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20 double result1, result2, result3;
23 result1 /=
pow(
y, 2) - (
x +
z) *
y +
z *
x;
26 result2 /=
pow(
x, 2) - (
x -
z) *
y -
z *
x;
29 result3 /=
pow(
z, 2) + (
x -
z) *
y -
z *
x;
31 return result1 + result2 + result3;
37 double result1, result2;
40 result1 *=
z *
x / (
z -
x);
44 return (result1 + result2) / (
z -
x);
49 double pulse(
double x,
double y,
double z,
double t) {
56 if ((
x == 0) && (
y ==
z))
66 double fpeak(
double *
x,
double *par) {
73 double t =
x[0] - t_0;
86 double width = par[3];
88 return a_0 +
s * TMath::Erf((
x[0] - t_0) /
width);
93 double c_exp = par[1];
94 double c_pow = par[2];
96 return s * TMath::Exp(
x[0] * c_exp) * (1 +
x[0] * c_pow);
99 double fdecay(
double *
x,
double *par);
102 double xm = par[6] * (
x[0] - 25);
103 double xp = par[6] * (
x[0] + 25);
104 double xz = par[6] *
x[0];
105 return 1.2131 *
fpeak(&xp, par) - 1.4715 *
fpeak(&
xz, par) + 0.4463 *
fpeak(&xm, par);
109 TF1 f(
"peak_convoluted",
fpeak, 0, 250, 4);
110 return f.IntegralError(
x[0] - par[4] / 2.,
x[0] + par[4] / 2., par,
nullptr, 1.) / (par[4]);
114 double xm = (
x[0] - 25);
115 double xp = (
x[0] + 25);
double fdeconv_convoluted(double *x, double *par)
double fpeak_convoluted(double *x, double *par)
double fturnOn(double *x, double *par)
double fdecay(double *x, double *par)
double pulse(double x, double y, double z, double t)
double fdeconv(double *x, double *par)
double pulse_x0(double y, double z, double t)
double pulse_raw(double x, double y, double z, double t)
double pulse_yz(double x, double z, double t)
double fpeak(double *x, double *par)
Power< A, B >::type pow(const A &a, const B &b)
double pulse_x0_yz(double z, double t)