#include "AliHelix.h"
#include "AliKalmanTrack.h"
-#include "AliExternalTrackParam.h"
+#include "AliTracker.h"
#include "TMath.h"
ClassImp(AliHelix)
alpha=t.GetAlpha();
//
//circle parameters
- fHelix[4]=fHelix[4]/t.GetConvConst(); // C
+ //PH Sometimes fP4 and fHelix[4] are very big and the calculation
+ //PH of the Sqrt cannot be done. To be investigated...
+ fHelix[4]=fHelix[4]/(1000/0.299792458/AliTracker::GetBz()); // C
cs=TMath::Cos(alpha); sn=TMath::Sin(alpha);
Double_t xc, yc, rc;
rc = 1/fHelix[4];
xc = x-fHelix[2]*rc;
- yc = fHelix[0]+TMath::Sqrt(1-(x-xc)*(x-xc)*fHelix[4]*fHelix[4])/fHelix[4];
+ Double_t dummy = 1-(x-xc)*(x-xc)*fHelix[4]*fHelix[4];
+ if (dummy<0) {
+ AliError(Form("The argument of the Sqrt is %f => set to 0\n",dummy));
+ dummy = 0;
+ }
+ yc = fHelix[0]+TMath::Sqrt(dummy)/fHelix[4];
fHelix[6] = xc*cs - yc*sn;
fHelix[7] = xc*sn + yc*cs;
fHelix[5]=x*cs - fHelix[0]*sn; // x0
fHelix[0]=x*sn + fHelix[0]*cs; // y0
//fHelix[1]= // z0
- fHelix[2]=TMath::ASin(fHelix[2]) + alpha; // phi0
+ fHelix[2]=TMath::ATan2(-(fHelix[5]-fHelix[6]),fHelix[0]-fHelix[7]); // phi0
+ if (fHelix[4]>0) fHelix[2]-=TMath::Pi();
+
//fHelix[3]= // tgl
//
//
fHelix[5] = fHelix[6];
fHelix[0] = fHelix[7];
- //fHelix[5]-=TMath::Sin(fHelix[2])/fHelix[4];
- //fHelix[0]+=TMath::Cos(fHelix[2])/fHelix[4];
}
Double_t alpha,x,cs,sn;
const Double_t *param =t.GetParameter();
for (Int_t i=0;i<5;i++) fHelix[i]=param[i];
- x = t.X();
- alpha=t.Alpha();
+ x = t.GetX();
+ alpha=t.GetAlpha();
//
//circle parameters
- fHelix[4]=fHelix[4]/AliKalmanTrack::GetConvConst(); // C
+ //PH Sometimes fP4 and fHelix[4] are very big and the calculation
+ //PH of the Sqrt cannot be done. To be investigated...
+ fHelix[4]=fHelix[4]/(1000/0.299792458/AliTracker::GetBz()); // C
cs=TMath::Cos(alpha); sn=TMath::Sin(alpha);
Double_t xc, yc, rc;
rc = 1/fHelix[4];
xc = x-fHelix[2]*rc;
- yc = fHelix[0]+TMath::Sqrt(1-(x-xc)*(x-xc)*fHelix[4]*fHelix[4])/fHelix[4];
+ Double_t dummy = 1-(x-xc)*(x-xc)*fHelix[4]*fHelix[4];
+ if (dummy<0) {
+ AliError(Form("The argument of the Sqrt is %f => set to 0\n",dummy));
+ dummy = 0;
+ }
+ yc = fHelix[0]+TMath::Sqrt(dummy)/fHelix[4];
fHelix[6] = xc*cs - yc*sn;
fHelix[7] = xc*sn + yc*cs;
//
fHelix[5] = fHelix[6];
fHelix[0] = fHelix[7];
- //fHelix[5]-=TMath::Sin(fHelix[2])/fHelix[4];
- //fHelix[0]+=TMath::Cos(fHelix[2])/fHelix[4];
}
AliHelix::AliHelix(Double_t x[3], Double_t p[3], Double_t charge, Double_t conversion)
//
Double_t pt = TMath::Sqrt(p[0]*p[0]+p[1]*p[1]);
if (TMath::Abs(conversion)<0.00000001)
- conversion = AliKalmanTrack::GetConvConst();
+ conversion = 1000/0.299792458/AliTracker::GetBz();
//
//
fHelix[4] = charge/(conversion*pt); // C
}
-void AliHelix::GetMomentum(Double_t phase, Double_t p[4],Double_t conversion)
+void AliHelix::GetMomentum(Double_t phase, Double_t p[4],Double_t conversion, Double_t *xr)
{
// return momentum at given phase
Double_t x[3],g[3],gg[3];
Evaluate(phase,x,g,gg);
- if (TMath::Abs(conversion)<0.0001) conversion = AliKalmanTrack::GetConvConst();
+ if (TMath::Abs(conversion)<0.0001) conversion = 1000/0.299792458/AliTracker::GetBz();
Double_t mt = TMath::Sqrt(g[0]*g[0]+g[1]*g[1]);
p[0] = fHelix[8]*g[0]/(mt*conversion);
p[1] = fHelix[8]*g[1]/(mt*conversion);
p[2] = fHelix[8]*g[2]/(mt*conversion);
+ if (xr){
+ xr[0] = x[0]; xr[1] = x[1]; xr[2] = x[2];
+ }
}
void AliHelix::GetAngle(Double_t t1, AliHelix &h, Double_t t2, Double_t angle[3])
//
angle[0] = (g1[0]*g2[0]+g1[1]*g2[1])/(norm1r*norm2r); // angle in phi projection
if (TMath::Abs(angle[0])<1.) angle[0] = TMath::ACos(angle[0]);
- else angle[0]=0;
+ else{
+ if (angle[0]>0) angle[0] = 0;
+ if (angle[0]<0) angle[0] = TMath::Pi();
+ }
//
angle[1] = ((norm1r*norm2r)+g1[2]*g2[2])/(norm1*norm2); // angle in rz projection
if (TMath::Abs(angle[1])<1.) angle[1] = TMath::ACos(angle[1]);
- else angle[1]=0;
+ else
+ angle[1]=0;
angle[2] = (g1[0]*g2[0]+g1[1]*g2[1]+g1[2]*g2[2])/(norm1*norm2); //3D angle
if (TMath::Abs(angle[2])<1.) angle[2] = TMath::ACos(angle[2]);
- else angle[2]=0;
+ else
+ angle[2]=0;
Double_t phase=fHelix[4]*t+fHelix[2];
Double_t sn=TMath::Sin(phase), cs=TMath::Cos(phase);
- //r[0] = fHelix[5] + (sn - fHelix[6])/fHelix[4];
- //r[1] = fHelix[0] - (cs - fHelix[7])/fHelix[4];
r[0] = fHelix[5] + sn/fHelix[4];
r[1] = fHelix[0] - cs/fHelix[4];
r[2] = fHelix[1] + fHelix[3]*t;
gg[0]=-fHelix[4]*sn; gg[1]=fHelix[4]*cs; gg[2]=0.;
}
+Int_t AliHelix::GetClosestPhases(AliHelix &h, Double_t phase[2][2])
+{
+ //
+ // get phases to minimize distances
+ //
+ Double_t xyz0[3];
+ Double_t xyz1[3];
+
+ for (Int_t i=0;i<2;i++){
+ Evaluate(phase[i][0] ,xyz0);
+ h.Evaluate(phase[i][1],xyz1);
+ Double_t mindist = TMath::Sqrt((xyz0[0]-xyz1[0])*(xyz0[0]-xyz1[0])+
+ (xyz0[1]-xyz1[1])*(xyz0[1]-xyz1[1])+
+ (xyz0[2]-xyz1[2])*(xyz0[2]-xyz1[2]));
+ Double_t tbest[2]={phase[i][0],phase[i][1]};
+ for (Int_t i0=-1;i0<=1;i0++){
+ Double_t t0 = ((phase[i][0]*fHelix[4])+i0*2.*TMath::Pi())/fHelix[4];
+ Evaluate(t0,xyz0);
+ for (Int_t i1=-1;i1<=1;i1++){
+ Double_t t1 = ((phase[i][1]*h.fHelix[4])+i1*2.*TMath::Pi())/h.fHelix[4];
+ h.Evaluate(t1,xyz1);
+ Double_t dist = TMath::Sqrt((xyz0[0]-xyz1[0])*(xyz0[0]-xyz1[0])+
+ (xyz0[1]-xyz1[1])*(xyz0[1]-xyz1[1])+
+ (xyz0[2]-xyz1[2])*(xyz0[2]-xyz1[2]));
+ if (dist<=mindist){
+ tbest[0] = t0;
+ tbest[1] = t1;
+ mindist=dist;
+ }
+ }
+ }
+ phase[i][0] = tbest[0];
+ phase[i][1] = tbest[1];
+ }
+ return 1;
+}
+
+Double_t AliHelix::GetPointAngle(AliHelix &h, Double_t phase[2], const Float_t * vertex)
+{
+ //
+ // get point angle bettwen two helixes
+ //
+ Double_t r0[3],p0[4];
+ Double_t r1[3],p1[4];
+ GetMomentum(phase[0],p0,1,r0);
+ h.GetMomentum(phase[1],p1,1,r1);
+ //
+ Double_t r[3] = {(r0[0]+r1[0])*0.5-vertex[0],(r0[1]+r1[1])*0.5-vertex[1],(r0[2]+r1[2])*0.5-vertex[2]};
+ //intersection point - relative to the prim vertex
+ Double_t p[3] = { p0[0]+p1[0], p0[1]+p1[1],p0[2]+p1[2]};
+ // derivation vector
+ Double_t normr = TMath::Sqrt(r[0]*r[0]+r[1]*r[1]+r[2]*r[2]);
+ Double_t normp = TMath::Sqrt(p[0]*p[0]+p[1]*p[1]+p[2]*p[2]);
+ Double_t pointAngle = (r[0]*p[0]+r[1]*p[1]+r[2]*p[2])/(normr*normp);
+ return pointAngle;
+}
+
Double_t AliHelix::GetPhase(Double_t x, Double_t y )
{
//
//calculate helix param at given x,y point
//
- Double_t phase = (x-fHelix[5])*fHelix[4];
- if (TMath::Abs(phase)>=1)
- phase = TMath::Sign(0.99999999999,phase);
- phase = TMath::ASin(phase);
-
- if ( ( ( fHelix[0]-y)*fHelix[4]) < 0.) {
- if (phase>0)
- phase = TMath::Pi()-phase;
- else
- phase = -(TMath::Pi()+phase);
- }
- if ( (phase-fHelix[2])>TMath::Pi()) phase = phase-2.*TMath::Pi();
- if ( (phase-fHelix[2])<-TMath::Pi()) phase = phase+2.*TMath::Pi();
+ //Double_t phase2 = TMath::ATan2((y-fHelix[0]), (x-fHelix[5]))- TMath::Pi()/2.;
+ Double_t phase2 = TMath::ATan2(-(x-fHelix[5]),(y-fHelix[0]));
+ Int_t sign = (fHelix[4]>0)? 1:-1;
+ if (sign>0) phase2 = phase2-TMath::Pi();
+ //
+ Float_t delta = TMath::Nint((phase2-fHelix[2])/(2.*TMath::Pi()));
+ phase2-= 2*TMath::Pi()*delta;
+ if ( (phase2-fHelix[2])>TMath::Pi()) phase2 -=2.*TMath::Pi();
+ if ( (phase2-fHelix[2])<-TMath::Pi()) phase2+=2.*TMath::Pi();
- Double_t t = (phase-fHelix[2])/fHelix[4];
-
- // Double_t r[3];
- //Evaluate(t,r);
- //if ( (TMath::Abs(r[0]-x)>0.01) || (TMath::Abs(r[1]-y)>0.01)){
- // Double_t phase = (x-fHelix[5])*fHelix[4];
- // printf("problem\n");
- //}
+ Double_t t = (phase2-fHelix[2]);
+ t/=fHelix[4];
return t;
}
// Double_t * c1 = &fHelix[6];
//Double_t * c2 = &(h.fHelix[6]);
// Double_t c1[3] = {fHelix[5],fHelix[0],fHelix[8]};
+
+ // PH initiaziation in case of return
+ phase[0][0]=phase[0][1]=phase[1][0]=phase[1][1]=0;
+ ri[0]=ri[1]=1000000;
+
Double_t c1[3] = {0,0,fHelix[8]};
Double_t c2[3] = {h.fHelix[5]-fHelix[5],h.fHelix[0]-fHelix[0],h.fHelix[8]};
x0[0] = (d+c1[2]-c2[2])*c2[0]/(2*d)+ fHelix[5];
y0[0] = (d+c1[2]-c2[2])*c2[1]/(2*d)+ fHelix[0];
// return 0;
- phase[0][0] = GetPhase(x0[0],y0[0]);
- phase[0][1] = h.GetPhase(x0[0],y0[0]);
- ri[0] = x0[0]*x0[0]+y0[0]*y0[0];
+ phase[1][0] = phase[0][0] = GetPhase(x0[0],y0[0]);
+ phase[1][1] = phase[0][1] = h.GetPhase(x0[0],y0[0]);
+ ri[1] = ri[0] = x0[0]*x0[0]+y0[0]*y0[0];
return 1;
}
if ( (d+c2[2])<c1[2]){
//
Double_t xx = c2[0]+ c2[0]*c2[2]/d+ fHelix[5];
Double_t yy = c2[1]+ c2[1]*c2[2]/d+ fHelix[0];
- phase[0][1] = h.GetPhase(xx,yy);
+ phase[1][1] = phase[0][1] = h.GetPhase(xx,yy);
//
Double_t xx2 = c2[0]*c1[2]/d+ fHelix[5];
Double_t yy2 = c2[1]*c1[2]/d+ fHelix[0];
- phase[0][0] = GetPhase(xx2,yy2);
- ri[0] = xx*xx+yy*yy;
+ phase[1][0] = phase[0][0] = GetPhase(xx2,yy2);
+ ri[1] = ri[0] = xx*xx+yy*yy;
return 1;
}
//
Double_t xx = -c2[0]*c1[2]/d+ fHelix[5];
Double_t yy = -c2[1]*c1[2]/d+ fHelix[0];
- phase[0][1] = GetPhase(xx,yy);
+ phase[1][1] = phase[0][1] = GetPhase(xx,yy);
//
Double_t xx2 = c2[0]- c2[0]*c2[2]/d+ fHelix[5];
Double_t yy2 = c2[1]- c2[1]*c2[2]/d+ fHelix[0];
- phase[0][0] = h.GetPhase(xx2,yy2);
- ri[0] = xx*xx+yy*yy;
+ phase[1][0] = phase[0][0] = h.GetPhase(xx2,yy2);
+ ri[1] = ri[0] = xx*xx+yy*yy;
return 1;
}
return 2;
}
-/*
-
-Int_t AliHelix::GetRPHIintersections(AliHelix &h, Double_t phase[2][2], Double_t ri[2], Double_t cut)
-{
- //--------------------------------------------------------------------
- // This function returns phase vectors with intesection between helix (0, 1 or 2)
- // in x-y plane projection
- //--------------------------------------------------------------------
- //
- Double_t * c1 = &fHelix[6];
- Double_t * c2 = &(h.fHelix[6]);
- Double_t d = TMath::Sqrt((c1[0]-c2[0])*(c1[0]-c2[0])+(c1[1]-c2[1])*(c1[1]-c2[1]));
- //
- Double_t x0[2];
- Double_t y0[2];
- //
- if ( d>=(c1[2]+c2[2])){
- if (d>=(c1[2]+c2[2]+cut)) return 0;
- x0[0] = c1[0]+ (d+c1[2]-c2[2])*(c2[0]-c1[0])/(2*d);
- y0[0] = c1[1]+ (d+c1[2]-c2[2])*(c2[1]-c1[1])/(2*d);
- return 0;
- phase[0][0] = GetPhase(x0[0],y0[0]);
- phase[0][1] = h.GetPhase(x0[0],y0[0]);
- ri[0] = x0[0]*x0[0]+y0[0]*y0[0];
- return 1;
- }
- if ( (d+c2[2])<c1[2]){
- if ( (d+c2[2])+cut<c1[2]) return 0;
- //
- Double_t xx = c2[0]+ (c2[0]-c1[0])*c2[2]/d;
- Double_t yy = c2[1]+ (c2[1]-c1[1])*c2[2]/d;
- phase[0][1] = h.GetPhase(xx,yy);
- //
- Double_t xx2 = c1[0]- (c1[0]-c2[0])*c1[2]/d;
- Double_t yy2 = c1[1]- (c1[1]-c2[1])*c1[2]/d;
- phase[0][0] = GetPhase(xx2,yy2);
- //if ( (TMath::Abs(xx2-xx)>cut)||(TMath::Abs(yy2-yy)>cut)){
- // printf("problem\n");
- //}
- ri[0] = xx*xx+yy*yy;
- return 1;
- }
-
- if ( (d+c1[2])<c2[2]){
- if ( (d+c1[2])+cut<c2[2]) return 0;
- //
- Double_t xx = c1[0]+ (c1[0]-c2[0])*c1[2]/d;
- Double_t yy = c1[1]+ (c1[1]-c2[1])*c1[2]/d;
- phase[0][1] = GetPhase(xx,yy);
- //
- Double_t xx2 = c2[0]- (c2[0]-c1[0])*c2[2]/d;
- Double_t yy2 = c2[1]- (c2[1]-c1[1])*c2[2]/d;
- phase[0][0] = h.GetPhase(xx2,yy2);
- //if ( (TMath::Abs(xx2-xx)>cut)||(TMath::Abs(yy2-yy)>cut)){
- // printf("problem\n");
- //}
- ri[0] = xx*xx+yy*yy;
- return 1;
- }
-
- Double_t d1 = (d*d+c1[2]*c1[2]-c2[2]*c2[2])/(2.*d);
- Double_t v1 = c1[2]*c1[2]-d1*d1;
- if (v1<0) return 0;
- v1 = TMath::Sqrt(v1);
- //
- x0[0] = c1[0]+ ((c2[0]-c1[0])*d1-(c1[1]-c2[1])*v1)/d;
- y0[0] = c1[1]+ ((c2[1]-c1[1])*d1+(c1[0]-c2[0])*v1)/d;
- //
- x0[1] = c1[0]+ ((c2[0]-c1[0])*d1+(c1[1]-c2[1])*v1)/d;
- y0[1] = c1[1]+ ((c2[1]-c1[1])*d1-(c1[0]-c2[0])*v1)/d;
- //
- for (Int_t i=0;i<2;i++){
- phase[i][0] = GetPhase(x0[i],y0[i]);
- phase[i][1] = h.GetPhase(x0[i],y0[i]);
- ri[i] = x0[i]*x0[i]+y0[i]*y0[i];
- }
- return 2;
-}
-*/
Int_t AliHelix::LinearDCA(AliHelix &h, Double_t &t1, Double_t &t2,
}
-
-
-/*
Int_t AliHelix::ParabolicDCA(AliHelix&h, //helixes
Double_t &t1, Double_t &t2,
Double_t &R, Double_t &dist, Int_t iter)
iter++;
while (iter--) {
-
- Double_t gt1=-(dx*g1[0]/dx2 + dy*g1[1]/dy2 + dz*g1[2]/dz2);
- Double_t gt2=+(dx*g2[0]/dx2 + dy*g2[1]/dy2 + dz*g2[2]/dz2);
- Double_t h11=(g1[0]*g1[0] - dx*gg1[0])/dx2 +
- (g1[1]*g1[1] - dy*gg1[1])/dy2 +
- (g1[2]*g1[2] - dz*gg1[2])/dz2;
- Double_t h22=(g2[0]*g2[0] + dx*gg2[0])/dx2 +
- (g2[1]*g2[1] + dy*gg2[1])/dy2 +
- (g2[2]*g2[2] + dz*gg2[2])/dz2;
- Double_t h12=-(g1[0]*g2[0]/dx2 + g1[1]*g2[1]/dy2 + g1[2]*g2[2]/dz2);
-
- Double_t det=h11*h22-h12*h12;
-
- Double_t dt1,dt2;
- if (TMath::Abs(det)<1.e-33) {
- //(quasi)singular Hessian
- dt1=-gt1; dt2=-gt2;
- } else {
- dt1=-(gt1*h22 - gt2*h12)/det;
- dt2=-(h11*gt2 - h12*gt1)/det;
- }
-
- if ((dt1*gt1+dt2*gt2)>0) {dt1=-dt1; dt2=-dt2;}
-
- //check delta(phase1) ?
- //check delta(phase2) ?
-
- if (TMath::Abs(dt1)/(TMath::Abs(t1)+1.e-3) < 1.e-4)
- if (TMath::Abs(dt2)/(TMath::Abs(t2)+1.e-3) < 1.e-4) {
- //if ((gt1*gt1+gt2*gt2) > 1.e-4/dy2/dy2)
- // Warning("GetDCA"," stopped at not a stationary point !\n");
- Double_t lmb=h11+h22; lmb=lmb-TMath::Sqrt(lmb*lmb-4*det);
- if (lmb < 0.)
- //Warning("GetDCA"," stopped at not a minimum !\n");
- break;
- }
-
- Double_t dd=dm;
- for (Int_t div=1 ; ; div*=2) {
- Evaluate(t1+dt1,r1,g1,gg1);
- h.Evaluate(t2+dt2,r2,g2,gg2);
- dx=r2[0]-r1[0]; dy=r2[1]-r1[1]; dz=r2[2]-r1[2];
- dd=dx*dx/dx2 + dy*dy/dy2 + dz*dz/dz2;
- if (dd<dm) break;
- dt1*=0.5; dt2*=0.5;
- if (div>512) {
- //Warning("GetDCA"," overshoot !\n");
- break;
- }
- }
- dm=dd;
-
- t1+=dt1;
- t2+=dt2;
-
+ Double_t gt1=-(dx*g1[0]/dx2 + dy*g1[1]/dy2 + dz*g1[2]/dz2);
+ Double_t gt2=+(dx*g2[0]/dx2 + dy*g2[1]/dy2 + dz*g2[2]/dz2);
+
+ Double_t h11=(g1[0]*g1[0] - dx*gg1[0])/dx2 +
+ (g1[1]*g1[1] - dy*gg1[1])/dy2 +
+ (g1[2]*g1[2] - dz*gg1[2])/dz2;
+ Double_t h22=(g2[0]*g2[0] + dx*gg2[0])/dx2 +
+ (g2[1]*g2[1] + dy*gg2[1])/dy2 +
+ (g2[2]*g2[2] + dz*gg2[2])/dz2;
+ Double_t h12=-(g1[0]*g2[0]/dx2 + g1[1]*g2[1]/dy2 + g1[2]*g2[2]/dz2);
+
+ Double_t det=h11*h22-h12*h12;
+
+ Double_t dt1,dt2;
+ if (TMath::Abs(det)<1.e-33) {
+ //(quasi)singular Hessian
+ dt1=-gt1; dt2=-gt2;
+ } else {
+ dt1=-(gt1*h22 - gt2*h12)/det;
+ dt2=-(h11*gt2 - h12*gt1)/det;
+ }
+
+ if ((dt1*gt1+dt2*gt2)>0) {dt1=-dt1; dt2=-dt2;}
+
+ //if (TMath::Abs(dt1)/(TMath::Abs(t1)+1.e-3) < 1.e-4)
+ // if (TMath::Abs(dt2)/(TMath::Abs(t2)+1.e-3) < 1.e-4) {
+ // break;
+ // }
+
+ Double_t dd=dm;
+ for (Int_t div=1 ; div<512 ; div*=2) {
+ Evaluate(t1+dt1,r1,g1,gg1);
+ h.Evaluate(t2+dt2,r2,g2,gg2);
+ dx=r2[0]-r1[0]; dy=r2[1]-r1[1]; dz=r2[2]-r1[2];
+ dd=dx*dx/dx2 + dy*dy/dy2 + dz*dz/dz2;
+ if (dd<dm) break;
+ dt1*=0.5; dt2*=0.5;
+ if (div==0){
+ div =1;
+ }
+ if (div>512) {
+ break;
+ }
+ }
+ dm=dd;
+ t1+=dt1;
+ t2+=dt2;
}
-
Evaluate(t1,r1,g1,gg1);
h.Evaluate(t2,r2,g2,gg2);
//
(r1[2]-r2[2])*(r1[2]-r2[2]);
R = ((r1[0]+r2[0])*(r1[0]+r2[0])+(r1[1]+r2[1])*(r1[1]+r2[1]))/4;
+ return 0;
}
-*/
-
-
-
-
-Int_t AliHelix::ParabolicDCA(AliHelix&h, //helixes
+Int_t AliHelix::ParabolicDCA2(AliHelix&h, //helixes
Double_t &t1, Double_t &t2,
- Double_t &R, Double_t &dist, Int_t iter)
+ Double_t &R, Double_t &dist, Double_t err[3], Int_t iter)
{
//
//
h.Evaluate(t2,r2,g2,gg2);
//
- Double_t dx2=1.;
- Double_t dy2=1.;
- Double_t dz2=1.;
+ Double_t dx2=err[0];
+ Double_t dy2=err[1];
+ Double_t dz2=err[2];
//
Double_t dx=r2[0]-r1[0], dy=r2[1]-r1[1], dz=r2[2]-r1[2];
Double_t dm=dx*dx/dx2 + dy*dy/dy2 + dz*dz/dz2;