Belle II Software light-2406-ragdoll
KsfwMoments.cc
1/**************************************************************************
2 * basf2 (Belle II Analysis Software Framework) *
3 * Author: The Belle II Collaboration *
4 * *
5 * See git log for contributors and copyright holders. *
6 * This file is licensed under LGPL-3.0, see LICENSE.md. *
7 **************************************************************************/
8
10// //
11// KsfwMoments.cc //
12// //
13// moment-calculation of the k_sfw //
14// improved Super-Fox-Wolfram moments //
15// to be used with rooksfw.{cc,h} //
16// //
17// M. Nakao //
18// //
20
21#include <analysis/ContinuumSuppression/KsfwMoments.h>
22
23
24namespace Belle2 {
33 inline double legendre(const double z, const int i)
34 {
35 switch (i) {
36 case 0: return 1.;
37 case 1: return z;
38 case 2: return 1.5 * z * z - 0.5;
39 case 3: return z * (2.5 * z * z - 1.5);
40 case 4: return (4.375 * z * z * z * z - 3.75 * z * z + 0.375);
41 default: return 0;
42 }
43 }
44// ----------------------------------------------------------------------
45// Constructor
46// (copied from k_sfw.cc with minimum modification)
47// ----------------------------------------------------------------------
48 KsfwMoments::KsfwMoments(double Hso0_max,
49 std::vector<std::pair<ROOT::Math::XYZVector, int>> p3_cms_q_sigA,
50 std::vector<std::pair<ROOT::Math::XYZVector, int>> p3_cms_q_sigB,
51 std::vector<std::pair<ROOT::Math::XYZVector, int>> p3_cms_q_roe,
52 const ROOT::Math::PxPyPzEVector& p_cms_missA,
53 const ROOT::Math::PxPyPzEVector& p_cms_missB,
54 const double et[2]
55 )
56 {
57 // Private member needs to be initialized. Here it is initialized to -1 (illegal value).
58 m_uf = -1;
59
60 m_et[0] = et[0];
61 m_et[1] = et[1];
62
63 m_mm2[0] = p_cms_missA.E() > 0
64 ? p_cms_missA.mag2()
65 : -p_cms_missA.E() * p_cms_missA.E() - p_cms_missA.P2();
66 m_mm2[1] = p_cms_missB.E() > 0
67 ? p_cms_missB.mag2()
68 : -p_cms_missB.E() * p_cms_missB.E() - p_cms_missB.P2();
69
70 //========================
71 // Calculate discriminants
72 //========================
73 std::vector<std::pair<ROOT::Math::XYZVector, int>>::iterator pqi, pqj;
74
75 // Calculate Hso components
76 for (int i = 0; i < 3; i++) {
77 for (int k = 0; k < 5; k++) {
78 m_Hso[0][i][k] = m_Hso[1][i][k] = 0;
79 }
80 }
81
82 // Signal A (use_finalstate_for_sig == 0)
83 for (pqi = p3_cms_q_sigA.begin(); pqi != p3_cms_q_sigA.end(); ++pqi) {
84 const double pi_mag((pqi->first).R());
85 for (pqj = p3_cms_q_roe.begin(); pqj != p3_cms_q_roe.end(); ++pqj) {
86 const double pj_mag((pqj->first).R());
87 const double ij_cos((pqi->first).Dot(pqj->first) / pi_mag / pj_mag);
88 const int c_or_n(0 == (pqj->second) ? 1 : 0); // 0: charged 1: neutral
89 for (int k = 0; k < 5; k++) {
90 m_Hso[0][c_or_n][k] += (k % 2)
91 ? (pqi->second) * (pqj->second) * pj_mag * legendre(ij_cos, k)
92 : pj_mag * legendre(ij_cos, k);
93 }
94 }
95 const double p_miss_mag(p_cms_missA.P());
96 const double i_miss_cos((pqi->first).Dot(p_cms_missA.Vect()) / pi_mag / p_miss_mag);
97 for (int k = 0; k < 5; k++) {
98 m_Hso[0][2][k] += (k % 2) ? 0 : p_miss_mag * legendre(i_miss_cos, k);
99 }
100 }
101
102 // Signal B (use_finalstate_for_sig == 1)
103 for (pqi = p3_cms_q_sigB.begin(); pqi != p3_cms_q_sigB.end(); ++pqi) {
104 const double pi_mag((pqi->first).R());
105 for (pqj = p3_cms_q_roe.begin(); pqj != p3_cms_q_roe.end(); ++pqj) {
106 const double pj_mag((pqj->first).R());
107 const double ij_cos((pqi->first).Dot(pqj->first) / pi_mag / pj_mag);
108 const int c_or_n(0 == (pqj->second) ? 1 : 0); // 0: charged 1: neutral
109 for (int k = 0; k < 5; k++) {
110 m_Hso[1][c_or_n][k] += (k % 2)
111 ? (pqi->second) * (pqj->second) * pj_mag * legendre(ij_cos, k)
112 : pj_mag * legendre(ij_cos, k);
113 }
114 }
115 const double p_miss_mag(p_cms_missB.P());
116 const double i_miss_cos((pqi->first).Dot(p_cms_missB.Vect()) / pi_mag / p_miss_mag);
117 for (int k = 0; k < 5; k++) {
118 m_Hso[1][2][k] += (k % 2) ? 0 : p_miss_mag * legendre(i_miss_cos, k);
119 }
120 }
121
122 // Add missing to the lists
123 std::vector<std::pair<ROOT::Math::XYZVector, int>> p3_cms_q_roeA(p3_cms_q_roe), p3_cms_q_roeB(p3_cms_q_roe);
124 p3_cms_q_roeA.emplace_back(p_cms_missA.Vect(), 0);
125 p3_cms_q_roeB.emplace_back(p_cms_missB.Vect(), 0);
126
127 // Calculate Hoo components
128 for (int k = 0; k < 5; k++) {
129 m_Hoo[0][k] = m_Hoo[1][k] = 0;
130 }
131 for (pqi = p3_cms_q_roeA.begin(); pqi != p3_cms_q_roeA.end(); ++pqi) {
132 const double pi_mag((pqi->first).R());
133 for (pqj = p3_cms_q_roeA.begin(); pqj != pqi; ++pqj) {
134 const double pj_mag((pqj->first).R());
135 const double ij_cos((pqi->first).Dot(pqj->first) / pi_mag / pj_mag);
136 for (int k = 0; k < 5; k++) {
137 m_Hoo[0][k] += (k % 2)
138 ? (pqi->second) * (pqj->second) * pi_mag * pj_mag * legendre(ij_cos, k)
139 : pi_mag * pj_mag * legendre(ij_cos, k);
140 }
141 }
142 }
143 for (pqi = p3_cms_q_roeB.begin(); pqi != p3_cms_q_roeB.end(); ++pqi) {
144 const double pi_mag((pqi->first).R());
145 for (pqj = p3_cms_q_roeB.begin(); pqj != pqi; ++pqj) {
146 const double pj_mag((pqj->first).R());
147 const double ij_cos((pqi->first).Dot(pqj->first) / pi_mag / pj_mag);
148 for (int k = 0; k < 5; k++) {
149 m_Hoo[1][k] += (k % 2)
150 ? (pqi->second) * (pqj->second) * pi_mag * pj_mag * legendre(ij_cos, k)
151 : pi_mag * pj_mag * legendre(ij_cos, k);
152 }
153 }
154 }
155
156 // Normalize so that it does not dependent on delta_e
157 for (int k = 0; k < 5; k++) {
158 for (int j = 0; j < ((k % 2) ? 1 : 3); j++) {
159 m_Hso[0][j][k] /= Hso0_max;
160 m_Hso[1][j][k] /= Hso0_max;
161 }
162 m_Hoo[0][k] /= (Hso0_max * Hso0_max);
163 m_Hoo[1][k] /= (Hso0_max * Hso0_max);
164 }
165
166 }
167
169} // Belle2 namespace
double et(int uf=-1) const
Returns calculated transverse energy.
Definition: KsfwMoments.h:93
double m_et[2]
Transverse energy.
Definition: KsfwMoments.h:127
int m_uf
Flag that specifiies we are using the final state for signal.
Definition: KsfwMoments.h:124
double m_Hso[2][3][5]
KSFW moments.
Definition: KsfwMoments.h:125
KsfwMoments()
Initialize KSFW moments, et, and mm2 to 0.
Definition: KsfwMoments.h:41
double m_mm2[2]
Missing mass squared.
Definition: KsfwMoments.h:128
double m_Hoo[2][5]
KSFW moments.
Definition: KsfwMoments.h:126
double legendre(const double z, const int i)
Legendre polynomials.
Definition: KsfwMoments.cc:33
Abstract base class for different kinds of events.
Definition: ClusterUtils.h:24