_bwd().inverse(inv) ..."<<seg.Ea_pre_bwd().inverse(inv)<<std::endl;
1173 std::cout<<"seg.Ea_pre_fwd().inverse(inv) ..."<<seg.Ea_pre_fwd().inverse(inv)<<std::endl;
1174 }
1175
1176 HepSymMatrix Ea_pre_comb = (seg.Ea_pre_bwd().inverse(inv)+seg.Ea_pre_fwd().inverse(inv)).inverse(inv);
1177 seg.Ea_exclude(Ea_pre_comb);
1178
1179
1180 if(debug_ == 4) {
1181 std::cout<<"Ea_pre_comb_ ... "<<Ea_pre_comb<<std::endl;
1182 std::cout<<"seg.a_pre_bwd()..."<<seg.a_pre_bwd()<<std::endl;
1183 std::cout<<"seg.a_pre_fwd()..."<<seg.a_pre_fwd()<<std::endl;
1184 }
1185 HepVector a_pre_comb = Ea_pre_comb*((seg.Ea_pre_bwd().inverse(inv))*seg.a_pre_bwd()+(seg.Ea_pre_fwd().inverse(inv))*seg.a_pre_fwd());
1186 seg.a_exclude(a_pre_comb);
1187
1188
1189 if(debug_ == 4) {
1190 std::cout<<"seg.Ea_filt_fwd()..."<<seg.Ea_filt_fwd()<<std::endl;
1191 std::cout<<"seg.Ea_filt_fwd().inverse(inv)..."<<seg.Ea_filt_fwd().inverse(inv)<<std::endl;
1192 }
1193 seg.Ea((seg.Ea_filt_fwd().inverse(inv)+seg.Ea_pre_bwd().inverse(inv)).inverse(inv));
1194 seg.Ea_include((seg.Ea_filt_fwd().inverse(inv)+seg.Ea_pre_bwd().inverse(inv)).inverse(inv));
1195
1196 if(debug_ == 4) {
1197 std::cout<<"seg.Ea() is ..."<<seg.Ea()<<std::endl;
1198 std::cout<<"seg.Ea_filt_fwd().inverse(inv)*seg.a_filt_fwd() ..."<<seg.Ea_filt_fwd().inverse(inv)*seg.a_filt_fwd()<<std::endl;
1199 std::cout<<"seg.Ea_pre_bwd().inverse(inv)*seg.a_pre_bwd() ... "<<seg.Ea_pre_bwd().inverse(inv)*seg.a_pre_bwd()<<std::endl;
1200 }
1201
1202 seg.a(seg.Ea()*(seg.Ea_filt_fwd().inverse(inv)*seg.a_filt_fwd()+seg.Ea_pre_bwd().inverse(inv)*seg.a_pre_bwd()));
1203 seg.a_include(seg.Ea()*(seg.Ea_filt_fwd().inverse(inv)*seg.a_filt_fwd()+seg.Ea_pre_bwd().inverse(inv)*seg.a_pre_bwd()));
1204
1205 if(inv != 0) {
1206 //std::cout<<"ERROR OCCUR WHEN INVERSE MATRIX !"<<std::endl;
1207 }
1208
1209 seg.residual_exclude(dd - (v_HT*a_pre_comb)[0]);
1210 seg.residual_include(dd - (v_HT*seg.a())[0]);
1211 seg.doca_exclude(fabs((v_HT*a_pre_comb)[0]));
1212 seg.doca_include(fabs((v_HT*seg.a())[0]));
1213
1214 if(debug_ == 4){
1215 std::cout<<"the dd in smoother_Mdc is "<<dd
1216 <<" the (v_HT*a_pre_comb)[0] is "<<(v_HT*a_pre_comb)[0]<<std::endl;
1217 }
1218
1219 //compare the two method to calculate the include doca value :
1220 if(debug_ == 4){
1221 std::cout<<"method 1 ..."<<sqrt(seg.a()[0]*seg.a()[0]+seg.a()[3]*seg.a()[3])<<std::endl;
1222 std::cout<<"method 2 ..."<<fabs((v_HT*seg.a())[0])<<std::endl;
1223 }
1224
1225
1226 /// move the pivot of the helixseg to IP(0,0,0)
1227 KalFitTrack helixNew1(pivot_work, seg.a(), seg.Ea(), 0, 0, 0);
1228 helixNew1.pivot(ip);
1229 HepVector a_temp1 = helixNew1.a();
1230 HepSymMatrix ea_temp1 = helixNew1.Ea();
1231 seg.Ea(ea_temp1);
1232 seg.a(a_temp1);
1233 seg.Ea_include(ea_temp1);
1234 seg.a_include(a_temp1);
1235
1236 KalFitTrack helixNew2(pivot_work, seg.a_exclude(), seg.Ea_exclude(), 0, 0, 0);
1237 helixNew2.pivot(ip);
1238 HepVector a_temp2 = helixNew2.a();
1239 HepSymMatrix ea_temp2 = helixNew2.Ea();
1240 seg.Ea_exclude(ea_temp2);
1241 seg.a_exclude(a_temp2);
1242
1243 seg.tof(tofest);
1244 seg.dd(dd);
1245
1246 }
1247 return chiSq_back_;
1248}
1249
1250
1251
1252
1253
1254double KalFitTrack::filter(double v_m, const HepVector& m_H,
1255 double v_d, double m_V)
1256{
1257 HepMatrix m_HT = m_H.T();
1258 HepPoint3D x0 = x(0);
1259 HepVector v_x(3);
1260 v_x[0] = x0.x();
1261 v_x[1] = x0.y();
1262 v_x[2] = x0.z();
1263 HepMatrix m_X = delXDelA(0);
1264 HepMatrix m_XT = m_X.T();
1265 HepMatrix m_C = m_X * Ea() * m_XT;
1266 //int err;
1267 HepVector m_K = 1 / (m_V + (m_HT * m_C * m_H)[0]) * m_H;
1268 HepVector v_a = a();
1269 HepSymMatrix ea = Ea();
1270 HepMatrix mXTmK = m_XT * m_K;
1271 double v_r = v_m - v_d - (m_HT * v_x)[0];
1272 v_a += ea * mXTmK * v_r;
1273 a(v_a);
1274 ea.assign(ea - ea * mXTmK * m_HT * m_X * ea);
1275 Ea(ea);
1276 // Record last hit included parameters :
1277 update_last();
1278 HepMatrix mCmK = m_C * m_K;
1279 v_x += mCmK * v_r;
1280 m_C -= mCmK * m_HT * m_C;
1281 v_r = v_m - v_d - (m_HT * v_x)[0];
1282 double m_R = m_V - (m_HT * m_C * m_H)[0];
1283 double chiSq = v_r * v_r / m_R;
1284 chiSq_ += chiSq;
1285 return chiSq;
1286}
1287
1288
1289void KalFitTrack::path_add(double path)
1290{
1291 pathip_ += path;
1292 tof(path);
1293}
1294
1295
1296void KalFitTrack::addPathSM(double path){
1297 pathSM_ += path;
1298}
1299
1300
1302 tof2_ += time;
1303}
1304
1305
1306void KalFitTrack::fiTerm(double fi){
1307 fiTerm_ = fi;
1308}
1309
1310
1311void KalFitTrack::tof(double path)
1312{
1313 double light_speed( 29.9792458 ); // light speed in cm/nsec
1314 double t = tanl();
1315 double pmag( sqrt( 1.0 + t*t ) / kappa());
1316 if (pmag !=0) {
1317 double mass_over_p( mass_ / pmag );
1318 double beta( 1.0 / sqrt( 1.0 + mass_over_p * mass_over_p ) );
1319 tof_ += path / ( light_speed * beta );
1320 }
1321
1322 if (tofall_) {
1323 if (p_kaon_ > 0){
1324 double massk_over_p( MASS[3] / p_kaon_ );
1325 double beta_kaon( 1.0 / sqrt( 1.0 + massk_over_p * massk_over_p ) );
1326 tof_kaon_ += path / (light_speed * beta_kaon);
1327 }
1328 if (p_proton_ > 0){
1329 double massp_over_p( MASS[4] / p_proton_ );
1330 double beta_proton( 1.0 / sqrt( 1.0 + massp_over_p * massp_over_p ) );
1331 tof_proton_ += path / (light_speed * beta_proton);
1332 }
1333 }
1334}
1335
1336double KalFitTrack::radius_numf(void) const {
1337
1338 double Bz(Bznom_);
1339 //std::cout<<"Bz: "<<Bz<<std::endl;
1340 if (numf_ > 10){
1341 double dr = a()[0];
1342 double phi0 = a()[1];
1343 double dz = a()[3];
1344 double phi = fmod(phi0 + M_PI4, M_PI2);
1345 double csf0 = cos(phi);
1346 double snf0 = (1. - csf0) * (1. + csf0);
1347 snf0 = sqrt((snf0 > 0.) ? snf0 : 0.);
1348 if(phi > M_PI) snf0 = - snf0;
1349 //XYZPoint
1350 HepPoint3D x0((pivot().x() + dr*csf0),
1351 (pivot().y() + dr*snf0),
1352 (pivot().z() + dz));
1353
1354 //XYZVector b;
1355 HepVector3D b;
1356
1357 //std::cout<<"b: "<<b<<std::endl;
1358
1359 MFSvc_->fieldVector(10.*x0, b);
1360
1361 //std::cout<<"b: "<<b<<std::endl;
1362
1363
1364 b = 10000.*b;
1365 Bz = b.z();
1366 }
1367 if (Bz == 0)
1368 Bz = Bznom_;
1369 double ALPHA_loc = 10000./2.99792458/Bz;
1370 return ALPHA_loc / a()[2];
1371}
1372
1373const HepPoint3D &
1375
1376 int nstep(1);
1377 HepPoint3D delta_x((newPivot-pivot()).x()/double(inner_steps_),
1378 (newPivot-pivot()).y()/double(inner_steps_),
1379 (newPivot-pivot()).z()/double(inner_steps_));
1380 int i = 1;
1381
1382 while (i <= inner_steps_) {
1383 HepPoint3D nextPivot(pivot()+delta_x);
1384 double xnp(nextPivot.x()), ynp(nextPivot.y()), znp(nextPivot.z());
1385 HepSymMatrix Ea_now = Ea();
1386 HepPoint3D piv(pivot());
1387 double xp(piv.x()), yp(piv.y()), zp(piv.z());
1388 double dr = a()[0];
1389 double phi0 = a()[1];
1390 double kappa = a()[2];
1391 double dz = a()[3];
1392 double tanl = a()[4];
1393 double m_rad(0);
1394 if (numfcor_ == 1)
1395 m_rad = radius_numf();
1396 else
1397 m_rad = radius();
1398 double rdr = dr + m_rad;
1399 double phi = fmod(phi0 + M_PI4, M_PI2);
1400 double csf0 = cos(phi);
1401 double snf0 = (1. - csf0) * (1. + csf0);
1402 snf0 = sqrt((snf0 > 0.) ? snf0 : 0.);
1403 if(phi > M_PI) snf0 = - snf0;
1404
1405 double xc = xp + rdr * csf0;
1406 double yc = yp + rdr * snf0;
1407 double csf = (xc - xnp) / m_rad;
1408 double snf = (yc - ynp) / m_rad;
1409 double anrm = sqrt(csf * csf + snf * snf);
1410 csf /= anrm;
1411 snf /= anrm;
1412 phi = atan2(snf, csf);
1413 double phid = fmod(phi - phi0 + M_PI8, M_PI2);
1414 if(phid > M_PI) phid = phid - M_PI2;
1415 double drp = (xp + dr * csf0 + m_rad * (csf0 - csf) - xnp)
1416 * csf
1417 + (yp + dr * snf0 + m_rad * (snf0 - snf) - ynp) * snf;
1418 double dzp = zp + dz - m_rad * tanl * phid - znp;
1419
1420 HepVector ap(5);
1421 ap[0] = drp;
1422 ap[1] = fmod(phi + M_PI4, M_PI2);
1423 ap[2] = kappa;
1424 ap[3] = dzp;
1425 ap[4] = tanl;
1426
1427 // Modification due to non uniform magnetic field :
1428 if (numf_ > 10) {
1429
1430 Hep3Vector x1(xp + dr*csf0, yp + dr*snf0, zp + dz);
1431 double csf0p = cos(ap[1]);
1432 double snf0p = (1. - csf0p) * (1. + csf0p);
1433 snf0p = sqrt((snf0p > 0.) ? snf0p : 0.);
1434 if(ap[1] > M_PI) snf0p = - snf0p;
1435
1436 Hep3Vector x2(xnp + drp*csf0p,
1437 ynp + drp*snf0p,
1438 znp + dzp);
1439 Hep3Vector dist((x1 - x2).x()/100.0,
1440 (x1 - x2).y()/100.0,
1441 (x1 - x2).z()/100.0);
1442 HepPoint3D middlebis((x1.x() + x2.x())/2,
1443 (x1.y() + x2.y())/2,
1444 (x1.z() + x2.z())/2);
1445 HepVector3D field;
1446 MFSvc_->fieldVector(10.*middlebis,field);
1447 field = 1000.*field;
1448 Hep3Vector dB(field.x(),
1449 field.y(),
1450 (field.z()-0.1*Bznom_));
1451 if (field.z()) {
1452 double akappa(fabs(kappa));
1453 double sign = kappa/akappa;
1454 HepVector dp(3);
1455 dp = 0.299792458 * sign * dB.cross(dist);
1456 HepVector dhp(3);
1457 dhp[0] = -akappa*(dp[0]*csf0p+dp[1]*snf0p);
1458 dhp[1] = kappa*akappa*(dp[0]*snf0p-dp[1]*csf0p);
1459 dhp[2] = dp[2]*akappa+dhp[1]*tanl/kappa;
1460 if (numfcor_ == 0){
1461 ap[1] += dhp[0];
1462 }
1463 ap[2] += dhp[1];
1464 ap[4] += dhp[2];
1465 }
1466 }
1467 HepMatrix m_del = delApDelA(ap);
1468 Ea_now.assign(m_del * Ea_now * m_del.T());
1469 pivot(nextPivot);
1470 a(ap);
1471 Ea(Ea_now);
1472 i++;
1473 }
1474 return newPivot;
1475}
1476
1477const HepPoint3D &
1478KalFitTrack::pivot_numf(const HepPoint3D & newPivot, double & pathl) {
1479
1480 Helix tracktest = *(Helix*)this;
1481 tracktest.ignoreErrorMatrix();
1482 double tl = a()[4];
1483 double th = 90.0 - 180.0*M_1_PI*atan( tl );
1484 /*
1485 int nstep(1);
1486 if (steplev_ == 1)
1487 nstep = 3;
1488 else if (steplev_ == 2 && (th > 140 || th <45))
1489 if ((pivot()-newPivot).mag()<3.)
1490 nstep = 3;
1491 else
1492 nstep = 6;
1493 */
1494 Hep3Vector delta_x((newPivot-pivot()).x()/double(outer_steps_),
1495 (newPivot-pivot()).y()/double(outer_steps_),
1496 (newPivot-pivot()).z()/double(outer_steps_));
1497 int i = 1;
1498
1499 while (i <= outer_steps_) {
1500 HepPoint3D nextPivot(pivot()+delta_x);
1501 double xnp(nextPivot.x()), ynp(nextPivot.y()), znp(nextPivot.z());
1502
1503 HepSymMatrix Ea_now = Ea();
1504 HepPoint3D piv(pivot());
1505 double xp(piv.x()), yp(piv.y()), zp(piv.z());
1506
1507 double dr = a()[0];
1508 double phi0 = a()[1];
1509 double kappa = a()[2];
1510 double dz = a()[3];
1511 double tanl = a()[4];
1512
1513 double m_rad(0);
1514 m_rad = radius();
1515
1516 double rdr = dr + m_rad;
1517 double phi = fmod(phi0 + M_PI4, M_PI2);
1518 double csf0 = cos(phi);
1519 double snf0 = (1. - csf0) * (1. + csf0);
1520 snf0 = sqrt((snf0 > 0.) ? snf0 : 0.);
1521 if(phi > M_PI) snf0 = - snf0;
1522
1523 double xc = xp + rdr * csf0;
1524 double yc = yp + rdr * snf0;
1525 double csf = (xc - xnp) / m_rad;
1526 double snf = (yc - ynp) / m_rad;
1527 double anrm = sqrt(csf * csf + snf * snf);
1528 csf /= anrm;
1529 snf /= anrm;
1530 phi = atan2(snf, csf);
1531 double phid = fmod(phi - phi0 + M_PI8, M_PI2);
1532 if(phid > M_PI) phid = phid - M_PI2;
1533 double drp = (xp + dr * csf0 + m_rad * (csf0 - csf) - xnp)
1534 * csf
1535 + (yp + dr * snf0 + m_rad * (snf0 - snf) - ynp) * snf;
1536 double dzp = zp + dz - m_rad * tanl * phid - znp;
1537
1538 HepVector ap(5);
1539 ap[0] = drp;
1540 ap[1] = fmod(phi + M_PI4, M_PI2);
1541 ap[2] = kappa;
1542 ap[3] = dzp;
1543 ap[4] = tanl;
1544
1545 //std::cout<<" numf_: "<<numf_<<std::endl;
1546
1547 // Modification due to non uniform magnetic field :
1548 if (numf_ > 10) {
1549
1550 Hep3Vector x1(xp + dr*csf0, yp + dr*snf0, zp + dz);
1551
1552 double csf0p = cos(ap[1]);
1553 double snf0p = (1. - csf0p) * (1. + csf0p);
1554 snf0p = sqrt((snf0p > 0.) ? snf0p : 0.);
1555 if(ap[1] > M_PI) snf0p = - snf0p;
1556
1557 Hep3Vector x2(xnp + drp*csf0p,
1558 ynp + drp*snf0p,
1559 znp + dzp);
1560
1561 Hep3Vector dist((x1 - x2).x()/100.0,
1562 (x1 - x2).y()/100.0,
1563 (x1 - x2).z()/100.0);
1564
1565 HepPoint3D middlebis((x1.x() + x2.x())/2,
1566 (x1.y() + x2.y())/2,
1567 (x1.z() + x2.z())/2);
1568
1569 HepVector3D field;
1570 MFSvc_->fieldVector(10.*middlebis,field);
1571 field = 1000.*field;
1572
1573 //std::cout<<"B field: "<<field<<std::endl;
1574 Hep3Vector dB(field.x(),
1575 field.y(),
1576 (field.z()-0.1*Bznom_));
1577
1578
1579 //std::cout<<" dB: "<<dB<<std::endl;
1580
1581
1582 if (field.z()) {
1583 double akappa(fabs(kappa));
1584 double sign = kappa/akappa;
1585 HepVector dp(3);
1586 dp = 0.299792458 * sign * dB.cross(dist);
1587
1588 //std::cout<<"dp: "<<dp<<std::endl;
1589
1590 HepVector dhp(3);
1591 dhp[0] = -akappa*(dp[0]*csf0p+dp[1]*snf0p);
1592 dhp[1] = kappa*akappa*(dp[0]*snf0p-dp[1]*csf0p);
1593 dhp[2] = dp[2]*akappa+dhp[1]*tanl/kappa;
1594
1595
1596 //std::cout<<"dhp: "<<dhp<<std::endl;
1597
1598
1599 ap[1] += dhp[0];
1600 ap[2] += dhp[1];
1601 ap[4] += dhp[2];
1602 }
1603 }
1604 HepMatrix m_del = delApDelA(ap);
1605 Ea_now.assign(m_del * Ea_now * m_del.T());
1606 pivot(nextPivot);
1607 a(ap);
1608 Ea(Ea_now);
1609 i++;
1610
1611 //std::cout<<" a: "<<a()<<std::endl;
1612 }
1613
1614 // Estimation of the path length :
1615 double tanl_0(tracktest.a()[4]);
1616 double phi0_0(tracktest.a()[1]);
1617 double radius_0(tracktest.radius());
1618 tracktest.pivot(newPivot);
1619
1620 double phi0_1 = tracktest.a()[1];
1621 if (fabs(phi0_1 - phi0_0) > M_PI) {
1622 if (phi0_1 > phi0_0) phi0_1 -= 2 * M_PI;
1623 else phi0_0 -= 2 * M_PI;
1624 }
1625 if(phi0_1 == phi0_0) phi0_1 = phi0_0 + 1.e-10;
1626 pathl = fabs(radius_0 * (phi0_1 - phi0_0)
1627 * sqrt(1 + tanl_0 * tanl_0));
1628 return newPivot;
1629}
1630
1631// function to calculate the path length in the layer
1632/*
1633 double KalFitTrack::PathL(int layer){
1634 HepPoint3D piv(pivot());
1635 double phi0 = a()[1];
1636 double kappa = a()[2];
1637 double tanl = a()[4];
1638
1639#ifdef YDEBUG
1640cout<<"helix "<<a()<<endl;
1641#endif
1642// Choose the local field !!
1643double Bz(Bznom_);
1644if (numf_ > 10){
1645HepVector3D b;
1646MFSvc_->fieldVector(10.*piv, b);
1647b = 10000.*b;
1648Bz=b.z();
1649}
1650double ALPHA_loc = 10000./2.99792458/Bz;
1651int charge = ( kappa >= 0 )? 1 : -1;
1652double rho = ALPHA_loc/kappa;
1653double pt = fabs( 1.0/kappa );
1654double lambda = 180.0*M_1_PI*atan( tanl );
1655double theta = 90.0 - lambda;
1656theta = 2.0*M_PI*theta/360.;
1657double phi = fmod(phi0 + M_PI4, M_PI2);
1658double csf0 = cos(phi);
1659double snf0 = (1. - csf0) * (1. + csf0);
1660snf0 = sqrt((snf0 > 0.) ? snf0 : 0.);
1661if(phi > M_PI) snf0 = - snf0;
1662
1663double x_c = piv.x() + ( dr() + rho )*csf0;
1664double y_c = piv.y() + ( dr() + rho )*snf0;
1665double z_c = piv.z() + dz();
1666HepPoint3D ccenter(x_c, y_c, 0);
1667double m_c_perp(ccenter.perp());
1668Hep3Vector m_c_unit(((CLHEP::Hep3Vector)ccenter).unit());
1669#ifdef YDEBUG
1670cout<<"rho=..."<<rho<<endl;
1671cout<<"ccenter "<<ccenter<<" m_c_unit "<<m_c_unit<<endl;
1672#endif
1673//phi resion estimation
1674double phi_io[2];
1675HepPoint3D IO = charge*m_c_unit;
1676double dphi0 = fmod( IO.phi()+4*M_PI,2*M_PI ) - phi;
1677if( dphi0 > M_PI ) dphi0 -= 2*M_PI;
1678else if( dphi0 < -M_PI ) dphi0 += 2*M_PI;
1679phi_io[0] = -(1+charge)*M_PI_2 - charge*dphi0;
1680phi_io[1] = phi_io[0]+1.5*M_PI;
1681double phi_in(0); /// for debug
1682
1683double m_crio[2];
1684double m_zb, m_zf;
1685int m_div;
1686
1687// retrieve Mdc geometry information
1688// IMdcGeomSvc* geosvc;
1689StatusCode sc= Gaudi::svcLocator()->service("MdcGeomSvc", geosvc);
1690if(sc==StatusCode::FAILURE) cout << "GeoSvc failing!!!!!!!SC=" << sc << endl;
1691
1692MdcGeomSvc* geomsvc = dynamic_cast<MdcGeomSvc*>(iGeomSvc_);
1693if(!geomsvc){
1694std::cout<<"ERROR OCCUR when dynamic_cast in KalFitTrack.cxx !!"<<std::endl;
1695}
1696double rcsiz1 = geomsvc->Layer(layer)->RCSiz1();
1697double rcsiz2 = geomsvc->Layer(layer)->RCSiz2();
1698double rlay = geomsvc->Layer(layer)->Radius();
1699m_zb = 0.5*(geomsvc->Layer(layer)->Length());
1700m_zf = -0.5*(geomsvc->Layer(layer)->Length());
1701
1702m_crio[0] = rlay - rcsiz1;
1703m_crio[1] = rlay + rcsiz2;
1704//conversion of the units(mm=>cm)
1705m_crio[0] = 0.1*m_crio[0];
1706m_crio[1] = 0.1*m_crio[1];
1707m_zb = 0.1*m_zb;
1708m_zf = 0.1*m_zf;
1709
1710int sign = 1; ///assumed the first half circle
1711int epflag[2];
1712Hep3Vector iocand;
1713Hep3Vector cell_IO[2];
1714double dphi;
1715for( int i = 0; i < 2; i++ ){
1716 double cos_alpha = m_c_perp*m_c_perp + m_crio[i]*m_crio[i] - rho*rho;
1717 cos_alpha = 0.5*cos_alpha/( m_c_perp*m_crio[i] );
1718 double Calpha = acos( cos_alpha );
1719 epflag[i] = 0;
1720 iocand = m_c_unit;
1721 iocand.rotateZ( charge*sign*Calpha );
1722 iocand *= m_crio[i];
1723 double xx = iocand.x() - x_c;
1724 double yy = iocand.y() - y_c;
1725 dphi = atan2(yy, xx) - phi0 - M_PI_2*(1+charge);
1726 dphi = fmod( dphi + 8.0*M_PI, 2*M_PI );
1727
1728 if( dphi < phi_io[0] ){
1729 dphi += 2*M_PI;
1730 }
1731 else if( phi_io[1] < dphi ){
1732 dphi -= 2*M_PI;
1733 }
1734
1735 ///in the Local Helix case, phi must be small
1736
1737 Hep3Vector zvector( 0., 0., z_c-rho*dphi*tanl);
1738
1739 double xcio, ycio, phip;
1740 ///// z region check active volume is between zb+2. and zf-2. [cm]
1741 double delrin = 2.0;
1742 if( m_zf-delrin > zvector.z() ){
1743 phip = z_c - m_zb + delrin;
1744 phip = phip/( rho*tanl );
1745 phip = phip + phi0;
1746 xcio = x_c - rho*cos( phip );
1747 ycio = y_c - rho*sin( phip );
1748 cell_IO[i].setX( xcio );
1749 cell_IO[i].setY( ycio );
1750 cell_IO[i].setZ( m_zb+delrin );
1751 epflag[i] = 1;
1752 }
1753 else if( m_zb+delrin < zvector.z() ){
1754 phip = z_c - m_zf-delrin;
1755 phip = phip/( rho*tanl );
1756 phip = phip + phi0;
1757 xcio = x_c - rho*cos( phip );
1758 ycio = y_c - rho*sin( phip );
1759 cell_IO[i].setX( xcio );
1760 cell_IO[i].setY( ycio );
1761 cell_IO[i].setZ( m_zf-delrin );
1762 epflag[i] = 1;
1763 }
1764 else{
1765 cell_IO[i] = iocand;
1766 cell_IO[i] += zvector;
1767 }
1768 /// for debug
1769 if( i == 0 ) phi_in = dphi;
1770}
1771// path length estimation
1772// phi calculation
1773Hep3Vector cl = cell_IO[1] - cell_IO[0];
1774#ifdef YDEBUG
1775cout<<"cell_IO[0] "<<cell_IO[0]<<" cell_IO[1] "<<cell_IO[1]<<" cl "<<cl<<endl;
1776#endif
1777
1778double ch_theta;
1779double ch_dphi;
1780double ch_ltrk = 0;
1781double ch_ltrk_rp = 0;
1782ch_dphi = cl.perp()*0.5/(ALPHA_loc*pt);
1783ch_dphi = 2.0 * asin( ch_dphi );
1784ch_ltrk_rp = ch_dphi*ALPHA_loc*pt;
1785#ifdef YDEBUG
1786cout<<"ch_dphi "<<ch_dphi<<" ch_ltrk_rp "<<ch_ltrk_rp<<" cl.z "<<cl.z()<<endl;
1787#endif
1788ch_ltrk = sqrt( ch_ltrk_rp*ch_ltrk_rp + cl.z()*cl.z() );
1789ch_theta = cl.theta();
1790
1791if( ch_theta < theta*0.85 || 1.15*theta < ch_theta)
1792 ch_ltrk *= -1; /// miss calculation
1793
1794if( epflag[0] == 1 || epflag [1] == 1 )
1795 ch_ltrk *= -1; /// invalid resion for dE/dx or outside of Mdc
1796
1797 mom_[layer] = momentum( phi_in );
1798 PathL_[layer] = ch_ltrk;
1799#ifdef YDEBUG
1800 cout<<"ch_ltrk "<<ch_ltrk<<endl;
1801#endif
1802 return ch_ltrk;
1803 }
1804*/
1805
1806
1808 int j(0);
1809 if (i < 31){
1810 j = (int) pow(2.,i);
1811 if (!(pat1_ & j))
1812 pat1_ = pat1_ | j;
1813 } else if (i < 50) {
1814 j = (int) pow(2.,(i-31));
1815 if (!(pat2_ & j))
1816 pat2_ = pat2_ | j;
1817 }
1818}
1819
1820int KalFitTrack::nmass(void){ return NMASS;}
1821double KalFitTrack::mass(int i){ return MASS[i];}
1823 mass_=MASS[i];
1824 l_mass_=i;
1825}
1826
1827void KalFitTrack::lead(int i){ lead_ = i;}
1828int KalFitTrack::lead(void){ return lead_;}
1829void KalFitTrack::back(int i){ back_ = i;}
1830int KalFitTrack::back(void){ return back_;}
1833void KalFitTrack::numf(int i){ numf_ = i;}
1834int KalFitTrack::numf(void){ return numf_;}
1835void KalFitTrack::LR(int x){ LR_ = x;}
1836void KalFitTrack::HitsMdc(vector<KalFitHitMdc>& lh){ HitsMdc_ = lh;}
1837void KalFitTrack::appendHitsMdc(KalFitHitMdc h){ HitsMdc_.push_back(h);}
1838
1839/*
1840 This member function is in charge of the forward filter,
1841 for the tof correction of the drift distance in the case of cosmic rays
1842 if way=1, it's a down track means same as track in collision data,
1843 if way=-1, it's a up track !
1844 */
1845
1846double KalFitTrack::update_hits(KalFitHitMdc & HitMdc, int inext, Hep3Vector& meas, int way, double& dchi2out, double& dtrack,double& dtracknew, double& dtdc, int csmflag) {
1847
1848 double lr = HitMdc.LR();
1849 //std::cout<<" in update_hits: lr= " << lr <<std::endl;
1850 // For taking the propagation delay into account :
1851 const KalFitWire& Wire = HitMdc.wire();
1852 int wire_ID = Wire.geoID();
1853 int layerid = HitMdc.wire().layer().layerId();
1854 //std::cout<<" when in layer: "<<layerid<<std::endl;
1855 double entrangle = HitMdc.rechitptr()->getEntra();
1856
1857 if (wire_ID<0 || wire_ID>6796){ //bes
1858 std::cout << " KalFitTrack: wire_ID problem : " << wire_ID
1859 << std::endl;
1860 return 0;
1861 }
1862 int flag_ster = Wire.stereo();
1863 double x[3] ={pivot().x(), pivot().y(), pivot().z()};
1864 double pmom[3] ={momentum().x(), momentum().y(), momentum().z()};
1865 double tofest(0);
1866 double phi = fmod(phi0() + M_PI4, M_PI2);
1867 double csf0 = cos(phi);
1868 double snf0 = (1. - csf0) * (1. + csf0);
1869 snf0 = sqrt((snf0 > 0.) ? snf0 : 0.);
1870 if(phi > M_PI) snf0 = - snf0;
1871 if (Tof_correc_){
1872 double t = tanl();
1873 double dphi(0);
1874
1875 Helix work = *(Helix*)this;
1876 work.ignoreErrorMatrix();
1877 double phi_ip(0);
1878 Hep3Vector ip(0, 0, 0);
1879 work.pivot(ip);
1880 phi_ip = work.phi0();
1881 if (fabs(phi - phi_ip) > M_PI) {
1882 if (phi > phi_ip) phi -= 2 * M_PI;
1883 else phi_ip -= 2 * M_PI;
1884 }
1885 dphi = phi - phi_ip;
1886 double l = fabs(radius() * dphi * sqrt(1 + t * t));
1887 double pmag( sqrt( 1.0 + t*t ) / kappa());
1888 double mass_over_p( mass_ / pmag );
1889 double beta( 1.0 / sqrt( 1.0 + mass_over_p * mass_over_p ) );
1890 tofest = l / ( 29.9792458 * beta );
1891 if(csmflag==1 && HitMdc.wire().y()>0.) tofest= -1. * tofest;
1892 }
1893
1894 const HepSymMatrix& ea = Ea();
1895 const HepVector& v_a = a();
1896 double dchi2R(99999999), dchi2L(99999999);
1897
1898 HepVector v_H(5, 0);
1899 v_H[0] = -csf0 * meas.x() - snf0 * meas.y();
1900 v_H[3] = -meas.z();
1901 HepMatrix v_HT = v_H.T();
1902
1903 double estim = (v_HT * v_a)[0];
1904 dtrack = estim;
1905 // std::cout<<" in update_hits estim is "<<estim<<std::endl;
1906 HepVector ea_v_H = ea * v_H;
1907 HepMatrix ea_v_HT = (ea_v_H).T();
1908 HepVector v_H_T_ea_v_H = v_HT * ea_v_H;
1909
1910 HepSymMatrix eaNewL(5), eaNewR(5);
1911 HepVector aNewL(5), aNewR(5);
1912
1913 double drifttime = getDriftTime(HitMdc , tofest);
1914 double ddl = getDriftDist(HitMdc, drifttime, 0 );
1915 double ddr = getDriftDist(HitMdc, drifttime, 1 );
1916 double erddl = getSigma( HitMdc, a()[4], 0, ddl);
1917 double erddr = getSigma( HitMdc, a()[4], 1, ddr);
1918
1919 if(debug_ == 4) {
1920 std::cout<<"drifttime in update_hits() for ananlysis is "<<drifttime<<std::endl;
1921 std::cout<<"ddl in update_hits() for ananlysis is "<<ddl<<std::endl;
1922 std::cout<<"ddr in update_hits() for ananlysis is "<<ddr<<std::endl;
1923 std::cout<<"erddl in update_hits() for ananlysis is "<<erddl<<std::endl;
1924 std::cout<<"erddr in update_hits() for ananlysis is "<<erddr<<std::endl;
1925 }
1926
1927 //the following 3 line : tempory
1928 double dmeas2[2] = { 0.1*ddl, 0.1*ddr }; // millimeter to centimeter
1929 double er_dmeas2[2] = {0.,0.};
1930 if(resolflag_ == 1) {
1931 er_dmeas2[0] = 0.1*erddl;
1932 er_dmeas2[1] = 0.1*erddr;
1933 }
1934 else if(resolflag_ == 0) {
1935 // int layid = HitMdc.wire().layer().layerId();
1936 // double sigma = getSigma(layid, dd);
1937 // er_dmeas2[0] = er_dmeas2[1] = sigma;
1938 }
1939
1940 // Left hypothesis :
1941 if ((LR_==0 && lr != 1.0) ||
1942 (LR_==1 && lr == -1.0)) {
1943 double er_dmeasL, dmeasL;
1944 if(Tof_correc_) {
1945 dmeasL = (-1.0)*fabs(dmeas2[0]);
1946 er_dmeasL = er_dmeas2[0];
1947 } else {
1948 dmeasL = (-1.0)*fabs(HitMdc.dist()[0]);
1949 er_dmeasL = HitMdc.erdist()[0];
1950 }
1951 dtdc = dmeasL;
1952 double AL = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasL*er_dmeasL);
1953 eaNewL.assign(ea - ea_v_H * AL * ea_v_HT);
1954 double RkL = 1 - (v_H_T_ea_v_H)[0] * AL;
1955 if(debug_ == 4){
1956 std::cout<<" ea_v_H * AL * ea_v_HT is: "<<ea_v_H * AL * ea_v_HT<<std::endl;
1957 std::cout<<" v_H is: "<<v_H<<" Ea is: "<<ea<<" v_H_T_ea_v_H is: "<<v_H_T_ea_v_H<<std::endl;
1958 std::cout<<" AL is: "<<AL<<" (v_H_T_ea_v_H)[0] * AL is: "<<(v_H_T_ea_v_H)[0]*AL<<std::endl;
1959 }
1960
1961 if(0. == RkL) RkL = 1.e-4;
1962
1963 HepVector diffL = ea_v_H * AL * (dmeasL - estim);
1964 aNewL = v_a + diffL;
1965 double sigL = dmeasL -(v_HT * aNewL)[0];
1966 dtracknew = (v_HT * aNewL)[0];
1967 dchi2L = (sigL * sigL)/(RkL * er_dmeasL*er_dmeasL);
1968
1969 if(debug_ == 4){
1970 std::cout<<" fwd_filter : in left hypothesis dchi2L is "<<dchi2L<<std::endl;
1971 }
1972 }
1973
1974 if ((LR_==0 && lr != -1.0) ||
1975 (LR_==1 && lr == 1.0)) {
1976 double er_dmeasR, dmeasR;
1977 if(Tof_correc_) {
1978 dmeasR = dmeas2[1];
1979 er_dmeasR = er_dmeas2[1];
1980 } else {
1981 dmeasR = fabs(HitMdc.dist()[1]);
1982 er_dmeasR = HitMdc.erdist()[1];
1983 }
1984 dtdc = dmeasR;
1985 double AR = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasR*er_dmeasR);
1986 eaNewR.assign(ea - ea_v_H * AR * ea_v_HT);
1987 double RkR = 1 - (v_H_T_ea_v_H)[0] * AR;
1988
1989 if(debug_ == 4){
1990 std::cout<<" ea_v_H * AR * ea_v_HT is: "<<ea_v_H * AR * ea_v_HT<<std::endl;
1991 std::cout<<" v_H is: "<<v_H<<" Ea is: "<<ea<<" v_H_T_ea_v_H is: "<<v_H_T_ea_v_H<<std::endl;
1992 std::cout<<" AR is: "<<AR<<" (v_H_T_ea_v_H)[0] * AR is: "<<(v_H_T_ea_v_H)[0]*AR<<std::endl;
1993 }
1994
1995 if(0. == RkR) RkR = 1.e-4;
1996 HepVector diffR = ea_v_H * AR * (dmeasR - estim);
1997 aNewR = v_a + diffR;
1998 double sigR = dmeasR -(v_HT * aNewR)[0];
1999 dtracknew = (v_HT * aNewR)[0];
2000 dchi2R = (sigR*sigR)/(RkR * er_dmeasR*er_dmeasR);
2001 if(debug_ == 4){
2002 std::cout<<" fwd_filter : in right hypothesis dchi2R is "<<dchi2R<<std::endl;
2003 }
2004 }
2005 // Update Kalman result :
2006 double dchi2_loc(0);
2007 if (fabs(dchi2R-dchi2L)<10. && inext>0) {
2008 KalFitHitMdc & HitMdc_next = HitsMdc_[inext];
2009 Helix H_fromR(pivot(), aNewR, eaNewR);
2010 double chi2_fromR(chi2_next(H_fromR, HitMdc_next, csmflag));
2011 Helix H_fromL(pivot(), aNewL, eaNewL);
2012 double chi2_fromL(chi2_next(H_fromL, HitMdc_next, csmflag));
2013#ifdef YDEBUG
2014 std::cout << " chi2_fromL = " << chi2_fromL
2015 << ", chi2_fromR = " << chi2_fromR << std::endl;
2016#endif
2017 if (fabs(chi2_fromR-chi2_fromL)<10.){
2018 int inext2(-1);
2019 if (inext+1<HitsMdc_.size())
2020 for( int k=inext+1 ; k < HitsMdc_.size(); k++ )
2021 if (!(HitsMdc_[k].chi2()<0)) {
2022 inext2 = k;
2023 break;
2024 }
2025
2026 if (inext2 != -1){
2027 KalFitHitMdc & HitMdc_next2 = HitsMdc_[inext2];
2028 double chi2_fromR2(chi2_next(H_fromR, HitMdc_next2, csmflag));
2029 double chi2_fromL2(chi2_next(H_fromL, HitMdc_next2, csmflag));
2030#ifdef YDEBUG
2031 std::cout << " chi2_fromL2 = " << chi2_fromL2
2032 << ", chi2_fromR2 = " << chi2_fromR2 << std::endl;
2033#endif
2034 if (fabs(dchi2R+chi2_fromR+chi2_fromR2-(dchi2L+chi2_fromL+chi2_fromL2))<2) {
2035 if (chi2_fromR2<chi2_fromL2)
2036 dchi2L = DBL_MAX;
2037 else
2038 dchi2R = DBL_MAX;
2039 }
2040 }
2041 }
2042
2043 if (!(dchi2L == DBL_MAX && dchi2R == DBL_MAX)) {
2044 if (dchi2R+chi2_fromR < dchi2L+chi2_fromL){
2045 dchi2L = DBL_MAX;
2046#ifdef YDEBUG
2047 std::cout << " choose right..." << std::endl;
2048#endif
2049 } else {
2050 dchi2R = DBL_MAX;
2051#ifdef YDEBUG
2052 std::cout << " choose left..." << std::endl;
2053#endif
2054 }
2055 }
2056 }
2057 if ((0 < dchi2R && dchi2R < dchi2cutf_anal[layerid]) ||
2058 (0 < dchi2L && dchi2L < dchi2cutf_anal[layerid])) {
2059
2060 if (((LR_==0 && dchi2R < dchi2L && lr != -1) ||
2061 (LR_==1 && lr == 1)) &&
2062 fabs(aNewR[2]-a()[2]) < 1000. && aNewR[2]) {
2063 if (nchits_ < (unsigned) nmdc_hit2_ || dchi2R < dchi2cutf_anal[layerid]){
2064 nchits_++;
2065 if (flag_ster) nster_++;
2066 Ea(eaNewR);
2067 a(aNewR);
2068 chiSq_ += dchi2R;
2069 dchi2_loc = dchi2R;
2070 if (l_mass_ == lead_){
2071 HitMdc.LR(1);
2072 }
2074 }
2075 } else if (((LR_==0 && dchi2L <= dchi2R && lr != 1) ||
2076 (LR_==1 && lr == -1)) &&
2077 fabs(aNewL[2]-a()[2]) < 1000. && aNewL[2]){
2078 if (nchits_ < (unsigned) nmdc_hit2_ || dchi2L < dchi2cutf_anal[layerid]){
2079 nchits_++;
2080 if (flag_ster) nster_++;
2081 Ea(eaNewL);
2082 a(aNewL);
2083 chiSq_ += dchi2L;
2084 dchi2_loc = dchi2L;
2085 if (l_mass_ == lead_){
2086 HitMdc.LR(-1);
2087 }
2089 }
2090 }
2091 }
2092 if (dchi2_loc > dchi2_max_) {
2093 dchi2_max_ = dchi2_loc ;
2094 r_max_ = pivot().perp();
2095 }
2096 dchi2out = dchi2_loc;
2097 //if(dchi2out == 0) {
2098 // dchi2out = ( (dchi2L < dchi2R ) ? dchi2L : dchi2R ) ;
2099 // }
2100 return chiSq_;
2101}
2102
2103
2104double KalFitTrack::update_hits_csmalign(KalFitHelixSeg& HelixSeg, int inext, Hep3Vector& meas,int way, double& dchi2out, int csmflag ) {
2105
2106
2107 HepPoint3D ip(0.,0.,0.);
2108
2110 double lr = HitMdc->LR();
2111 int layerid = (*HitMdc).wire().layer().layerId();
2112 // cout<<"layerid: "<<layerid<<endl;
2113 double entrangle = HitMdc->rechitptr()->getEntra();
2114
2115 if(debug_ == 4) {
2116 std::cout<<"in update_hits(kalFitHelixSeg,...) : the layerid ="<<layerid<<std::endl;
2117 std::cout<<" update_hits: lr= " << lr <<std::endl;
2118 }
2119 // For taking the propagation delay into account :
2120 const KalFitWire& Wire = HitMdc->wire();
2121 int wire_ID = Wire.geoID();
2122
2123 if (wire_ID<0 || wire_ID>6796){ //bes
2124 std::cout << " KalFitTrack: wire_ID problem : " << wire_ID
2125 << std::endl;
2126 return 0;
2127 }
2128 int flag_ster = Wire.stereo();
2129 double x[3] ={pivot().x(), pivot().y(), pivot().z()};
2130 double pmom[3] ={momentum().x(), momentum().y(), momentum().z()};
2131 double tofest(0);
2132 double phi = fmod(phi0() + M_PI4, M_PI2);
2133 double csf0 = cos(phi);
2134 double snf0 = (1. - csf0) * (1. + csf0);
2135 snf0 = sqrt((snf0 > 0.) ? snf0 : 0.);
2136 if(phi > M_PI) snf0 = - snf0;
2137 if (Tof_correc_){
2138 double t = tanl();
2139 double dphi(0);
2140
2141 Helix work = *(Helix*)this;
2142 work.ignoreErrorMatrix();
2143 double phi_ip(0);
2144 Hep3Vector ip(0, 0, 0);
2145 work.pivot(ip);
2146 phi_ip = work.phi0();
2147 if (fabs(phi - phi_ip) > M_PI) {
2148 if (phi > phi_ip) phi -= 2 * M_PI;
2149 else phi_ip -= 2 * M_PI;
2150 }
2151 dphi = phi - phi_ip;
2152
2153 double l = fabs(radius() * dphi * sqrt(1 + t * t));
2154 double pmag( sqrt( 1.0 + t*t ) / kappa());
2155 double mass_over_p( mass_ / pmag );
2156 double beta( 1.0 / sqrt( 1.0 + mass_over_p * mass_over_p ) );
2157 tofest = l / ( 29.9792458 * beta );
2158 if(csmflag==1 && (*HitMdc).wire().y()>0.) tofest= -1. * tofest;
2159 }
2160
2161 const HepSymMatrix& ea = Ea();
2162 HelixSeg.Ea_pre_fwd(ea);
2164
2165
2166 const HepVector& v_a = a();
2167 HelixSeg.a_pre_fwd(v_a);
2168 HelixSeg.a_filt_fwd(v_a);
2169
2170 /*
2171
2172 HepPoint3D pivot_work = pivot();
2173 HepVector a_work = a();
2174 HepSymMatrix ea_work = Ea();
2175 KalFitTrack helix_work(pivot_work, a_work, ea_work, 0, 0, 0);
2176 helix_work.pivot(ip);
2177
2178 HepVector a_temp = helix_work.a();
2179 HepSymMatrix ea_temp = helix_work.Ea();
2180
2181 HelixSeg.Ea_pre_fwd(ea_temp);
2182 HelixSeg.a_pre_fwd(a_temp);
2183
2184 // My God, for the protection purpose
2185 HelixSeg.Ea_filt_fwd(ea_temp);
2186 HelixSeg.a_filt_fwd(a_temp);
2187
2188 */
2189
2190 double dchi2R(99999999), dchi2L(99999999);
2191
2192 HepVector v_H(5, 0);
2193 v_H[0] = -csf0 * meas.x() - snf0 * meas.y();
2194 v_H[3] = -meas.z();
2195 HepMatrix v_HT = v_H.T();
2196
2197 double estim = (v_HT * v_a)[0];
2198 HepVector ea_v_H = ea * v_H;
2199 HepMatrix ea_v_HT = (ea_v_H).T();
2200 HepVector v_H_T_ea_v_H = v_HT * ea_v_H;
2201
2202 HepSymMatrix eaNewL(5), eaNewR(5);
2203 HepVector aNewL(5), aNewR(5);
2204#ifdef YDEBUG
2205 cout<<"phi "<<phi<<" snf0 "<<snf0<<" csf0 "<<csf0<<endl
2206 <<" meas: "<<meas <<endl;
2207 cout<<"the related matrix:"<<endl;
2208 cout<<"v_H "<<v_H<<endl;
2209 cout<<"v_a "<<v_a<<endl;
2210 cout<<"ea "<<ea<<endl;
2211 cout<<"v_H_T_ea_v_H "<<v_H_T_ea_v_H<<endl;
2212 cout<<"LR_= "<< LR_ << "lr= " << lr <<endl;
2213#endif
2214
2215 double time = (*HitMdc).tdc();
2216 // if (Tof_correc_)
2217 // time = time - way*tofest;
2218
2219 // double dd = 1.0e-4 * 40.0 * time;
2220 //the following 3 line : tempory
2221
2222 double drifttime = getDriftTime(*HitMdc , tofest);
2223 double ddl = getDriftDist(*HitMdc, drifttime, 0 );
2224 double ddr = getDriftDist(*HitMdc, drifttime, 1 );
2225 double erddl = getSigma( *HitMdc, a()[4], 0, ddl);
2226 double erddr = getSigma( *HitMdc, a()[4], 1, ddr);
2227
2228 if(debug_ == 4){
2229 std::cout<<"the pure drift time is "<<drifttime<<std::endl;
2230 std::cout<<"the drift dist left hypothesis is "<<ddl<<std::endl;
2231 std::cout<<"the drift dist right hypothesis is "<<ddr<<std::endl;
2232 std::cout<<"the error sigma left hypothesis is "<<erddl<<std::endl;
2233 std::cout<<"the error sigma right hypothesis is "<<erddr<<std::endl;
2234 }
2235 double dmeas2[2] = { 0.1*ddl , 0.1*ddr }; //millimeter to centimeter
2236 double er_dmeas2[2] = {0. , 0.} ;
2237
2238 if(resolflag_ == 1) {
2239 er_dmeas2[0] = 0.1*erddl;
2240 er_dmeas2[1] = 0.1*erddr;
2241 }
2242 else if(resolflag_ == 0) {
2243 // int layid = (*HitMdc).wire().layer().layerId();
2244 // double sigma = getSigma(layid, dd);
2245 // er_dmeas2[0] = er_dmeas2[1] = sigma;
2246 }
2247
2248 // Left hypothesis :
2249 if ((LR_==0 && lr != 1.0) ||
2250 (LR_==1 && lr == -1.0)) {
2251
2252 double er_dmeasL, dmeasL;
2253 if(Tof_correc_) {
2254 dmeasL = (-1.0)*fabs(dmeas2[0]);
2255 er_dmeasL = er_dmeas2[0];
2256 } else {
2257 dmeasL = (-1.0)*fabs((*HitMdc).dist()[0]);
2258 er_dmeasL = (*HitMdc).erdist()[0];
2259 }
2260
2261 double AL = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasL*er_dmeasL);
2262 eaNewL.assign(ea - ea_v_H * AL * ea_v_HT);
2263 double RkL = 1 - (v_H_T_ea_v_H)[0] * AL;
2264 if(0. == RkL) RkL = 1.e-4;
2265
2266 HepVector diffL = ea_v_H * AL * (dmeasL - estim);
2267
2268 aNewL = v_a + diffL;
2269 double sigL = dmeasL -(v_HT * aNewL)[0];
2270 dchi2L = (sigL * sigL) / (RkL * er_dmeasL*er_dmeasL);
2271 }
2272
2273 if ((LR_==0 && lr != -1.0) ||
2274 (LR_==1 && lr == 1.0)) {
2275
2276 double er_dmeasR, dmeasR;
2277 if(Tof_correc_) {
2278 dmeasR = dmeas2[1];
2279 er_dmeasR = er_dmeas2[1];
2280 } else {
2281 dmeasR = fabs((*HitMdc).dist()[1]);
2282 er_dmeasR = (*HitMdc).erdist()[1];
2283 }
2284
2285 double AR = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasR*er_dmeasR);
2286 eaNewR.assign(ea - ea_v_H * AR * ea_v_HT);
2287 double RkR = 1 - (v_H_T_ea_v_H)[0] * AR;
2288 if(0. == RkR) RkR = 1.e-4;
2289
2290 HepVector diffR = ea_v_H * AR * (dmeasR - estim);
2291
2292 aNewR = v_a + diffR;
2293 double sigR = dmeasR -(v_HT * aNewR)[0];
2294 dchi2R = (sigR*sigR) / (RkR * er_dmeasR*er_dmeasR);
2295 }
2296
2297 // Update Kalman result :
2298 double dchi2_loc(0);
2299
2300#ifdef YDEBUG
2301 cout<<" track::update_hits......"<<endl;
2302 std::cout << " dchi2R = " << dchi2R << ", dchi2L = " << dchi2L
2303 << " estimate = "<<estim<< std::endl;
2304 std::cout << " dmeasR = " << dmeas2[1]
2305 << ", dmeasL = " << (-1.0)*fabs(dmeas2[0]) << ", check HitMdc.ddl = "
2306 << (*HitMdc).dist()[0] << std::endl;
2307 std::cout<<"dchi2L : "<<dchi2L<<" ,dchi2R: "<<dchi2R<<std::endl;
2308#endif
2309
2310
2311 if (fabs(dchi2R-dchi2L)<10. && inext>0) {
2312
2313 KalFitHitMdc & HitMdc_next = HitsMdc_[inext];
2314
2315 Helix H_fromR(pivot(), aNewR, eaNewR);
2316 double chi2_fromR(chi2_next(H_fromR, HitMdc_next,csmflag));
2317 //double chi2_fromR(chi2_next(H_fromR, HitMdc_next));
2318
2319 Helix H_fromL(pivot(), aNewL, eaNewL);
2320 double chi2_fromL(chi2_next(H_fromL, HitMdc_next,csmflag));
2321 //double chi2_fromL(chi2_next(H_fromL, HitMdc_next));
2322#ifdef YDEBUG
2323 std::cout << " chi2_fromL = " << chi2_fromL
2324 << ", chi2_fromR = " << chi2_fromR << std::endl;
2325#endif
2326 if (fabs(chi2_fromR-chi2_fromL)<10.){
2327 int inext2(-1);
2328 if (inext+1<HitsMdc_.size())
2329 for( int k=inext+1 ; k < HitsMdc_.size(); k++ )
2330 if (!(HitsMdc_[k].chi2()<0)) {
2331 inext2 = k;
2332 break;
2333 }
2334
2335 if (inext2 != -1){
2336 KalFitHitMdc & HitMdc_next2 = HitsMdc_[inext2];
2337 // double chi2_fromR2(chi2_next(H_fromR, HitMdc_next2));
2338 // double chi2_fromL2(chi2_next(H_fromL, HitMdc_next2));
2339 double chi2_fromR2(chi2_next(H_fromR, HitMdc_next2, csmflag));
2340 double chi2_fromL2(chi2_next(H_fromL, HitMdc_next2, csmflag));
2341#ifdef YDEBUG
2342 std::cout << " chi2_fromL2 = " << chi2_fromL2
2343 << ", chi2_fromR2 = " << chi2_fromR2 << std::endl;
2344#endif
2345 if (fabs(dchi2R+chi2_fromR+chi2_fromR2-(dchi2L+chi2_fromL+chi2_fromL2))<2) {
2346 if (chi2_fromR2<chi2_fromL2)
2347 dchi2L = DBL_MAX;
2348 else
2349 dchi2R = DBL_MAX;
2350 }
2351 }
2352 }
2353
2354 if (!(dchi2L == DBL_MAX && dchi2R == DBL_MAX)) {
2355 if (dchi2R+chi2_fromR < dchi2L+chi2_fromL){
2356 dchi2L = DBL_MAX;
2357#ifdef YDEBUG
2358 std::cout << " choose right..." << std::endl;
2359#endif
2360 } else {
2361 dchi2R = DBL_MAX;
2362#ifdef YDEBUG
2363 std::cout << " choose left..." << std::endl;
2364#endif
2365 }
2366 }
2367 }
2368
2369 if ((0 < dchi2R && dchi2R < dchi2cutf_calib[layerid]) ||
2370 (0 < dchi2L && dchi2L < dchi2cutf_calib[layerid])) {
2371
2372 if (((LR_==0 && dchi2R < dchi2L && lr != -1) ||
2373 (LR_==1 && lr == 1)) &&
2374 fabs(aNewR[2]-a()[2]) < 1000. && aNewR[2]) {
2375 if (nchits_ < (unsigned) nmdc_hit2_ || dchi2R < dchi2cutf_calib[layerid]){
2376 nchits_++;
2377 if (flag_ster) nster_++;
2378 if(layerid>19){
2379 Ea(eaNewR);
2380 HelixSeg.Ea_filt_fwd(eaNewR);
2381 a(aNewR);
2382 HelixSeg.a_filt_fwd(aNewR);
2383 }
2384 /*
2385 Ea(eaNewR);
2386 a(aNewR);
2387
2388 KalFitTrack helixR(pivot_work, aNewR, eaNewR, 0, 0, 0);
2389 helixR.pivot(ip);
2390
2391 a_temp = helixR.a();
2392 ea_temp = helixR.Ea();
2393
2394 HelixSeg.Ea_filt_fwd(ea_temp);
2395 HelixSeg.a_filt_fwd(a_temp);
2396 //HelixSeg.filt_include(1);
2397
2398 */
2399
2400 chiSq_ += dchi2R;
2401 dchi2_loc = dchi2R;
2402 if (l_mass_ == lead_){
2403 (*HitMdc).LR(1);
2404 HelixSeg.LR(1);
2405 }
2406 update_bit((*HitMdc).wire().layer().layerId());
2407 }
2408 } else if (((LR_==0 && dchi2L <= dchi2R && lr != 1) ||
2409 (LR_==1 && lr == -1)) &&
2410 fabs(aNewL[2]-a()[2]) < 1000. && aNewL[2]){
2411 if (nchits_ < (unsigned) nmdc_hit2_ || dchi2L < dchi2cutf_calib[layerid]){
2412 nchits_++;
2413 if (flag_ster) nster_++;
2414 if(layerid>19){
2415 Ea(eaNewL);
2416 HelixSeg.Ea_filt_fwd(eaNewL);
2417 a(aNewL);
2418 HelixSeg.a_filt_fwd(aNewL);
2419 }
2420
2421 /*
2422 Ea(eaNewL);
2423 a(aNewL);
2424
2425 KalFitTrack helixL(pivot_work, aNewL, eaNewL, 0, 0, 0);
2426 helixL.pivot(ip);
2427 a_temp = helixL.a();
2428 ea_temp = helixL.Ea();
2429 HelixSeg.Ea_filt_fwd(ea_temp);
2430 HelixSeg.a_filt_fwd(a_temp);
2431 //HelixSeg.filt_include(1);
2432
2433 */
2434
2435 chiSq_ += dchi2L;
2436 dchi2_loc = dchi2L;
2437 if (l_mass_ == lead_){
2438 (*HitMdc).LR(-1);
2439 HelixSeg.LR(-1);
2440 }
2441 update_bit((*HitMdc).wire().layer().layerId());
2442 }
2443 }
2444 }
2445
2446 if (dchi2_loc > dchi2_max_) {
2447 dchi2_max_ = dchi2_loc ;
2448 r_max_ = pivot().perp();
2449 }
2450 dchi2out = dchi2_loc;
2451 // if(dchi2out == 0) {
2452 // dchi2out = ( (dchi2L < dchi2R ) ? dchi2L : dchi2R ) ;
2453 // }
2454 return chiSq_;
2455}
2456
2457
2458double KalFitTrack::update_hits(KalFitHelixSeg& HelixSeg, int inext, Hep3Vector& meas,int way, double& dchi2out, int csmflag) {
2459
2460
2461 HepPoint3D ip(0.,0.,0.);
2462
2464 double lr = HitMdc->LR();
2465 int layerid = (*HitMdc).wire().layer().layerId();
2466 double entrangle = HitMdc->rechitptr()->getEntra();
2467
2468 if(debug_ == 4) {
2469 std::cout<<"in update_hits(kalFitHelixSeg,...) : the layerid ="<<layerid<<std::endl;
2470 std::cout<<" update_hits: lr= " << lr <<std::endl;
2471 }
2472 // For taking the propagation delay into account :
2473 const KalFitWire& Wire = HitMdc->wire();
2474 int wire_ID = Wire.geoID();
2475
2476 if (wire_ID<0 || wire_ID>6796){ //bes
2477 std::cout << " KalFitTrack: wire_ID problem : " << wire_ID
2478 << std::endl;
2479 return 0;
2480 }
2481 int flag_ster = Wire.stereo();
2482 double x[3] ={pivot().x(), pivot().y(), pivot().z()};
2483 double pmom[3] ={momentum().x(), momentum().y(), momentum().z()};
2484 double tofest(0);
2485 double phi = fmod(phi0() + M_PI4, M_PI2);
2486 double csf0 = cos(phi);
2487 double snf0 = (1. - csf0) * (1. + csf0);
2488 snf0 = sqrt((snf0 > 0.) ? snf0 : 0.);
2489 if(phi > M_PI) snf0 = - snf0;
2490 if (Tof_correc_){
2491 double t = tanl();
2492 double dphi(0);
2493
2494 Helix work = *(Helix*)this;
2495 work.ignoreErrorMatrix();
2496 double phi_ip(0);
2497 Hep3Vector ip(0, 0, 0);
2498 work.pivot(ip);
2499 phi_ip = work.phi0();
2500 if (fabs(phi - phi_ip) > M_PI) {
2501 if (phi > phi_ip) phi -= 2 * M_PI;
2502 else phi_ip -= 2 * M_PI;
2503 }
2504 dphi = phi - phi_ip;
2505
2506 double l = fabs(radius() * dphi * sqrt(1 + t * t));
2507 double pmag( sqrt( 1.0 + t*t ) / kappa());
2508 double mass_over_p( mass_ / pmag );
2509 double beta( 1.0 / sqrt( 1.0 + mass_over_p * mass_over_p ) );
2510 tofest = l / ( 29.9792458 * beta );
2511 if(csmflag==1 && (*HitMdc).wire().y()>0.) tofest= -1. * tofest;
2512 }
2513
2514 const HepSymMatrix& ea = Ea();
2515 HelixSeg.Ea_pre_fwd(ea);
2517
2518
2519 const HepVector& v_a = a();
2520 HelixSeg.a_pre_fwd(v_a);
2521 HelixSeg.a_filt_fwd(v_a);
2522
2523 /*
2524
2525 HepPoint3D pivot_work = pivot();
2526 HepVector a_work = a();
2527 HepSymMatrix ea_work = Ea();
2528 KalFitTrack helix_work(pivot_work, a_work, ea_work, 0, 0, 0);
2529 helix_work.pivot(ip);
2530
2531 HepVector a_temp = helix_work.a();
2532 HepSymMatrix ea_temp = helix_work.Ea();
2533
2534 HelixSeg.Ea_pre_fwd(ea_temp);
2535 HelixSeg.a_pre_fwd(a_temp);
2536
2537 // My God, for the protection purpose
2538 HelixSeg.Ea_filt_fwd(ea_temp);
2539 HelixSeg.a_filt_fwd(a_temp);
2540
2541 */
2542
2543
2544 double dchi2R(99999999), dchi2L(99999999);
2545
2546 HepVector v_H(5, 0);
2547 v_H[0] = -csf0 * meas.x() - snf0 * meas.y();
2548 v_H[3] = -meas.z();
2549 HepMatrix v_HT = v_H.T();
2550
2551 double estim = (v_HT * v_a)[0];
2552 HepVector ea_v_H = ea * v_H;
2553 HepMatrix ea_v_HT = (ea_v_H).T();
2554 HepVector v_H_T_ea_v_H = v_HT * ea_v_H;
2555
2556 HepSymMatrix eaNewL(5), eaNewR(5);
2557 HepVector aNewL(5), aNewR(5);
2558#ifdef YDEBUG
2559 cout<<"phi "<<phi<<" snf0 "<<snf0<<" csf0 "<<csf0<<endl
2560 <<" meas: "<<meas <<endl;
2561 cout<<"the related matrix:"<<endl;
2562 cout<<"v_H "<<v_H<<endl;
2563 cout<<"v_a "<<v_a<<endl;
2564 cout<<"ea "<<ea<<endl;
2565 cout<<"v_H_T_ea_v_H "<<v_H_T_ea_v_H<<endl;
2566 cout<<"LR_= "<< LR_ << "lr= " << lr <<endl;
2567#endif
2568
2569 double time = (*HitMdc).tdc();
2570 // if (Tof_correc_)
2571 // time = time - way*tofest;
2572
2573 // double dd = 1.0e-4 * 40.0 * time;
2574 //the following 3 line : tempory
2575
2576 double drifttime = getDriftTime(*HitMdc , tofest);
2577 double ddl = getDriftDist(*HitMdc, drifttime, 0 );
2578 double ddr = getDriftDist(*HitMdc, drifttime, 1 );
2579 double erddl = getSigma( *HitMdc, a()[4], 0, ddl);
2580 double erddr = getSigma( *HitMdc, a()[4], 1, ddr);
2581
2582 if(debug_ == 4){
2583 std::cout<<"the pure drift time is "<<drifttime<<std::endl;
2584 std::cout<<"the drift dist left hypothesis is "<<ddl<<std::endl;
2585 std::cout<<"the drift dist right hypothesis is "<<ddr<<std::endl;
2586 std::cout<<"the error sigma left hypothesis is "<<erddl<<std::endl;
2587 std::cout<<"the error sigma right hypothesis is "<<erddr<<std::endl;
2588 }
2589 double dmeas2[2] = { 0.1*ddl , 0.1*ddr }; //millimeter to centimeter
2590 double er_dmeas2[2] = {0. , 0.} ;
2591
2592 if(resolflag_ == 1) {
2593 er_dmeas2[0] = 0.1*erddl;
2594 er_dmeas2[1] = 0.1*erddr;
2595 }
2596 else if(resolflag_ == 0) {
2597 // int layid = (*HitMdc).wire().layer().layerId();
2598 // double sigma = getSigma(layid, dd);
2599 // er_dmeas2[0] = er_dmeas2[1] = sigma;
2600 }
2601
2602 // Left hypothesis :
2603 if ((LR_==0 && lr != 1.0) ||
2604 (LR_==1 && lr == -1.0)) {
2605
2606 double er_dmeasL, dmeasL;
2607 if(Tof_correc_) {
2608 dmeasL = (-1.0)*fabs(dmeas2[0]);
2609 er_dmeasL = er_dmeas2[0];
2610 } else {
2611 dmeasL = (-1.0)*fabs((*HitMdc).dist()[0]);
2612 er_dmeasL = (*HitMdc).erdist()[0];
2613 }
2614
2615 double AL = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasL*er_dmeasL);
2616 eaNewL.assign(ea - ea_v_H * AL * ea_v_HT);
2617 double RkL = 1 - (v_H_T_ea_v_H)[0] * AL;
2618 if(0. == RkL) RkL = 1.e-4;
2619
2620 HepVector diffL = ea_v_H * AL * (dmeasL - estim);
2621
2622 aNewL = v_a + diffL;
2623 double sigL = dmeasL -(v_HT * aNewL)[0];
2624 dchi2L = (sigL * sigL) / (RkL * er_dmeasL*er_dmeasL);
2625 }
2626
2627 if ((LR_==0 && lr != -1.0) ||
2628 (LR_==1 && lr == 1.0)) {
2629
2630 double er_dmeasR, dmeasR;
2631 if(Tof_correc_) {
2632 dmeasR = dmeas2[1];
2633 er_dmeasR = er_dmeas2[1];
2634 } else {
2635 dmeasR = fabs((*HitMdc).dist()[1]);
2636 er_dmeasR = (*HitMdc).erdist()[1];
2637 }
2638
2639 double AR = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasR*er_dmeasR);
2640 eaNewR.assign(ea - ea_v_H * AR * ea_v_HT);
2641 double RkR = 1 - (v_H_T_ea_v_H)[0] * AR;
2642 if(0. == RkR) RkR = 1.e-4;
2643
2644 HepVector diffR = ea_v_H * AR * (dmeasR - estim);
2645
2646 aNewR = v_a + diffR;
2647 double sigR = dmeasR -(v_HT * aNewR)[0];
2648 dchi2R = (sigR*sigR) / (RkR * er_dmeasR*er_dmeasR);
2649 }
2650
2651 // Update Kalman result :
2652 double dchi2_loc(0);
2653
2654#ifdef YDEBUG
2655 cout<<" track::update_hits......"<<endl;
2656 std::cout << " dchi2R = " << dchi2R << ", dchi2L = " << dchi2L
2657 << " estimate = "<<estim<< std::endl;
2658 std::cout << " dmeasR = " << dmeas2[1]
2659 << ", dmeasL = " << (-1.0)*fabs(dmeas2[0]) << ", check HitMdc.ddl = "
2660 << (*HitMdc).dist()[0] << std::endl;
2661#endif
2662
2663 if (fabs(dchi2R-dchi2L)<10. && inext>0) {
2664
2665 KalFitHitMdc & HitMdc_next = HitsMdc_[inext];
2666
2667 Helix H_fromR(pivot(), aNewR, eaNewR);
2668 double chi2_fromR(chi2_next(H_fromR, HitMdc_next,csmflag));
2669
2670 Helix H_fromL(pivot(), aNewL, eaNewL);
2671 double chi2_fromL(chi2_next(H_fromL, HitMdc_next,csmflag));
2672#ifdef YDEBUG
2673 std::cout << " chi2_fromL = " << chi2_fromL
2674 << ", chi2_fromR = " << chi2_fromR << std::endl;
2675#endif
2676 if (fabs(chi2_fromR-chi2_fromL)<10.){
2677 int inext2(-1);
2678 if (inext+1<HitsMdc_.size())
2679 for( int k=inext+1 ; k < HitsMdc_.size(); k++ )
2680 if (!(HitsMdc_[k].chi2()<0)) {
2681 inext2 = k;
2682 break;
2683 }
2684
2685 if (inext2 != -1){
2686 KalFitHitMdc & HitMdc_next2 = HitsMdc_[inext2];
2687 double chi2_fromR2(chi2_next(H_fromR, HitMdc_next2, csmflag));
2688 double chi2_fromL2(chi2_next(H_fromL, HitMdc_next2, csmflag));
2689#ifdef YDEBUG
2690 std::cout << " chi2_fromL2 = " << chi2_fromL2
2691 << ", chi2_fromR2 = " << chi2_fromR2 << std::endl;
2692#endif
2693 if (fabs(dchi2R+chi2_fromR+chi2_fromR2-(dchi2L+chi2_fromL+chi2_fromL2))<2) {
2694 if (chi2_fromR2<chi2_fromL2)
2695 dchi2L = DBL_MAX;
2696 else
2697 dchi2R = DBL_MAX;
2698 }
2699 }
2700 }
2701
2702 if (!(dchi2L == DBL_MAX && dchi2R == DBL_MAX)) {
2703 if (dchi2R+chi2_fromR < dchi2L+chi2_fromL){
2704 dchi2L = DBL_MAX;
2705#ifdef YDEBUG
2706 std::cout << " choose right..." << std::endl;
2707#endif
2708 } else {
2709 dchi2R = DBL_MAX;
2710#ifdef YDEBUG
2711 std::cout << " choose left..." << std::endl;
2712#endif
2713 }
2714 }
2715 }
2716
2717 if ((0 < dchi2R && dchi2R < dchi2cutf_calib[layerid]) ||
2718 (0 < dchi2L && dchi2L < dchi2cutf_calib[layerid])) {
2719
2720 if (((LR_==0 && dchi2R < dchi2L && lr != -1) ||
2721 (LR_==1 && lr == 1)) &&
2722 fabs(aNewR[2]-a()[2]) < 1000. && aNewR[2]) {
2723 if (nchits_ < (unsigned) nmdc_hit2_ || dchi2R < dchi2cutf_calib[layerid]){
2724 nchits_++;
2725 if (flag_ster) nster_++;
2726
2727 Ea(eaNewR);
2728 HelixSeg.Ea_filt_fwd(eaNewR);
2729 a(aNewR);
2730 HelixSeg.a_filt_fwd(aNewR);
2731
2732 /*
2733 Ea(eaNewR);
2734 a(aNewR);
2735
2736 KalFitTrack helixR(pivot_work, aNewR, eaNewR, 0, 0, 0);
2737 helixR.pivot(ip);
2738
2739 a_temp = helixR.a();
2740 ea_temp = helixR.Ea();
2741
2742 HelixSeg.Ea_filt_fwd(ea_temp);
2743 HelixSeg.a_filt_fwd(a_temp);
2744 //HelixSeg.filt_include(1);
2745
2746 */
2747
2748 chiSq_ += dchi2R;
2749 dchi2_loc = dchi2R;
2750 if (l_mass_ == lead_){
2751 (*HitMdc).LR(1);
2752 HelixSeg.LR(1);
2753 }
2754 update_bit((*HitMdc).wire().layer().layerId());
2755 }
2756 } else if (((LR_==0 && dchi2L <= dchi2R && lr != 1) ||
2757 (LR_==1 && lr == -1)) &&
2758 fabs(aNewL[2]-a()[2]) < 1000. && aNewL[2]){
2759 if (nchits_ < (unsigned) nmdc_hit2_ || dchi2L < dchi2cutf_calib[layerid]){
2760 nchits_++;
2761 if (flag_ster) nster_++;
2762 Ea(eaNewL);
2763 HelixSeg.Ea_filt_fwd(eaNewL);
2764 a(aNewL);
2765 HelixSeg.a_filt_fwd(aNewL);
2766
2767
2768 /*
2769 Ea(eaNewL);
2770 a(aNewL);
2771
2772 KalFitTrack helixL(pivot_work, aNewL, eaNewL, 0, 0, 0);
2773 helixL.pivot(ip);
2774 a_temp = helixL.a();
2775 ea_temp = helixL.Ea();
2776 HelixSeg.Ea_filt_fwd(ea_temp);
2777 HelixSeg.a_filt_fwd(a_temp);
2778 //HelixSeg.filt_include(1);
2779
2780 */
2781
2782 chiSq_ += dchi2L;
2783 dchi2_loc = dchi2L;
2784 if (l_mass_ == lead_){
2785 (*HitMdc).LR(-1);
2786 HelixSeg.LR(-1);
2787 }
2788 update_bit((*HitMdc).wire().layer().layerId());
2789 }
2790 }
2791 }
2792
2793 if (dchi2_loc > dchi2_max_) {
2794 dchi2_max_ = dchi2_loc ;
2795 r_max_ = pivot().perp();
2796 }
2797 dchi2out = dchi2_loc;
2798 // if(dchi2out == 0) {
2799 // dchi2out = ( (dchi2L < dchi2R ) ? dchi2L : dchi2R ) ;
2800 // }
2801 return chiSq_;
2802}
2803
2804
2806
2807 double lr = HitMdc.LR();
2808 const KalFitWire& Wire = HitMdc.wire();
2809 int wire_ID = Wire.geoID();
2810 int layerid = HitMdc.wire().layer().layerId();
2811 double entrangle = HitMdc.rechitptr()->getEntra();
2812
2813 HepPoint3D fwd(Wire.fwd());
2814 HepPoint3D bck(Wire.bck());
2815 Hep3Vector wire = (Hep3Vector)fwd -(Hep3Vector)bck;
2816 Helix work = H;
2817 work.ignoreErrorMatrix();
2818 work.pivot((fwd + bck) * .5);
2819 HepPoint3D x0kal = (work.x(0).z() - bck.z())/ wire.z() * wire + bck;
2820 H.pivot(x0kal);
2821
2822 Hep3Vector meas = H.momentum(0).cross(wire).unit();
2823
2824 if (wire_ID<0 || wire_ID>6796){ //bes
2825 std::cout << "KalFitTrack : wire_ID problem : " << wire_ID
2826 << std::endl;
2827 return DBL_MAX;
2828 }
2829
2830 double x[3] ={pivot().x(), pivot().y(), pivot().z()};
2831 double pmom[3] ={momentum().x(), momentum().y(), momentum().z()};
2832 double tofest(0);
2833 double phi = fmod(phi0() + M_PI4, M_PI2);
2834 double csf0 = cos(phi);
2835 double snf0 = (1. - csf0) * (1. + csf0);
2836 snf0 = sqrt((snf0 > 0.) ? snf0 : 0.);
2837 if(phi > M_PI) snf0 = - snf0;
2838
2839 if (Tof_correc_) {
2840 Hep3Vector ip(0, 0, 0);
2841 Helix work = *(Helix*)this;
2842 work.ignoreErrorMatrix();
2843 work.pivot(ip);
2844 double phi_ip = work.phi0();
2845 if (fabs(phi - phi_ip) > M_PI) {
2846 if (phi > phi_ip) phi -= 2 * M_PI;
2847 else phi_ip -= 2 * M_PI;
2848 }
2849 double t = tanl();
2850 double l = fabs(radius() * (phi - phi_ip) * sqrt(1 + t * t));
2851 double pmag( sqrt( 1.0 + t*t ) / kappa());
2852 double mass_over_p( mass_ / pmag );
2853 double beta( 1.0 / sqrt( 1.0 + mass_over_p * mass_over_p ) );
2854 tofest = l / ( 29.9792458 * beta );
2855 // if(csmflag==1 && HitMdc.wire().y()>0.) tofest= -1. * tofest;
2856 }
2857
2858 const HepSymMatrix& ea = H.Ea();
2859 const HepVector& v_a = H.a();
2860 double dchi2R(DBL_MAX), dchi2L(DBL_MAX);
2861
2862 HepVector v_H(5, 0);
2863 v_H[0] = -csf0 * meas.x() - snf0 * meas.y();
2864 v_H[3] = -meas.z();
2865 HepMatrix v_HT = v_H.T();
2866
2867 double estim = (v_HT * v_a)[0];
2868 HepVector ea_v_H = ea * v_H;
2869 HepMatrix ea_v_HT = (ea_v_H).T();
2870 HepVector v_H_T_ea_v_H = v_HT * ea_v_H;
2871
2872 HepSymMatrix eaNewL(5), eaNewR(5);
2873 HepVector aNewL(5), aNewR(5);
2874
2875 //double time = HitMdc.tdc();
2876 //if (Tof_correc_)
2877 // time = time - tofest;
2878 double drifttime = getDriftTime(HitMdc , tofest);
2879 double ddl = getDriftDist(HitMdc, drifttime , 0 );
2880 double ddr = getDriftDist(HitMdc, drifttime , 1 );
2881 double erddl = getSigma( HitMdc, H.a()[4], 0, ddl);
2882 double erddr = getSigma( HitMdc, H.a()[4], 1, ddr);
2883
2884 double dmeas2[2] = { 0.1*ddl, 0.1*ddr };
2885 double er_dmeas2[2] = {0. , 0.};
2886 if(resolflag_ == 1) {
2887 er_dmeas2[0] = 0.1*erddl;
2888 er_dmeas2[1] = 0.1*erddr;
2889 }
2890 else if(resolflag_ == 0) {
2891 // int layid = HitMdc.wire().layer().layerId();
2892 // double sigma = getSigma(layid, dd);
2893 // er_dmeas2[0] = er_dmeas2[1] = sigma;
2894 }
2895
2896 if ((LR_==0 && lr != 1.0) ||
2897 (LR_==1 && lr == -1.0)) {
2898
2899 double er_dmeasL, dmeasL;
2900 if(Tof_correc_) {
2901 dmeasL = (-1.0)*fabs(dmeas2[0]);
2902 er_dmeasL = er_dmeas2[0];
2903 } else {
2904 dmeasL = (-1.0)*fabs(HitMdc.dist()[0]);
2905 er_dmeasL = HitMdc.erdist()[0];
2906 }
2907
2908 double AL = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasL*er_dmeasL);
2909 eaNewL.assign(ea - ea_v_H * AL * ea_v_HT);
2910 double RkL = 1 - (v_H_T_ea_v_H)[0] * AL;
2911 if(0. == RkL) RkL = 1.e-4;
2912
2913 HepVector diffL = ea_v_H * AL * (dmeasL - estim);
2914 aNewL = v_a + diffL;
2915 double sigL = dmeasL -(v_HT * aNewL)[0];
2916 dchi2L = (sigL * sigL) / (RkL * er_dmeasL*er_dmeasL);
2917 }
2918
2919 if ((LR_==0 && lr != -1.0) ||
2920 (LR_==1 && lr == 1.0)) {
2921
2922 double er_dmeasR, dmeasR;
2923 if(Tof_correc_) {
2924 dmeasR = dmeas2[1];
2925 er_dmeasR = er_dmeas2[1];
2926 } else {
2927 dmeasR = fabs(HitMdc.dist()[1]);
2928 er_dmeasR = HitMdc.erdist()[1];
2929 }
2930
2931 double AR = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasR*er_dmeasR);
2932 eaNewR.assign(ea - ea_v_H * AR * ea_v_HT);
2933 double RkR = 1 - (v_H_T_ea_v_H)[0] * AR;
2934 if(0. == RkR) RkR = 1.e-4;
2935
2936 HepVector diffR = ea_v_H * AR * (dmeasR - estim);
2937 aNewR = v_a + diffR;
2938 double sigR = dmeasR -(v_HT * aNewR)[0];
2939 dchi2R = (sigR*sigR) / (RkR * er_dmeasR*er_dmeasR);
2940 }
2941
2942 if (dchi2R < dchi2L){
2943 H.a(aNewR); H.Ea(eaNewR);
2944 } else {
2945 H.a(aNewL); H.Ea(eaNewL);
2946 }
2947 return ((dchi2R < dchi2L) ? dchi2R : dchi2L);
2948}
2949
2950double KalFitTrack::chi2_next(Helix& H, KalFitHitMdc & HitMdc, int csmflag){
2951
2952 double lr = HitMdc.LR();
2953 const KalFitWire& Wire = HitMdc.wire();
2954 int wire_ID = Wire.geoID();
2955 int layerid = HitMdc.wire().layer().layerId();
2956 double entrangle = HitMdc.rechitptr()->getEntra();
2957
2958 HepPoint3D fwd(Wire.fwd());
2959 HepPoint3D bck(Wire.bck());
2960 Hep3Vector wire = (Hep3Vector)fwd -(Hep3Vector)bck;
2961 Helix work = H;
2962 work.ignoreErrorMatrix();
2963 work.pivot((fwd + bck) * .5);
2964 HepPoint3D x0kal = (work.x(0).z() - bck.z())/ wire.z() * wire + bck;
2965 H.pivot(x0kal);
2966
2967 Hep3Vector meas = H.momentum(0).cross(wire).unit();
2968
2969 if (wire_ID<0 || wire_ID>6796){ //bes
2970 std::cout << "KalFitTrack : wire_ID problem : " << wire_ID
2971 << std::endl;
2972 return DBL_MAX;
2973 }
2974
2975 double x[3] ={pivot().x(), pivot().y(), pivot().z()};
2976 double pmom[3] ={momentum().x(), momentum().y(), momentum().z()};
2977 double tofest(0);
2978 double phi = fmod(phi0() + M_PI4, M_PI2);
2979 double csf0 = cos(phi);
2980 double snf0 = (1. - csf0) * (1. + csf0);
2981 snf0 = sqrt((snf0 > 0.) ? snf0 : 0.);
2982 if(phi > M_PI) snf0 = - snf0;
2983
2984 if (Tof_correc_) {
2985 Hep3Vector ip(0, 0, 0);
2986 Helix work = *(Helix*)this;
2987 work.ignoreErrorMatrix();
2988 work.pivot(ip);
2989 double phi_ip = work.phi0();
2990 if (fabs(phi - phi_ip) > M_PI) {
2991 if (phi > phi_ip) phi -= 2 * M_PI;
2992 else phi_ip -= 2 * M_PI;
2993 }
2994 double t = tanl();
2995 double l = fabs(radius() * (phi - phi_ip) * sqrt(1 + t * t));
2996 double pmag( sqrt( 1.0 + t*t ) / kappa());
2997 double mass_over_p( mass_ / pmag );
2998 double beta( 1.0 / sqrt( 1.0 + mass_over_p * mass_over_p ) );
2999 tofest = l / ( 29.9792458 * beta );
3000 if(csmflag==1 && HitMdc.wire().y()>0.) tofest= -1. * tofest;
3001 }
3002
3003 const HepSymMatrix& ea = H.Ea();
3004 const HepVector& v_a = H.a();
3005 double dchi2R(DBL_MAX), dchi2L(DBL_MAX);
3006
3007 HepVector v_H(5, 0);
3008 v_H[0] = -csf0 * meas.x() - snf0 * meas.y();
3009 v_H[3] = -meas.z();
3010 HepMatrix v_HT = v_H.T();
3011
3012 double estim = (v_HT * v_a)[0];
3013 HepVector ea_v_H = ea * v_H;
3014 HepMatrix ea_v_HT = (ea_v_H).T();
3015 HepVector v_H_T_ea_v_H = v_HT * ea_v_H;
3016
3017 HepSymMatrix eaNewL(5), eaNewR(5);
3018 HepVector aNewL(5), aNewR(5);
3019
3020 //double time = HitMdc.tdc();
3021 //if (Tof_correc_)
3022 // time = time - tofest;
3023 double drifttime = getDriftTime(HitMdc , tofest);
3024 double ddl = getDriftDist(HitMdc, drifttime , 0 );
3025 double ddr = getDriftDist(HitMdc, drifttime , 1 );
3026 double erddl = getSigma( HitMdc, H.a()[4], 0, ddl);
3027 double erddr = getSigma( HitMdc, H.a()[4], 1, ddr);
3028
3029 double dmeas2[2] = { 0.1*ddl, 0.1*ddr };
3030 double er_dmeas2[2] = {0. , 0.};
3031 if(resolflag_ == 1) {
3032 er_dmeas2[0] = 0.1*erddl;
3033 er_dmeas2[1] = 0.1*erddr;
3034 }
3035 else if(resolflag_ == 0) {
3036 // int layid = HitMdc.wire().layer().layerId();
3037 // double sigma = getSigma(layid, dd);
3038 // er_dmeas2[0] = er_dmeas2[1] = sigma;
3039 }
3040
3041 if ((LR_==0 && lr != 1.0) ||
3042 (LR_==1 && lr == -1.0)) {
3043
3044 double er_dmeasL, dmeasL;
3045 if(Tof_correc_) {
3046 dmeasL = (-1.0)*fabs(dmeas2[0]);
3047 er_dmeasL = er_dmeas2[0];
3048 } else {
3049 dmeasL = (-1.0)*fabs(HitMdc.dist()[0]);
3050 er_dmeasL = HitMdc.erdist()[0];
3051 }
3052
3053 double AL = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasL*er_dmeasL);
3054 eaNewL.assign(ea - ea_v_H * AL * ea_v_HT);
3055 double RkL = 1 - (v_H_T_ea_v_H)[0] * AL;
3056 if(0. == RkL) RkL = 1.e-4;
3057
3058 HepVector diffL = ea_v_H * AL * (dmeasL - estim);
3059 aNewL = v_a + diffL;
3060 double sigL = dmeasL -(v_HT * aNewL)[0];
3061 dchi2L = (sigL * sigL) / (RkL * er_dmeasL*er_dmeasL);
3062 }
3063
3064 if ((LR_==0 && lr != -1.0) ||
3065 (LR_==1 && lr == 1.0)) {
3066
3067 double er_dmeasR, dmeasR;
3068 if(Tof_correc_) {
3069 dmeasR = dmeas2[1];
3070 er_dmeasR = er_dmeas2[1];
3071 } else {
3072 dmeasR = fabs(HitMdc.dist()[1]);
3073 er_dmeasR = HitMdc.erdist()[1];
3074 }
3075
3076 double AR = 1 / ((v_H_T_ea_v_H)[0] + er_dmeasR*er_dmeasR);
3077 eaNewR.assign(ea - ea_v_H * AR * ea_v_HT);
3078 double RkR = 1 - (v_H_T_ea_v_H)[0] * AR;
3079 if(0. == RkR) RkR = 1.e-4;
3080
3081 HepVector diffR = ea_v_H * AR * (dmeasR - estim);
3082 aNewR = v_a + diffR;
3083 double sigR = dmeasR -(v_HT * aNewR)[0];
3084 dchi2R = (sigR*sigR) / (RkR * er_dmeasR*er_dmeasR);
3085 }
3086
3087 if (dchi2R < dchi2L){
3088 H.a(aNewR); H.Ea(eaNewR);
3089 } else {
3090 H.a(aNewL); H.Ea(eaNewL);
3091 }
3092 return ((dchi2R < dchi2L) ? dchi2R : dchi2L);
3093}
3094
3095
3096double KalFitTrack::getSigma(int layerId, double driftDist ) const {
3097 double sigma1,sigma2,f;
3098 driftDist *= 10;//mm
3099 if(layerId<8){
3100 if(driftDist<0.5){
3101 sigma1=0.112784; sigma2=0.229274; f=0.666;
3102 }else if(driftDist<1.){
3103 sigma1=0.103123; sigma2=0.269797; f=0.934;
3104 }else if(driftDist<1.5){
3105 sigma1=0.08276; sigma2=0.17493; f=0.89;
3106 }else if(driftDist<2.){
3107 sigma1=0.070109; sigma2=0.149859; f=0.89;
3108 }else if(driftDist<2.5){
3109 sigma1=0.064453; sigma2=0.130149; f=0.886;
3110 }else if(driftDist<3.){
3111 sigma1=0.062383; sigma2=0.138806; f=0.942;
3112 }else if(driftDist<3.5){
3113 sigma1=0.061873; sigma2=0.145696; f=0.946;
3114 }else if(driftDist<4.){
3115 sigma1=0.061236; sigma2=0.119584; f=0.891;
3116 }else if(driftDist<4.5){
3117 sigma1=0.066292; sigma2=0.148426; f=0.917;
3118 }else if(driftDist<5.){
3119 sigma1=0.078074; sigma2=0.188148; f=0.911;
3120 }else if(driftDist<5.5){
3121 sigma1=0.088657; sigma2=0.27548; f=0.838;
3122 }else{
3123 sigma1=0.093089; sigma2=0.115556; f=0.367;
3124 }
3125 }else{
3126 if(driftDist<0.5){
3127 sigma1=0.112433; sigma2=0.327548; f=0.645;
3128 }else if(driftDist<1.){
3129 sigma1=0.096703; sigma2=0.305206; f=0.897;
3130 }else if(driftDist<1.5){
3131 sigma1=0.082518; sigma2=0.248913; f= 0.934;
3132 }else if(driftDist<2.){
3133 sigma1=0.072501; sigma2=0.153868; f= 0.899;
3134 }else if(driftDist<2.5){
3135 sigma1= 0.065535; sigma2=0.14246; f=0.914;
3136 }else if(driftDist<3.){
3137 sigma1=0.060497; sigma2=0.126489; f=0.918;
3138 }else if(driftDist<3.5){
3139 sigma1=0.057643; sigma2= 0.112927; f=0.892;
3140 }else if(driftDist<4.){
3141 sigma1=0.055266; sigma2=0.094833; f=0.887;
3142 }else if(driftDist<4.5){
3143 sigma1=0.056263; sigma2=0.124419; f= 0.932;
3144 }else if(driftDist<5.){
3145 sigma1=0.056599; sigma2=0.124248; f=0.923;
3146 }else if(driftDist<5.5){
3147 sigma1= 0.061377; sigma2=0.146147; f=0.964;
3148 }else if(driftDist<6.){
3149 sigma1=0.063978; sigma2=0.150591; f=0.942;
3150 }else if(driftDist<6.5){
3151 sigma1=0.072951; sigma2=0.15685; f=0.913;
3152 }else if(driftDist<7.){
3153 sigma1=0.085438; sigma2=0.255109; f=0.931;
3154 }else if(driftDist<7.5){
3155 sigma1=0.101635; sigma2=0.315529; f=0.878;
3156 }else{
3157 sigma1=0.149529; sigma2=0.374697; f=0.89;
3158 }
3159 }
3160 double sigmax = sqrt(f*sigma1*sigma1+(1 - f)*sigma2*sigma2)*0.1;
3161 return sigmax;//cm
3162}
3163
double cos(const BesAngle a)
Definition: BesAngle.h:213
**********INTEGER nmxhep !maximum number of particles DOUBLE PRECISION vhep INTEGER jdahep COMMON hepevt $ !serial number $ !number of particles $ !status code $ !particle ident KF $ !parent particles $ !childreen particles $ !four momentum
TFile f("ana_bhabha660a_dqa_mcPat_zy_old.root")
Double_t x[10]
Double_t time
HepGeom::Point3D< double > HepPoint3D
Definition: Gam4pikp.cxx:37
const double M_PI8
Definition: KalFitTrack.cxx:76
const double M_PI2
Definition: KalFitTrack.cxx:70
const double M_PI4
Definition: KalFitTrack.cxx:73
HepGeom::Transform3D HepTransform3D
Definition: KalFitTrack.h:7
#define DBL_MAX
Definition: KalFitTrack.h:4
********INTEGER modcns REAL m_C
Definition: PseuMar.h:13
#define M_PI
Definition: TConstant.h:4
TTree * t
Definition: binning.cxx:23
virtual StatusCode fieldVector(const HepGeom::Point3D< double > &xyz, HepGeom::Vector3D< double > &fvec) const =0
CLHEP::HepVector a_pre_fwd(void)
CLHEP::HepSymMatrix Ea_filt_fwd(void)
CLHEP::HepVector a_filt_bwd(void)
CLHEP::HepVector a_include(void)
double tof(void)
CLHEP::HepSymMatrix Ea_pre_bwd(void)
double doca_include(void)
CLHEP::HepVector a_filt_fwd(void)
double dt(void)
double doca_exclude(void)
CLHEP::HepVector a_pre_bwd(void)
CLHEP::HepSymMatrix & Ea_pre_fwd(void)
double dd(void)
CLHEP::HepVector a_exclude(void)
CLHEP::HepSymMatrix Ea_filt_bwd(void)
double residual_exclude(void)
CLHEP::HepSymMatrix Ea_include(void)
CLHEP::HepSymMatrix Ea_exclude(void)
KalFitHitMdc * HitMdc(void)
double residual_include(void)
Description of a Hit in Mdc.
Definition: KalFitHitMdc.h:17
int LR(void) const
Definition: KalFitHitMdc.h:29
RecMdcHit * rechitptr(void)
Definition: KalFitHitMdc.h:36
const double * erdist(void) const
Definition: KalFitHitMdc.h:34
const double * dist(void) const
Definition: KalFitHitMdc.h:33
const KalFitWire & wire(void) const
Definition: KalFitHitMdc.h:35
const int layerId(void) const
returns layer ID
double X0(void) const
Extractor.
double del_E(double mass, double path, double p) const
Calculate the straggling of energy loss.
double mcs_angle(double mass, double path, double p) const
Calculate Multiple Scattering angle.
double dE(double mass, double path, double p) const
Calculate energy loss.
Description of a track class (<- Helix.cc)
Definition: KalFitTrack.h:35
double * pathl(void)
Definition: KalFitTrack.h:189
~KalFitTrack(void)
destructor
double chi2_next(Helix &H, KalFitHitMdc &HitMdc, int csmflag)
static int lead(void)
Magnetic field map.
double getDriftTime(KalFitHitMdc &hitmdc, double toftime) const
static double chi2_hitf_
Cut chi2 for each hit.
Definition: KalFitTrack.h:282
KalFitTrack(const HepPoint3D &pivot, const CLHEP::HepVector &a, const CLHEP::HepSymMatrix &Ea, unsigned int m, double chiSq, unsigned int nhits)
constructor
Definition: KalFitTrack.cxx:81
static double dchi2cuts_anal[43]
Definition: KalFitTrack.h:290
static double dchi2cuts_calib[43]
Definition: KalFitTrack.h:294
static int debug_
for debug
Definition: KalFitTrack.h:280
static int nmass(void)
double filter(double v_m, const CLHEP::HepVector &m_H, double v_d, double m_V)
double tof(void) const
Definition: KalFitTrack.h:191
static double Bznom_
Definition: KalFitTrack.h:299
static int back(void)
void update_bit(int i)
void order_wirhit(int index)
double chiSq(void) const
Definition: KalFitTrack.h:183
static int nmdc_hit2_
Cut chi2 for each hit.
Definition: KalFitTrack.h:312
double getSigma(int layerId, double driftDist) const
static int tofall_
Definition: KalFitTrack.h:314
KalFitHelixSeg & HelixSeg(int i)
Definition: KalFitTrack.h:235
void addTofSM(double time)
static int resolflag_
wire resoltion flag
Definition: KalFitTrack.h:316
static int steplev_
Definition: KalFitTrack.h:302
void chgmass(int i)
static double factor_strag_
factor of energy loss straggling for electron
Definition: KalFitTrack.h:310
const HepPoint3D & pivot_numf(const HepPoint3D &newPivot)
Sets pivot position in a given mag field.
void ms(double path, const KalFitMaterial &m, int index)
static int Tof_correc_
Flag for TOF correction.
Definition: KalFitTrack.h:305
void update_forMdc(void)
double intersect_cylinder(double r) const
Intersection with different geometry.
vector< KalFitHitMdc > & HitsMdc(void)
Definition: KalFitTrack.h:229
void fiTerm(double fi)
static double chi2_hits_
Definition: KalFitTrack.h:282
void number_wirhit(void)
static int numf_
Flag for treatment of non-uniform mag field.
Definition: KalFitTrack.h:284
void path_add(double path)
Update the path length estimation.
static int inner_steps_
Definition: KalFitTrack.h:285
double mass(void) const
Definition: KalFitTrack.h:182
static int outer_steps_
Definition: KalFitTrack.h:286
double update_hits_csmalign(KalFitHelixSeg &HelixSeg, int inext, CLHEP::Hep3Vector &meas, int way, double &dchi2, int csmflag)
static int drifttime_choice_
the drifttime choice
Definition: KalFitTrack.h:321
double smoother_Mdc(KalFitHelixSeg &seg, CLHEP::Hep3Vector &meas, int &flg, int csmflag)
Kalman smoother for Mdc.
void msgasmdc(double path, int index)
Calculate multiple scattering angle.
void appendHitsMdc(KalFitHitMdc h)
Functions for Mdc hits list.
void addPathSM(double path)
static double mdcGasRadlen_
Definition: KalFitTrack.h:274
static double dchi2cutf_calib[43]
Definition: KalFitTrack.h:292
static int resol(void)
void eloss(double path, const KalFitMaterial &m, int index)
Calculate total energy lost in material.
void update_last(void)
Record the current parameters as ..._last information :
static void LR(int x)
double getDriftDist(KalFitHitMdc &hitmdc, double drifttime, int lr) const
double intersect_yz_plane(const HepTransform3D &plane, double x) const
static int numf(void)
double intersect_zx_plane(const HepTransform3D &plane, double y) const
static int numfcor_
NUMF treatment improved.
Definition: KalFitTrack.h:297
void order_hits(void)
double intersect_xy_plane(double z) const
double radius_numf(void) const
Estimation of the radius in a given mag field.
double smoother_Mdc_csmalign(KalFitHelixSeg &seg, CLHEP::Hep3Vector &meas, int &flg, int csmflag)
double update_hits(KalFitHitMdc &HitMdc, int inext, CLHEP::Hep3Vector &meas, int way, double &dchi2, double &dtrack, double &dtracknew, double &dtdc, int csmflag)
Include the Mdc wire hits.
static double dchi2cutf_anal[43]
Definition: KalFitTrack.h:288
static int LR_
Use L/R decision from MdcRecHit information :
Definition: KalFitTrack.h:319
KalFitHitMdc & HitMdc(int i)
Definition: KalFitTrack.h:230
static int strag_
Flag to take account of energy loss straggling :
Definition: KalFitTrack.h:308
Description of a Wire class.
Definition: KalFitWire.h:46
double y(void) const
Definition: KalFitWire.h:101
unsigned int geoID(void) const
Definition: KalFitWire.h:74
HepPoint3D bck(void) const
Definition: KalFitWire.h:93
HepPoint3D fwd(void) const
Geometry :
Definition: KalFitWire.h:92
const KalFitLayer_Mdc & layer(void) const
Definition: KalFitWire.h:70
unsigned int stereo(void) const
Definition: KalFitWire.h:75
const HepPoint3D & center(void) const
returns position of helix center(z = 0.);
void ignoreErrorMatrix(void)
unsets error matrix. Error calculations will be ignored after this function call until an error matri...
const HepSymMatrix & Ea(void) const
returns error matrix.
HepPoint3D x(double dPhi=0.) const
returns position after rotating angle dPhi in phi direction.
double dr(void) const
returns an element of parameters.
const HepVector & a(void) const
returns helix parameters.
const HepPoint3D & pivot(void) const
returns pivot position.
const double getEntra(void) const
Definition: RecMdcHit.h:54
double y[1000]
IMPLICIT REAL *A H
Definition: myXsection.h:1
int nhits
const double b
Definition: slope.cxx:9