test
CMS 3D CMS Logo

 All Classes Namespaces Files Functions Variables Typedefs Enumerations Enumerator Properties Friends Macros Pages
Functions
myFunctions.cc File Reference

Go to the source code of this file.

Functions

double crystalball (double *x, double *par)
 
double ene1x1_xtal (double mymatrix[], int xtal)
 
double ene3x3_xtal (double mymatrix[], int xtal)
 
double ene5x5_xtal (double mymatrix[], int xtal)
 
double ene7x7_xtal (double mymatrix[])
 
void energy_ieta (double mymatrix[], double *energyieta)
 
void energy_iphi (double mymatrix[], double *energyiphi)
 
int maxAmplitInMatrix (double myMatrix[])
 
double shapeFunction (double *x, double *par)
 

Function Documentation

double crystalball ( double *  x,
double *  par 
)

Definition at line 98 of file myFunctions.cc.

References create_public_lumi_plots::exp, HLT_25ns10e33_v2_cff::exponent, and funct::pow().

98  {
99  // par[0]: mean
100  // par[1]: sigma
101  // par[2]: alpha, crossover point
102  // par[3]: n, length of tail
103  // par[4]: N, normalization
104 
105  double cb = 0.0;
106  double exponent = 0.0;
107  double bla = 0.0;
108 
109  if (x[0] > par[0] - par[2]*par[1]) {
110  exponent = (x[0] - par[0])/par[1];
111  cb = exp(-exponent*exponent/2.);
112  } else {
113  double nenner = pow(par[3]/par[2], par[3])*exp(-par[2]*par[2]/2.);
114  double zaehler = (par[0] - x[0])/par[1] + par[3]/par[2] - par[2];
115  zaehler = pow(zaehler, par[3]);
116  cb = nenner/zaehler;
117  }
118 
119  if (par[4] > 0.) {
120  cb *= par[4];
121  }
122  return cb;
123 }
T x() const
Cartesian x coordinate.
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:40
double ene1x1_xtal ( double  mymatrix[],
int  xtal 
)

Definition at line 21 of file myFunctions.cc.

22 {
23  double E1x1 = 0.;
24  if (mymatrix[xtal]<-50) { E1x1 = -1000.; }
25  else { E1x1 = mymatrix[xtal]; }
26  return E1x1;
27 }
double ene3x3_xtal ( double  mymatrix[],
int  xtal 
)

Definition at line 30 of file myFunctions.cc.

31 {
32  double E3x3 = 0.;
33 
34  if ( (mymatrix[xtal-8]<-50) || (mymatrix[xtal-7]<-50) || (mymatrix[xtal-6]<-50) || (mymatrix[xtal-1]<-50) || (mymatrix[xtal]<-50) || (mymatrix[xtal+1]<-50) || (mymatrix[xtal+6]<-50) || (mymatrix[xtal+7]<-50) || (mymatrix[xtal+8]<-50) )
35  { E3x3 = -1000.; }
36  else
37  { E3x3 = mymatrix[xtal-8] + mymatrix[xtal-7] + mymatrix[xtal-6] + mymatrix[xtal-1] + mymatrix[xtal] + mymatrix[xtal+1] + mymatrix[xtal+6] + mymatrix[xtal+7] + mymatrix[xtal+8]; }
38 
39  return E3x3;
40 }
double ene5x5_xtal ( double  mymatrix[],
int  xtal 
)

Definition at line 43 of file myFunctions.cc.

44 {
45  double E5x5 = 0.;
46 
47  if( (mymatrix[xtal-16]<-50) || (mymatrix[xtal-15]<-50) || (mymatrix[xtal-14]<-50) || (mymatrix[xtal-13]<-50) || (mymatrix[xtal-12]<-50) || (mymatrix[xtal-9]<-50) || (mymatrix[xtal-8]<-50) || (mymatrix[xtal-7]<-50) || (mymatrix[xtal-6]<-50) || (mymatrix[xtal-5]<-50) || (mymatrix[xtal-2]<-50) || (mymatrix[xtal-1]<-50) || (mymatrix[xtal]<-50) || (mymatrix[xtal+1]<-50) || (mymatrix[xtal+2]<-50) || (mymatrix[xtal+5]<-50) || (mymatrix[xtal+6]<-50) || (mymatrix[xtal+7]<-50) || (mymatrix[xtal+8]<-50) || (mymatrix[xtal+9]<-50) || (mymatrix[xtal+12]<-50) || (mymatrix[xtal+13]<-50) || (mymatrix[xtal+14]<-50) || (mymatrix[xtal+15]<-50) || (mymatrix[xtal+16]<-50) )
48  { E5x5 = -1000.; }
49  else
50  { E5x5 = mymatrix[xtal-16] + mymatrix[xtal-15] + mymatrix[xtal-14] + mymatrix[xtal-13] + mymatrix[xtal-12] + mymatrix[xtal-9] + mymatrix[xtal-8] + mymatrix[xtal-7] + mymatrix[xtal-6] + mymatrix[xtal-5] + mymatrix[xtal-2] + mymatrix[xtal-1] + mymatrix[xtal] + mymatrix[xtal+1] + mymatrix[xtal+2] + mymatrix[xtal+5] + mymatrix[xtal+6] + mymatrix[xtal+7] + mymatrix[xtal+8] + mymatrix[xtal+9] + mymatrix[xtal+12] + mymatrix[xtal+13] + mymatrix[xtal+14] + mymatrix[xtal+15] + mymatrix[xtal+16]; }
51 
52  return E5x5;
53 }
double ene7x7_xtal ( double  mymatrix[])

Definition at line 77 of file myFunctions.cc.

References cuy::ii.

78 {
79  double E7x7 = 0.;
80 
81  for (int ii=0;ii<49;ii++)
82  {
83  if (mymatrix[ii]<-50)
84  E7x7 = -1000.;
85  else
86  E7x7 += mymatrix[ii];
87  }
88 
89  return E7x7;
90 }
int ii
Definition: cuy.py:588
void energy_ieta ( double  mymatrix[],
double *  energyieta 
)

Definition at line 56 of file myFunctions.cc.

References cuy::ii, and findQualityFiles::jj.

57 {
58  for(int jj = 0 ; jj < 5 ; jj++) energyieta[jj] = 0.0;
59 
60  for(int jj = 0 ; jj < 5 ; jj++){
61  for (int ii = 0; ii < 5 ; ii++) energyieta[jj] += mymatrix[(8+jj)+7*ii];
62  }
63 }
int ii
Definition: cuy.py:588
void energy_iphi ( double  mymatrix[],
double *  energyiphi 
)

Definition at line 66 of file myFunctions.cc.

References cuy::ii, and findQualityFiles::jj.

67 {
68  for(int jj = 0 ; jj < 5 ; jj++) energyiphi[jj] = 0.0;
69 
70  for(int jj = 0 ; jj < 5 ; jj++){
71  for (int ii = 0; ii < 5 ; ii++) energyiphi[jj] += mymatrix[(8+7*jj)+ii];
72  }
73 }
int ii
Definition: cuy.py:588
int maxAmplitInMatrix ( double  myMatrix[])

Definition at line 6 of file myFunctions.cc.

7 {
8  int maxXtal = 999;
9  double maxADC = -999.;
10 
11  for (int icry=0; icry<49; icry++) {
12  if (myMatrix[icry] > maxADC){
13  maxADC = myMatrix[icry];
14  maxXtal = icry;
15  }}
16 
17  return maxXtal;
18 }
double shapeFunction ( double *  x,
double *  par 
)

Definition at line 125 of file myFunctions.cc.

125  {
126 
127  // par[0] = constant value
128  // par[1], par[2], par[3]: a3, a2 x>0 pol3
129  // par[4], par[5], par[6]: a3, a2 x<=0 pol3
130 
131  double ret_val;
132  if(x[0]>0.)
133  ret_val = par[0] + par[1]*x[0]*x[0] + par[2]*x[0]*x[0]*x[0] + par[3]*x[0]*x[0]*x[0]*x[0];
134  else
135  ret_val = par[0] + par[4]*x[0]*x[0] + par[5]*x[0]*x[0]*x[0] + par[6]*x[0]*x[0]*x[0]*x[0];
136 
137  return ret_val;
138 }
T x() const
Cartesian x coordinate.