LArSoft  v06_85_00
Liquid Argon Software toolkit - http://larsoft.org/
GFSpacepointHitPolicy.cxx
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1 /* Copyright 2008-2010, Technische Universitaet Muenchen,
2  Authors: Christian Hoeppner & Sebastian Neubert
3 
4  This file is part of GENFIT.
5 
6  GENFIT is free software: you can redistribute it and/or modify
7  it under the terms of the GNU Lesser General Public License as published
8  by the Free Software Foundation, either version 3 of the License, or
9  (at your option) any later version.
10 
11  GENFIT is distributed in the hope that it will be useful,
12  but WITHOUT ANY WARRANTY; without even the implied warranty of
13  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14  GNU Lesser General Public License for more details.
15 
16  You should have received a copy of the GNU Lesser General Public License
17  along with GENFIT. If not, see <http://www.gnu.org/licenses/>.
18 */
20 
21 #include "TMath.h"
22 
24 
25 const std::string genf::GFSpacepointHitPolicy::fPolicyName = "GFSpacepointHitPolicy";
26 
27 
28 TMatrixT<Double_t>
30 {
31  TMatrixT<Double_t> returnMat(2,1);
32 
33  TMatrixT<Double_t> _D(3,1);
34  TVector3 _U;
35  TVector3 _V;
36 
37  _D[0][0] = (plane.getO())[0];
38  _D[1][0] = (plane.getO())[1];
39  _D[2][0] = (plane.getO())[2];
40 
41  _D *= -1.;
42  _D += hit->getRawHitCoord();
43  //now the vector _D points from the origin of the plane to the hit point
44 
45 
46  _U = plane.getU();
47  _V = plane.getV();
48 
49 
50  returnMat[0][0] = _D[0][0] * _U[0] + _D[1][0] * _U[1] + _D[2][0] * _U[2];
51  returnMat[1][0] = _D[0][0] * _V[0] + _D[1][0] * _V[1] + _D[2][0] * _V[2];
52  //std::cout << "hitCoord="<<std::endl;
53  //returnMat.Print();
54  return returnMat;
55 }
56 
57 
58 TMatrixT<Double_t>
60 {
61  TMatrixT<Double_t> returnMat(5,1); // Just return last 2 elements. Will calculate the rest in GFKalman.cxx.
62 
63  TMatrixT<Double_t> _D(3,1);
64  TVector3 _U;
65  TVector3 _V;
66 
67  _D[0][0] = (plane.getO())[0];
68  _D[1][0] = (plane.getO())[1];
69  _D[2][0] = (plane.getO())[2];
70 
71  _D *= -1.;
72  _D += hit->getRawHitCoord();
73  //now the vector _D points from the origin of the plane to the hit point
74 
75 
76  _U = plane.getU();
77  _V = plane.getV();
78 
79 
80  returnMat[0][0] = _D[0][0] * _U[0] + _D[1][0] * _U[1] + _D[2][0] * _U[2];
81  returnMat[1][0] = _D[0][0] * _V[0] + _D[1][0] * _V[1] + _D[2][0] * _V[2];
82  //std::cout << "hitCoord="<<std::endl;
83  //returnMat.Print();
84  return returnMat;
85 }
86 
87 
88 TMatrixT<Double_t>
90 {
91  TVector3 _U;
92  TVector3 _V;
93 
94  _U = plane.getU();
95  _V = plane.getV();
96 
97  TMatrixT<Double_t> rawCov = hit->getRawHitCov();
98  //rawCov[0][0] = 12.e12; // Force this. EC, 3-Apr-2012.
99 
100  TMatrixT<Double_t> jac(3,2);
101 
102  // jac = dF_i/dx_j = s_unitvec * t_untivec, with s=u,v and t=x,y,z
103  jac[0][0] = _U[0];
104  jac[1][0] = _U[1];
105  jac[2][0] = _U[2];
106  jac[0][1] = _V[0];
107  jac[1][1] = _V[1];
108  jac[2][1] = _V[2];
109 
110  TMatrixT<Double_t> jac_t = jac.T();
111  TMatrixT<Double_t> jac_orig = jac;
112 
113  TMatrixT<Double_t> result=jac_t * (rawCov * jac_orig);
114  //std::cout << "hitCov="<<std::endl;
115  //result.Print();
116  return result;
117 }
118 
119 TMatrixT<Double_t>
120 genf::GFSpacepointHitPolicy::hitCov(GFAbsRecoHit* hit,const GFDetPlane& plane, const GFDetPlane& planePrev, const TMatrixT<Double_t>& state, const Double_t& mass)
121 {
122  TVector3 _U;
123  TVector3 _V;
124 
125  _U = plane.getU();
126  _V = plane.getV();
127 
128 // Double_t eps(1.0e-6);
129  TMatrixT<Double_t> rawCov = hit->getRawHitCov();
130 
131  //rawCov[0][0] = 12.e12; // Force this. EC, 3-Apr-2012.
132  std::vector <double> tmpRawCov;
133  tmpRawCov.push_back(rawCov[0][0]);
134  tmpRawCov.push_back(rawCov[1][1]);
135  tmpRawCov.push_back(rawCov[2][2]);
136  tmpRawCov.push_back(rawCov[2][1]); // y-z correlated cov element.
137 
138  static std::vector <double> oldRawCov(tmpRawCov);
139  static std::vector <double> oldOldRawCov(tmpRawCov);
140  static GFDetPlane planePrevPrev(planePrev);
141  rawCov.ResizeTo(7,7); // this becomes used now for something else entirely:
142  // the 7x7 raw errors on x,y,z,px,py,pz,th, which sandwiched between 5x7
143  // Jacobian converts it to the cov matrix for the 5x5 state space.
144  rawCov[0][0] = tmpRawCov[0]; // x
145  rawCov[1][1] = tmpRawCov[1]; // y
146  rawCov[2][2] = tmpRawCov[2]; // z
147  rawCov[1][2] = tmpRawCov[3]; // yz
148  rawCov[2][1] = tmpRawCov[3]; // yz
149 
150  // This Jacobian concerns the transfrom from planar to detector coords.
151  // TMatrixT<Double_t> jac(3,2);
152  TMatrixT<Double_t> jac(7,5); // X,Y,Z,UX,UY,UZ,Theta in detector coords
153 
154  // jac = dF_i/dx_j = s_unitvec * t_unitvec, with s=|q|/p,du/dw, dv/dw, u,v and t=th, x,y,z
155 
156  // More correctly :
157  Double_t dist(0.3); // place holder!!
158  Double_t C;
159  //Double_t p (2.5); // place holder!!!
160  //p = abs(1/state[0][0]);
161 
162  Double_t mom = fabs(1.0/state[0][0]);
163  Double_t beta = mom/sqrt(mass*mass+mom*mom);
164  dist = (plane.getO()-planePrev.getO()).Mag();
165  C = 0.0136/beta*sqrt(dist/14.0)*(1+0.038*log(dist/14.0));
166  TVector3 _D (plane.getNormal());
167 
168  // px^ = (x1-x2)/d;
169  // (sigpx)^2 = (sig_x1^2+sig_x2^2)*[(y1-y2)^2 + (z1-z2)^2]/d^4 +
170  // (x1-x2)^2*(y1-y2)^2*sigma_y1^2/d^6 + ...
171  // (x1-x2)^2*(z1-z2)^2*sigma_z2^2/d^6 +
172 
173  rawCov[3][3] = (oldRawCov[0]+tmpRawCov[0])/pow(dist,4.) *
174  (
175  pow((plane.getO()-planePrev.getO()).Y(),2.) +
176  pow((plane.getO()-planePrev.getO()).Z(),2.)
177  )
178  +
179  pow((plane.getO()-planePrev.getO()).X(),2.) *
180  (
181  pow((plane.getO()-planePrev.getO()).Y(),2.) * (oldRawCov[1]+tmpRawCov[1]) +
182  pow((plane.getO()-planePrev.getO()).Z(),2.) * (oldRawCov[2]+tmpRawCov[2])
183  ) / pow(dist,6.)
184  // y-z cross-term
185  +
186  3.0* (plane.getO()-planePrev.getO()).X() * (plane.getO()-planePrev.getO()).Y() * (plane.getO()-planePrev.getO()).Z() / pow(dist,5.) * (tmpRawCov[3] + oldRawCov[3])
187  ;
188 
189  rawCov[4][4] = (oldRawCov[1]+tmpRawCov[1])/pow(dist,4.) *
190  (
191  pow((plane.getO()-planePrev.getO()).X(),2.) +
192  pow((plane.getO()-planePrev.getO()).Z(),2.)
193  )
194  +
195  pow((plane.getO()-planePrev.getO()).Y(),2.) *
196  (
197  pow((plane.getO()-planePrev.getO()).X(),2.) * (oldRawCov[0]+tmpRawCov[0]) +
198  pow((plane.getO()-planePrev.getO()).Z(),2.) * (oldRawCov[2]+tmpRawCov[2])
199  ) / pow(dist,6.)
200  // y-z cross-term
201  +
202  3.0* ( (plane.getO()-planePrev.getO()).X() * (plane.getO()-planePrev.getO()).Y() * (plane.getO()-planePrev.getO()).Z() / pow(dist,5.) + (plane.getO()-planePrev.getO()).Z() / pow(dist,3.) ) * ( tmpRawCov[3] + oldRawCov[3] )
203  ;
204 
205  rawCov[5][5] = (oldRawCov[2]+tmpRawCov[2])/pow(dist,4.) *
206  (
207  pow((plane.getO()-planePrev.getO()).X(),2.) +
208  pow((plane.getO()-planePrev.getO()).Y(),2.)
209  )
210  +
211  pow((plane.getO()-planePrev.getO()).Z(),2.) *
212  (
213  pow((plane.getO()-planePrev.getO()).Y(),2.) * (oldRawCov[0]+tmpRawCov[0])+
214  pow((plane.getO()-planePrev.getO()).X(),2.) * (oldRawCov[1]+tmpRawCov[1])
215  ) / pow(dist,6.)
216  +
217  // y-z cross-term
218  3.0* ( (plane.getO()-planePrev.getO()).X() * (plane.getO()-planePrev.getO()).Y() * (plane.getO()-planePrev.getO()).Z() / pow(dist,5.) + (plane.getO()-planePrev.getO()).Y() / pow(dist,3.) ) * ( tmpRawCov[3] + oldRawCov[3] )
219  ;
220 
221 
222  Double_t num = (plane.getO()-planePrev.getO())*(planePrev.getO()-planePrevPrev.getO());
223  Double_t d1 = (plane.getO()-planePrev.getO()).Mag(); // same as dist above
224  Double_t d2 = (planePrev.getO()-planePrevPrev.getO()).Mag();
225 
226  // This is the error on cosTh^2. There are 9 terms for diagonal errors, one for each
227  // x,y,z coordinate at 3 points. Below the first 3 terms are at pt 1.
228  // Second 3 are at 3. Third 3 are at 2, which is slightly more complicated.
229  // There are three more terms for non-diagonal erros.
230  double dcosTh =
231  pow(((planePrev.getO()-planePrevPrev.getO()).X()*d1*d2 -
232  num * (plane.getO()-planePrev.getO()).X() *d2/d1) /
233  pow(d1,2.0)/pow(d2,2.0),2.0) * tmpRawCov[0] +
234  pow(((planePrev.getO()-planePrevPrev.getO()).Y()*d1*d2 +
235  num * (plane.getO()-planePrev.getO()).Y() *d2/d1) /
236  pow(d1,2.0)/pow(d2,2.0),2.0) * tmpRawCov[1] +
237  pow(((planePrev.getO()-planePrevPrev.getO()).Z()*d1*d2 +
238  num * (plane.getO()-planePrev.getO()).Z() *d2/d1) /
239  pow(d1,2.0)/pow(d2,2.0),2.0) * tmpRawCov[2] +
240 
241  pow(((plane.getO()-planePrev.getO()).X()*d1*d2 -
242  num * (planePrev.getO()-planePrevPrev.getO()).X() *d1/d2) /
243  pow(d1,2.0)/pow(d2,2.0),2.0) * oldOldRawCov[0] +
244  pow(((plane.getO()-planePrev.getO()).Y()*d1*d2 -
245  num * (planePrev.getO()-planePrevPrev.getO()).Y() *d1/d2) /
246  pow(d1,2.0)/pow(d2,2.0),2.0) * oldOldRawCov[1] +
247  pow(((plane.getO()-planePrev.getO()).Z()*d1*d2 -
248  num * (planePrev.getO()-planePrevPrev.getO()).Z() *d1/d2) /
249  pow(d1,2.0)/pow(d2,2.0),2.0) * oldOldRawCov[2] +
250 
251  pow(((plane.getO()-planePrevPrev.getO()).X()*d1*d2 -
252  num * (plane.getO()-planePrev.getO()).X() *d2/d1 +
253  num * (planePrev.getO()-planePrevPrev.getO()).X() *d1/d2
254  ) /
255  pow(d1,2.0)/pow(d2,2.0),2.0) * oldRawCov[0] +
256  pow(((plane.getO()-planePrevPrev.getO()).Y()*d1*d2 -
257  num * (plane.getO()-planePrev.getO()).Y() *d2/d1 +
258  num * (planePrev.getO()-planePrevPrev.getO()).Y() *d1/d2
259  ) /
260  pow(d1,2.0)/pow(d2,2.0),2.0) * oldRawCov[1] +
261  pow(((plane.getO()-planePrevPrev.getO()).Z()*d1*d2 -
262  num * (plane.getO()-planePrev.getO()).Z() *d2/d1 +
263  num * (planePrev.getO()-planePrevPrev.getO()).Z() *d1/d2
264  ) /
265  pow(d1,2.0)/pow(d2,2.0),2.0) * oldRawCov[2]
266  // And now the off-diagonal terms. This is a mess unto itself.
267  // First, d^2(costh)/d(z1)d(y1)
268  +
269  (
270  (plane.getO()-planePrev.getO()).Z() * (planePrev.getO()-planePrevPrev.getO()).Y() / pow(d1,3.)/d2
271  -
272  (plane.getO()-planePrev.getO()).Y() * (planePrev.getO()-planePrevPrev.getO()).Z() / pow(d1,3.)/d2
273  +
274  3.*(plane.getO()-planePrev.getO()).Y() * (plane.getO()-planePrev.getO()).Z() * num / pow(d1,5.)/d2
275  ) * tmpRawCov[3]
276  // Next, d^2(costh)/d(z3)d(y3). Above w z1<->z3, y1<->y3
277  +
278  (
279  (planePrevPrev.getO()-planePrev.getO()).Z() * (planePrev.getO()-plane.getO()).Y() / pow(d1,3.)/d2
280  -
281  (planePrevPrev.getO()-planePrev.getO()).Y() * (planePrev.getO()-plane.getO()).Z() / pow(d1,3.)/d2
282  +
283  3.*(planePrevPrev.getO()-planePrev.getO()).Y() * (planePrevPrev.getO()-planePrev.getO()).Z() * num / pow(d1,5.)/d2
284  ) * oldOldRawCov[3]
285  // Last, d^2(costh)/d(z2)d(y2). This is an even bigger mess.
286  +
287  (
288  ( (plane.getO()-planePrev.getO()).Y() - (planePrev.getO()-planePrevPrev.getO()).Y() ) *
289  (-(plane.getO()-planePrev.getO()).Z()/pow(d1,3.)/d2 +
290  (planePrev.getO()-planePrevPrev.getO()).Z()/pow(d2,3.)/d1
291  )
292  + (plane.getO()-planePrev.getO()).Y() *
293  (
294  (-(planePrev.getO()-planePrevPrev.getO()).Z() +
295  (plane.getO()-planePrev.getO()).Z()
296  ) / pow(d1,3.)/d2
297  - num*
298  ( -3.* (plane.getO()-planePrev.getO()).Z()*d1*d2 +
299  (planePrev.getO()-planePrevPrev.getO()).Z()*pow(d1,3.)/d2
300  )
301  ) / pow(d1,6.) / pow(d2,2.)
302  -
303  (planePrev.getO()-planePrevPrev.getO()).Y()*
304  (
305  (-(planePrev.getO()-planePrevPrev.getO()).Z() +
306  (plane.getO()-planePrev.getO()).Z()
307  ) / pow(d2,3.)/d1
308  - num*
309  ( 3.* (planePrev.getO()-planePrevPrev.getO()).Z()*d1*d2 -
310  (plane.getO()-planePrev.getO()).Z()*pow(d2,3.)/d1
311  )
312  ) / pow(d1,2.) / pow(d2,6.)
313  ) * oldRawCov[3]
314  ;
315 
316  // That was delta(cos(theta))^2. I want delta(theta)^2. dTh^2 = d(cosTh)^2/sinTh^2
317  Double_t theta(TMath::ACos((plane.getO()-planePrev.getO()).Unit() * (planePrev.getO()-planePrevPrev.getO()).Unit()));
318  rawCov[6][6] = TMath::Min(pow(dcosTh,2.)/pow(TMath::Sin(theta),2.),pow(TMath::Pi()/2.0,2.));
319 
320  // This means I'm too close to the endpoints to have histories that allow
321  // proper calculation of above rawCovs. Use below defaults instead.
322  if (d1 == 0 || d2 == 0)
323  {
324  rawCov[3][3] = pow(0.2,2.0); // Unit Px
325  rawCov[4][4] = pow(0.2,2.0); // Unit Py
326  rawCov[5][5] = pow(0.2,2.0); // Unit Pz
327  rawCov[6][6] = pow(0.1,2.0); // theta. 0.3/3mm, say.
328  dist = 0.3;
329  C = 0.0136/beta*sqrt(dist/14.0)*(1+0.038*log(dist/14.0));
330  }
331 
332  // This forces a huge/tiny theta error, which effectively freezes/makes-us-sensitive theta, as is.
333  //rawCov[6][6] = /*9.99e9*/ 0.1;
334 
335  TVector3 u=plane.getU();
336  TVector3 v=plane.getV();
337  TVector3 w=u.Cross(v);
338 
339  // Below line has been done, with code change in GFKalman that has updated
340  // the plane orientation by now.
341  // TVector3 pTilde = 1.0 * (w + state[1][0] * u + state[2][0] * v);
342  TVector3 pTilde = w;
343  double pTildeMag = pTilde.Mag();
344 
345  jac.Zero();
346  jac[6][0] = 1./C; // Should be 1/C?; Had 1 until ... 12-Feb-2013
347 
348  jac[0][3] = _U[0];
349  jac[1][3] = _U[1];
350  jac[2][3] = _U[2];
351 
352  jac[0][4] = _V[0];
353  jac[1][4] = _V[1];
354  jac[2][4] = _V[2];
355 
356  // cnp'd from RKTrackRep.cxx, line ~496
357  // da{x,y,z}/du'
358  jac[3][1] = 1.0/pTildeMag*(u.X()-pTilde.X()/(pTildeMag*pTildeMag)*u*pTilde);
359  jac[4][1] = 1.0/pTildeMag*(u.Y()-pTilde.Y()/(pTildeMag*pTildeMag)*u*pTilde);
360  jac[5][1] = 1.0/pTildeMag*(u.Z()-pTilde.Z()/(pTildeMag*pTildeMag)*u*pTilde);
361  // da{x,y,z}/dv'
362  jac[3][2] = 1.0/pTildeMag*(v.X()-pTilde.X()/(pTildeMag*pTildeMag)*v*pTilde);
363  jac[4][2] = 1.0/pTildeMag*(v.Y()-pTilde.Y()/(pTildeMag*pTildeMag)*v*pTilde);
364  jac[5][2] = 1.0/pTildeMag*(v.Z()-pTilde.Z()/(pTildeMag*pTildeMag)*v*pTilde);
365 
366  TMatrixT<Double_t> jac_orig = jac;
367  TMatrixT<Double_t> jac_t = jac.T();
368 
369  TMatrixT<Double_t> result=jac_t * (rawCov * jac_orig);
370  //std::cout << "hitCov="<<std::endl;
371  //result.Print();
372 
373 
374  oldOldRawCov = oldRawCov;
375  oldRawCov = tmpRawCov;
376  planePrevPrev = planePrev;
377 
378  return result;
379 }
380 
381 const genf::GFDetPlane&
383 {
384  TMatrixT<Double_t> rawcoord = hit->getRawHitCoord();
385  TVector3 point(rawcoord[0][0],rawcoord[1][0],rawcoord[2][0]);
386 
387  TVector3 poca,dirInPoca;
388  rep->extrapolateToPoint(point,poca,dirInPoca);
389 
390  fPlane.setO(point);
391  fPlane.setNormal(dirInPoca);
392 
393  return fPlane;
394 }
395 
396 //ClassImp(GFSpacepointHitPolicy)
Float_t Y
Definition: plot.C:39
void setO(const TVector3 &o)
Definition: GFDetPlane.cxx:94
TMatrixT< Double_t > getRawHitCoord() const
Get raw hit coordinates.
Definition: GFAbsRecoHit.h:182
Double_t beta
TMatrixT< double > hitCoord(GFAbsRecoHit *, const GFDetPlane &)
Hit coordinates in detector plane.
Base Class for genfit track representations. Defines interface for track parameterizations.
Definition: GFAbsTrackRep.h:85
Float_t Z
Definition: plot.C:39
TVector3 getNormal() const
Definition: GFDetPlane.cxx:140
TMatrixT< double > hitCov(GFAbsRecoHit *, const GFDetPlane &)
Hit covariances in detector plane.
TVector3 getO() const
Definition: GFDetPlane.h:76
static const std::string fPolicyName
virtual void extrapolateToPoint(const TVector3 &point, TVector3 &poca, TVector3 &normVec)
This method is to extrapolate the track to point of closest approach to a point in space...
Detector simulation of raw signals on wires.
const GFDetPlane & detPlane(GFAbsRecoHit *, GFAbsTrackRep *)
Get detector plane perpendicular to track.
TVector3 getU() const
Definition: GFDetPlane.h:77
void setNormal(TVector3 n)
Definition: GFDetPlane.cxx:158
TVector3 getV() const
Definition: GFDetPlane.h:78
Float_t X
Definition: plot.C:39
TMatrixT< Double_t > getRawHitCov() const
Get raw hit covariances.
Definition: GFAbsRecoHit.h:177
Float_t w
Definition: plot.C:23