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source: git/external/TrackCovariance/SolTrack.cc@ 3a105e5

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Last change on this file since 3a105e5 was 3a105e5, checked in by michele <michele.selvaggi@…>, 2 years ago
added first hit to track
Property mode set to `100644`
File size: 20.7 KB

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1
2	#include "SolGeom.h"
3	#include "SolTrack.h"
4	#include <TString.h>
5	#include <TMath.h>
6	#include <TMatrixD.h>
7	#include <TMatrixDSym.h>
8	#include <TDecompChol.h>
9	#include <TMatrixDSymEigen.h>
10	#include <TGraph.h>
11	#include <iostream>
12	//
13	// Constructors
14	SolTrack::SolTrack(Double_t x, Double_t p, SolGeom *G)
15	{
16	// Set B field
17	fG = G; // Store geometry
18	Double_t B = G->B();
19	SetB(B);
20	// Store momentum and position
21	fp[0] = p[0]; fp[1] = p[1]; fp[2] = p[2];
22	fx[0] = x[0]; fx[1] = x[1]; fx[2] = x[2];
23	// Get generated parameters
24	TVector3 xv(fx);
25	TVector3 pv(fp);
26	Double_t Charge = 1.0; // Don't worry about charge for now
27	TVectorD gPar = XPtoPar(xv, pv, Charge);
28	// Store parameters
29	fpar[0] = gPar(0);
30	fpar[1] = gPar(1);
31	fpar[2] = gPar(2);
32	fpar[3] = gPar(3);
33	fpar[4] = gPar(4);
34	//cout << "SolTrack:: C = " << C << ", fpar[2] = " << fpar[2] << endl;
35	//
36	// Init covariances
37	//
38	fCov.ResizeTo(5, 5);
39	}
40	SolTrack::SolTrack(TVector3 x, TVector3 p, SolGeom* G)
41	{
42	// set B field
43	fG = G; // Store geometry
44	Double_t B = G->B();
45	SetB(B);
46	// Store momentum
47	fp[0] = p(0); fp[1] = p(1); fp[2] = p(2);
48	fx[0] = x(0); fx[1] = x(1); fx[2] = x(2);
49	// Get generated parameters
50	Double_t Charge = 1.0; // Don't worry about charge for now
51	TVectorD gPar = XPtoPar(x, p, Charge);
52	// Store parameters
53	fpar[0] = gPar(0);
54	fpar[1] = gPar(1);
55	fpar[2] = gPar(2);
56	fpar[3] = gPar(3);
57	fpar[4] = gPar(4);
58	//cout << "SolTrack:: C = " << C << ", fpar[2] = " << fpar[2] << endl;
59	//
60	// Init covariances
61	//
62	fCov.ResizeTo(5, 5);
63	}
64	//
65	SolTrack::SolTrack(Double_t D, Double_t phi0, Double_t C, Double_t z0, Double_t ct, SolGeom *G)
66	{
67	fG = G;
68	Double_t B = G->B();
69	SetB(B);
70	// Store parameters
71	fpar[0] = D;
72	fpar[1] = phi0;
73	fpar[2] = C;
74	fpar[3] = z0;
75	fpar[4] = ct;
76	// Store momentum
77	Double_t pt = B * TrkUtil::cSpeed() / TMath::Abs(2 * C);
78	Double_t px = pt*TMath::Cos(phi0);
79	Double_t py = pt*TMath::Sin(phi0);
80	Double_t pz = pt*ct;
81	//
82	fp[0] = px; fp[1] = py; fp[2] = pz;
83	fx[0] = -DTMath::Sin(phi0); fx[1] = DTMath::Cos(phi0); fx[2] = z0;
84	//
85	// Init covariances
86	//
87	fCov.ResizeTo(5, 5);
88	}
89	// Destructor
90	SolTrack::~SolTrack()
91	{
92	fCov.Clear();
93	}
94	//
95	// Calculate intersection with given layer
96	Bool_t SolTrack::HitLayer(Int_t il, Double_t &R, Double_t &phi, Double_t &zz)
97	{
98	Double_t Di = D();
99	Double_t phi0i = phi0();
100	Double_t Ci = C();
101	Double_t z0i = z0();
102	Double_t cti = ct();
103	//
104	R = 0; phi = 0; zz = 0;
105	Bool_t val = kFALSE;
106	Double_t Rmin = TMath::Sqrt(fx[0] * fx[0] + fx[1] * fx[1]); // Smallest track radius
107	if (Rmin < TMath::Abs(Di)) return val;
108	//
109	Double_t ArgzMin = Ci * TMath::Sqrt((Rmin * Rmin - Di * Di) / (1 + 2 * Ci * Di));
110	Double_t stMin = TMath::ASin(ArgzMin) / Ci; // Arc length at track origin
111	//
112	if (fG->lTyp(il) == 1) // Cylinder: layer at constant R
113	{
114	R = fG->lPos(il);
115	Double_t argph = (CiR + (1 + CiDi)Di / R) / (1. + 2.Ci*Di);
116	if (TMath::Abs(argph) < 1.0 && R > Rmin)
117	{
118	Double_t argz = CiTMath::Sqrt((RR - DiDi) / (1 + 2 Ci*Di));
119	if (TMath::Abs(argz) < 1.0)
120	{
121	zz = z0i + cti*TMath::ASin(argz) / Ci;
122	if (zz > fG->lxMin(il) && zz < fG->lxMax(il))
123	{
124	phi = phi0i + TMath::ASin(argph);
125	val = kTRUE;
126	}
127	}
128	}
129	}
130	else if (fG->lTyp(il) == 2) // disk: layer at constant z
131	{
132	zz = fG->lPos(il);
133	Double_t st = (zz - z0i) / cti;
134	if (TMath::Abs(Ci * st) < 1.0 && st > stMin)
135	{
136	R = TMath::Sqrt(Di * Di + (1. + 2. * Ci * Di) * pow(TMath::Sin(Ci * st), 2) / (Ci * Ci));
137	if (R > fG->lxMin(il) && R < fG->lxMax(il))
138	{
139	Double_t arg1 = (CiR + (1 + CiDi)Di / R) / (1. + 2.Ci*Di);
140	if (TMath::Abs(arg1) < 1.0)
141	{
142	phi = phi0i + TMath::ASin(arg1);
143	val = kTRUE;
144	}
145	}
146	}
147	}
148	//
149	return val;
150	}
151	//
152	// # of layers hit
153	Int_t SolTrack::nHit()
154	{
155	Int_t kh = 0;
156	Double_t R; Double_t phi; Double_t zz;
157	for (Int_t i = 0; i < fG->Nl(); i++)
158	if (HitLayer(i, R, phi, zz))kh++;
159	//
160	return kh;
161	}
162	//
163	// # of measurement layers hit
164	Int_t SolTrack::nmHit()
165	{
166	Int_t kmh = 0;
167	Double_t R; Double_t phi; Double_t zz;
168	for (Int_t i = 0; i < fG->Nl(); i++)
169	if (HitLayer(i, R, phi, zz))if (fG->isMeasure(i))kmh++;
170	//
171	return kmh;
172	}
173	//
174	// List of layers hit with intersections
175	Int_t SolTrack::HitList(Int_t &ihh, Double_t &rhh, Double_t *&zhh)
176	{
177	//
178	// Return lists of hits associated to a track including all scattering layers.
179	// Return value is the total number of measurement hits
180	// kmh = total number of measurement layers hit for given type
181	// ihh = pointer to layer number
182	// rhh = radius of hit
183	// zhh = z of hit
184	//
185	// ***** NB: double layers with stereo on lower layer not included
186	//
187	Int_t kh = 0; // Number of layers hit
188	Int_t kmh = 0; // Number of measurement layers of given type
189	for (Int_t i = 0; i < fG->Nl(); i++)
190	{
191	Double_t R; Double_t phi; Double_t zz;
192	if (HitLayer(i, R, phi, zz))
193	{
194	zhh[kh] = zz;
195	rhh[kh] = R;
196	ihh[kh] = i;
197	if (fG->isMeasure(i))kmh++;
198	kh++;
199	}
200	}
201	//
202	return kmh;
203	}
204	//
205	// List of XYZ measurements without any error
206	Int_t SolTrack::HitListXYZ(Int_t &ihh, Double_t &Xh, Double_t &Yh, Double_t &Zh)
207	{
208	//
209	// Return lists of hits associated to a track for all measurement layers.
210	// Return value is the total number of measurement hits
211	// kmh = total number of measurement layers hit for given type
212	// ihh = pointer to layer number
213	// Xh, Yh, Zh = X, Y, Z of hit - No measurement error - No multiple scattering
214	//
215	//
216	Int_t kmh = 0; // Number of measurement layers hit
217	for (Int_t i = 0; i < fG->Nl(); i++)
218	{
219	Double_t R; Double_t phi; Double_t zz;
220	if (HitLayer(i, R, phi, zz)) // Only barrel type layers
221	{
222	if (fG->isMeasure(i))
223	{
224	ihh[kmh] = i;
225	Xh[kmh] = R*cos(phi);
226	Yh[kmh] = R*sin(phi);
227	Zh[kmh] = zz;
228	kmh++;
229	}
230	}
231	}
232	//
233	return kmh;
234	}
235	//
236	Int_t SolTrack::FirstHit(Double_t &Xfirst, Double_t &Yfirst, Double_t &Zfirst)
237	{
238	Int_t iFirst = -1;
239	Int_t iFirstLay = -1; // Default return with no hits
240	Xfirst = 0.;
241	Yfirst = 0.;
242	Zfirst = 0.;
243	Int_t Nmh = nmHit(); // # measurement hits
244	if(Nmh > 0){
245	Int_t *ih = new Int_t [Nmh];
246	Double_t *Xh = new Double_t[Nmh];
247	Double_t *Yh = new Double_t[Nmh];
248	Double_t *Zh = new Double_t[Nmh];
249	Double_t *dh = new Double_t[Nmh];
250	//
251	Int_t n = HitListXYZ(ih, Xh, Yh, Zh);
252	//
253	for(Int_t i=0; i<Nmh; i++){
254	Double_t rr = TMath::Sqrt(Xh[i]Xh[i]+Yh[i]Yh[i]); // Hit radius
255	dh[i] = TMath::ASin(C() * TMath::Sqrt((rr * rr - D() * D()) / (1. + 2 * C() * D()))) / C(); // Arc length traveled
256	}
257	//
258	Int_t *hord = new Int_t[Nmh]; // hit order by increasing arc length
259	TMath::Sort(Nmh, dh, hord, kFALSE); // Order by increasing arc length
260	iFirst = hord[0]; // First hit pointer
261	Xfirst = Xh[iFirst];
262	Yfirst = Yh[iFirst];
263	Zfirst = Zh[iFirst];
264	iFirstLay = ih[iFirst];
265	//
266	// Clean
267	delete [] ih;
268	delete [] Xh;
269	delete [] Yh;
270	delete [] Zh;
271	delete [] dh;
272	delete [] hord;
273	}
274	//
275	return iFirstLay; // Return first hit layer number
276	}
277	//
278	// Track plot
279	//
280	TGraph *SolTrack::TrkPlot()
281	{
282	//
283	// Fill list of layers hit
284	//
285	Int_t Nhit = nHit(); // Total number of layers hit
286	//cout << "Nhit = " << Nhit << endl;
287	Double_t *zh = new Double_t[Nhit]; // z of hit
288	Double_t *rh = new Double_t[Nhit]; // r of hit
289	Int_t *ih = new Int_t [Nhit]; // true index of layer
290	Int_t kmh; // Number of measurement layers hit
291	//
292	kmh = HitList(ih, rh, zh); // hit layer list
293	//for (Int_t j = 0; j < Nhit; j++) cout << "r = " << rh[j] << ", z = " << zh[j] << endl;
294	Double_t *dh = new Double_t[Nhit]; // Hit distance from origin
295	for(Int_t i=0; i<Nhit; i++)dh[i] = TMath::ASin(C() * TMath::Sqrt((rh[i] * rh[i] - D() * D()) / (1. + 2 * C() * D()))) / C(); // Arc length traveled;
296	//
297	Int_t *hord = new Int_t[Nhit];
298	TMath::Sort(Nhit, dh, hord, kFALSE); // Order by increasing phase
299	Double_t *z = new Double_t[Nhit]; // z of ordered hit
300	Double_t *r = new Double_t[Nhit]; // r of ordered hit
301	for (Int_t i = 0; i < Nhit; i++)
302	{
303	z[i] = zh[hord[i]];
304	r[i] = rh[hord[i]];
305	}
306	//cout << "After ordering" << endl;
307	//for (Int_t j = 0; j < Nhit; j++) cout << "r = " << rh[j] << ", z = " << zh[j] << endl;
308	TGraph *gr = new TGraph(Nhit, z, r); // graph intersection with layers
309	gr->SetMarkerStyle(kCircle);
310	gr->SetMarkerColor(kMagenta);
311	gr->SetMarkerSize(1);
312	gr->SetLineColor(kMagenta);
313	//
314	// clean up
315	//
316	delete[] zh;
317	delete[] rh;
318	delete[] ih;
319	delete[] hord;
320	return gr;
321	}
322	//
323	// Covariance matrix estimation
324	//
325	void SolTrack::CovCalc(Bool_t Res, Bool_t MS)
326	{
327	//
328	//
329	// Input flags:
330	// Res = .TRUE. turn on resolution effects/Use standard resolutions
331	// .FALSE. set all resolutions to 0
332	// MS = .TRUE. include Multiple Scattering
333	//
334	// Assumptions:
335	// 1. Measurement layers can do one or two measurements
336	// 2. On disks at constant z:
337	// - Upper side measurement is phi
338	// - Lower side measurement is R
339	//
340	// Fill list of layers hit
341	//
342	Int_t ntry = 0;
343	Int_t ntrymax = 0;
344	Int_t Nhit = nHit(); // Total number of layers hit
345	Double_t *zhh = new Double_t[Nhit]; // z of hit
346	Double_t *rhh = new Double_t[Nhit]; // r of hit
347	Double_t *dhh = new Double_t[Nhit]; // distance of hit from origin
348	Int_t *ihh = new Int_t[Nhit]; // true index of layer
349	Int_t kmh; // Number of measurement layers hit
350	//
351	kmh = HitList(ihh, rhh, zhh); // hit layer list
352	Int_t mTot = 0; // Total number of measurements
353	for (Int_t i = 0; i < Nhit; i++)
354	{
355	Double_t rr = rhh[i];
356	dhh[i] = TMath::ASin(C() * TMath::Sqrt((rr * rr - D() * D()) / (1. + 2 * C() * D()))) / C(); // Arc length traveled
357	if (fG->isMeasure(ihh[i])) mTot += fG->lND(ihh[i]); // Count number of measurements
358	}
359	//
360	// Order hit list by increasing arc length
361	//
362	Int_t *hord = new Int_t[Nhit]; // hit order by increasing distance from origin
363	TMath::Sort(Nhit, dhh, hord, kFALSE); // Order by increasing distance from origin
364	Double_t *zh = new Double_t[Nhit]; // d-ordered z of hit
365	Double_t *rh = new Double_t[Nhit]; // d-ordered r of hit
366	Int_t *ih = new Int_t[Nhit]; // d-ordered true index of layer
367	for (Int_t i = 0; i < Nhit; i++)
368	{
369	Int_t il = hord[i]; // Hit layer numbering
370	zh[i] = zhh[il];
371	rh[i] = rhh[il];
372	ih[i] = ihh[il];
373	}
374	//
375	// Store interdistances and multiple scattering angles
376	//
377	Double_t sn2t = 1.0 / (1.0 + ct()*ct()); //sin^2 theta of track
378	Double_t cs2t = 1.0 - sn2t; //cos^2 theta
379	Double_t snt = TMath::Sqrt(sn2t); // sin theta
380	Double_t cst = TMath::Sqrt(cs2t); // cos theta
381	Double_t px0 = pt() * TMath::Cos(phi0()); // Momentum at minimum approach
382	Double_t py0 = pt() * TMath::Sin(phi0());
383	Double_t pz0 = pt() * ct();
384	//
385	TMatrixDSym dik(Nhit); dik.Zero(); // Distances between layers
386	Double_t *thms = new Double_t[Nhit]; // Scattering angles/plane
387	Double_t* cs = new Double_t[Nhit]; // Cosine of angle with normal in transverse plane
388	//
389	for (Int_t ii = 0; ii < Nhit; ii++) // Hit layer loop
390	{
391	Int_t i = ih[ii]; // Get true layer number
392	Int_t il = hord[ii]; // Unordered layer
393	Double_t B = C()TMath::Sqrt((rh[ii] rh[ii] - D()D()) / (1 + 2 C()*D()));
394	//
395	Double_t pxi = px0(1-2BB)-2py0BTMath::Sqrt(1-B*B); // Momentum at scattering layer
396	Double_t pyi = py0(1-2BB)+2px0BTMath::Sqrt(1-B*B);
397	Double_t pzi = pz0;
398	Double_t ArgRp = (rh[ii]C() + (1 + C() D())D() / rh[ii]) / (1 + 2 C()*D());
399	//
400	Double_t phi = phi0() + TMath::ASin(ArgRp);
401	Double_t nx = TMath::Cos(phi); // Barrel layer normal
402	Double_t ny = TMath::Sin(phi);
403	Double_t nz = 0.0;
404	cs[ii] = TMath::Abs((pxi * nx + pyi * ny) / pt());
405	//
406	if (fG->lTyp(i) == 2) // this is Z layer
407	{
408	nx = 0.0;
409	ny = 0.0;
410	nz = 1.0;
411	}
412	Double_t corr = TMath::Abs(pxinx + pyi ny + pzi * nz) / p();
413	Double_t Rlf = fG->lTh(i) / (corr*fG->lX0(i)); // Rad. length fraction
414	thms[ii] = 0.0136TMath::Sqrt(Rlf)(1.0 + 0.038*TMath::Log(Rlf)) / p(); // MS angle
415	if (!MS)thms[ii] = 0;
416	//
417	for (Int_t kk = 0; kk < ii; kk++) // Fill distances between layers
418	{
419	Int_t kl = hord[kk]; // Unordered layer
420	dik(ii, kk) = TMath::Abs(dhh[il] - dhh[kl])/snt;
421	dik(kk, ii) = dik(ii, kk);
422	}
423	}
424	//
425	// Fill measurement covariance
426	//
427	TVectorD tPar(5,fpar);
428	//
429	TMatrixDSym Sm(mTot); Sm.Zero(); // Measurement covariance
430	TMatrixD Rm(mTot, 5); // Derivative matrix
431	Int_t im = 0; // Initialize number of measurement counter
432	//
433	// Fill derivatives and error matrix with MS
434	//
435	for (Int_t ii = 0; ii < Nhit; ii++)
436	{
437	Int_t i = ih[ii]; // True layer number
438	Int_t ityp = fG->lTyp(i); // Layer type Barrel or Z
439	Int_t nmeai = fG->lND(i); // # measurements in layer
440
441	if (fG->isMeasure(i))
442	{
443	Double_t Ri = rh[ii];
444	Double_t zi = zh[ii];
445	//
446	for (Int_t nmi = 0; nmi < nmeai; nmi++)
447	{
448	Double_t stri = 0; // Stereo angle
449	Double_t sig = 0; // Layer resolution
450	// Constant R derivatives
451	TVectorD dRphi(5); dRphi.Zero(); // R-phi derivatives @ const. R
452	TVectorD dRz(5); dRz.Zero(); // z derivatives @ const. R
453	//
454	if (nmi + 1 == 1) // Upper layer measurements
455	{
456	stri = fG->lStU(i); // Stereo angle
457	Double_t csa = TMath::Cos(stri);
458	Double_t ssa = TMath::Sin(stri);
459	//
460	sig = fG->lSgU(i); // Resolution
461	if (ityp == 1) // Barrel type layer (Measure R-phi, stereo or z at const. R)
462	{
463	//
464	// Exact solution
465	dRphi = derRphi_R(tPar, Ri);
466	dRz = derZ_R (tPar, Ri);
467	//
468	Rm(im, 0) = csa * dRphi(0) - ssa * dRz(0); // D derivative
469	Rm(im, 1) = csa * dRphi(1) - ssa * dRz(1); // phi0 derivative
470	Rm(im, 2) = csa * dRphi(2) - ssa * dRz(2); // C derivative
471	Rm(im, 3) = csa * dRphi(3) - ssa * dRz(3); // z0 derivative
472	Rm(im, 4) = csa * dRphi(4) - ssa * dRz(4); // cot(theta) derivative
473	}
474	if (ityp == 2) // Z type layer (Measure R-phi at const. Z)
475	{
476	TVectorD dRphz(5); dRphz.Zero(); // R-phi derivatives @ const. z
477	dRphz = derRphi_Z(tPar, zi);
478	//
479	Rm(im, 0) = dRphz(0); // D derivative
480	Rm(im, 1) = dRphz(1); // phi0 derivative
481	Rm(im, 2) = dRphz(2); // C derivative
482	Rm(im, 3) = dRphz(3); // z0 derivative
483	Rm(im, 4) = dRphz(4); // cot(theta) derivative
484	}
485	}
486	if (nmi + 1 == 2) // Lower layer measurements
487	{
488	stri = fG->lStL(i); // Stereo angle
489	Double_t csa = TMath::Cos(stri);
490	Double_t ssa = TMath::Sin(stri);
491	sig = fG->lSgL(i); // Resolution
492	if (ityp == 1) // Barrel type layer (measure R-phi, stereo or z at const. R)
493	{
494	//
495	// Exact solution
496	dRphi = derRphi_R(tPar, Ri);
497	dRz = derZ_R (tPar, Ri);
498	//
499	Rm(im, 0) = csa * dRphi(0) - ssa * dRz(0); // D derivative
500	Rm(im, 1) = csa * dRphi(1) - ssa * dRz(1); // phi0 derivative
501	Rm(im, 2) = csa * dRphi(2) - ssa * dRz(2); // C derivative
502	Rm(im, 3) = csa * dRphi(3) - ssa * dRz(3); // z0 derivative
503	Rm(im, 4) = csa * dRphi(4) - ssa * dRz(4); // cot(theta) derivative
504	}
505	if (ityp == 2) // Z type layer (Measure R at const. z)
506	{
507	TVectorD dRRz(5); dRRz.Zero(); // R derivatives @ const. z
508	dRRz = derR_Z(tPar, zi);
509	//
510	Rm(im, 0) = dRRz(0); // D derivative
511	Rm(im, 1) = dRRz(1); // phi0 derivative
512	Rm(im, 2) = dRRz(2); // C derivative
513	Rm(im, 3) = dRRz(3); // z0 derivative
514	Rm(im, 4) = dRRz(4); // cot(theta) derivative
515	}
516	}
517	// Derivative calculation completed
518	//
519	// Now calculate measurement error matrix
520	//
521	Int_t km = 0;
522	Double_t CosMin = TMath::Sin(TMath::Pi() / 9.); // Protect for derivative explosion
523	for (Int_t kk = 0; kk <= ii; kk++)
524	{
525	Int_t k = ih[kk]; // True layer number
526	Int_t ktyp = fG->lTyp(k); // Layer type Barrel or disk
527	Int_t nmeak = fG->lND(k); // # measurements in layer
528	if (fG->isMeasure(k))
529	{
530	for (Int_t nmk = 0; nmk < nmeak; nmk++)
531	{
532	Double_t strk = 0;
533	if (nmk + 1 == 1) strk = fG->lStU(k); // Stereo angle upper
534	if (nmk + 1 == 2) strk = fG->lStL(k); // Stereo angle lower
535	//if (im == km && Res) Sm(im, km) += sig*sig; // Detector resolution on diagonal
536	if (im == km && Res) {
537	Double_t sg = sig;
538	if(TMath::Abs(strk) < TMath::Pi()/6. && cs[kk] < CosMin)
539	TMath::Min(1000.*sig,sg = sig/pow(cs[kk],4));
540	Sm(im, km) += sg * sg; // Detector resolution on diagonal
541	}
542	//
543	// Loop on all layers below for MS contributions
544	for (Int_t jj = 0; jj < kk; jj++)
545	{
546	Double_t di = dik(ii, jj);
547	Double_t dk = dik(kk, jj);
548	Double_t ms = thms[jj];
549	Double_t msk = ms; Double_t msi = ms;
550	if (ityp == 1) msi = ms / snt; // Barrel
551	else if (ityp == 2) msi = ms / cst; // Disk
552	if (ktyp == 1) msk = ms / snt; // Barrel
553	else if (ktyp == 2) msk = ms / cst; // Disk
554	Double_t ci = TMath::Abs(TMath::Cos(stri)); Double_t si = TMath::Abs(TMath::Sin(stri));
555	Double_t ck = TMath::Abs(TMath::Cos(strk)); Double_t sk = TMath::Abs(TMath::Sin(strk));
556	Sm(im, km) += didk(cickmsms + siskmsimsk); // Ms contribution
557	}
558	//
559	Sm(km, im) = Sm(im, km);
560	km++;
561	}
562	}
563	}
564	im++; mTot = im;
565	}
566	}
567	}
568	Sm.ResizeTo(mTot, mTot);
569	TMatrixDSym SmTemp = Sm;
570	Rm.ResizeTo(mTot, 5);
571	//
572	//**********************************************************************
573	// Calculate covariance from derivatives and measurement error matrix *
574	//**********************************************************************
575	//
576	TMatrixDSym DSmInv(mTot); DSmInv.Zero();
577	for (Int_t id = 0; id < mTot; id++) DSmInv(id, id) = 1.0 / TMath::Sqrt(Sm(id, id));
578	TMatrixDSym SmN = Sm.Similarity(DSmInv); // Normalize diagonal to 1
579	//
580	// Protected matrix inversions
581	//
582	TDecompChol Chl(SmN,1.e-12);
583	TMatrixDSym SmNinv = SmN;
584	if (Chl.Decompose())
585	{
586	Bool_t OK;
587	SmNinv = Chl.Invert(OK);
588	}
589	else
590	{
591	std::cout << "SolTrack::CovCalc: Error matrix not positive definite. Recovering ...." << std::endl;
592	//cout << "pt = " << pt() << endl;
593	if (ntry < ntrymax)
594	{
595	SmNinv.Print();
596	ntry++;
597	}
598	//
599	TMatrixDSym rSmN = MakePosDef(SmN); SmN = rSmN;
600	TDecompChol rChl(SmN);
601	SmNinv = SmN;
602	Bool_t OK = rChl.Decompose();
603	SmNinv = rChl.Invert(OK);
604	}
605	Sm = SmNinv.Similarity(DSmInv); // Error matrix inverted
606	TMatrixDSym H = Sm.SimilarityT(Rm); // Calculate half Hessian
607	const Int_t Npar = 5;
608	TMatrixDSym DHinv(Npar); DHinv.Zero();
609	for (Int_t i = 0; i < Npar; i++)DHinv(i, i) = 1.0 / TMath::Sqrt(H(i, i));
610	TMatrixDSym Hnrm = H.Similarity(DHinv);
611	// Invert and restore
612	Hnrm.Invert();
613	fCov = Hnrm.Similarity(DHinv);
614	//
615	// debug
616	//
617	if(TMath::IsNaN(fCov(0,0)))
618	{
619	std::cout<<"SolTrack::CovCalc: NaN found in covariance matrix"<<std::endl;
620	}
621	//
622	// Lots of cleanup to do
623	delete[] zhh;
624	delete[] rhh;
625	delete[] dhh;
626	delete[] ihh;
627	delete[] hord;
628	delete[] zh;
629	delete[] rh;
630	delete[] ih;
631	delete[] cs;
632	delete[] thms;
633	}
634	//
635	// Force positive definitness in normalized matrix
636	TMatrixDSym SolTrack::MakePosDef(TMatrixDSym NormMat)
637	{
638	//
639	// Input: symmetric matrix with 1's on diagonal
640	// Output: positive definite matrix with 1's on diagonal
641	//
642	// Default return value
643	TMatrixDSym rMatN = NormMat;
644	// Check the diagonal
645	Bool_t Check = kFALSE;
646	Int_t Size = NormMat.GetNcols();
647	for (Int_t i = 0; i < Size; i++)if (TMath::Abs(NormMat(i, i) - 1.0)>1.0E-15)Check = kTRUE;
648	if (Check)
649	{
650	std::cout << "SolTrack::MakePosDef: input matrix doesn ot have 1 on diagonal. Abort." << std::endl;
651	return rMatN;
652	}
653	//
654	// Diagonalize matrix
655	TMatrixDSymEigen Eign(NormMat);
656	TMatrixD U = Eign.GetEigenVectors();
657	TVectorD lambda = Eign.GetEigenValues();
658	//cout << "Eigenvalues:"; lambda.Print();
659	//cout << "Input matrix: "; NormMat.Print();
660	// Reset negative eigenvalues to small positive value
661	TMatrixDSym D(Size); D.Zero(); Double_t eps = 1.0e-13;
662	for (Int_t i = 0; i < Size; i++)
663	{
664	D(i, i) = lambda(i);
665	if (lambda(i) <= 0) D(i, i) = eps;
666	}
667	//Rebuild matrix
668	TMatrixD Ut(TMatrixD::kTransposed, U);
669	TMatrixD rMat = (UD)Ut; // Now it is positive defite
670	// Restore all ones on diagonal
671	for (Int_t i1 = 0; i1 < Size; i1++)
672	{
673	Double_t rn1 = TMath::Sqrt(rMat(i1, i1));
674	for (Int_t i2 = 0; i2 <= i1; i2++)
675	{
676	Double_t rn2 = TMath::Sqrt(rMat(i2, i2));
677	rMatN(i1, i2) = 0.5(rMat(i1, i2) + rMat(i2, i1)) / (rn1rn2);
678	rMatN(i2, i1) = rMatN(i1, i2);
679	}
680	}
681	//cout << "Rebuilt matrix: "; rMatN.Print();
682	return rMatN;
683	}

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