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ComputeClusterTime.cc
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2 
3 // functions to select the hits to compute the time of a given cluster
4 // start with the only hits with timing information
5 // average among the hits contained in the chosen time interval
6 
7 // N.B. time is corrected wrt vtx-calorimeter distance
8 // with straight line and light speed hypothesis
9 // for charged tracks or heavy particles (longer track length or beta < 1)
10 // need to correct the offset at analysis level
11 
12 using namespace hgcalsimclustertime;
13 
14 std::vector<size_t> decrease_sorted_indices(const std::vector<float>& v) {
15  // initialize original index locations
16  std::vector<size_t> idx(v.size());
17  std::iota(idx.begin(), idx.end(), 0);
18 
19  // sort indices based on comparing values in v (decreasing order)
20  std::sort(idx.begin(), idx.end(), [&v](size_t i1, size_t i2) { return v[i1] < v[i2]; });
21  return idx;
22 };
23 
24 ComputeClusterTime::ComputeClusterTime(float Xmin, float Xmax, float Cterm, float Aterm)
25  : xMin_(Xmin), xMax_(Xmax), cTerm_(Cterm), aTerm_(Aterm) {
26  if (xMin_ <= 0)
27  xMin_ = 0.1;
28 };
29 
30 ComputeClusterTime::ComputeClusterTime() : xMin_(1.), xMax_(5.), cTerm_(0), aTerm_(0){};
31 
32 void ComputeClusterTime::setParameters(float Xmin, float Xmax, float Cterm, float Aterm) {
33  xMin_ = (Xmin > 0) ? Xmin : 0.1;
34  xMax_ = Xmax;
35  cTerm_ = Cterm;
36  aTerm_ = Aterm;
37  return;
38 }
39 
40 //time resolution parametrization
42  float funcVal = pow(aTerm_ / x, 2) + pow(cTerm_, 2);
43  return sqrt(funcVal);
44 }
45 
47  if (type == "recHit") {
48  //xVal is S/N
49  //time is in ns units
50  //std::cout << type << ", " << xVal << ", " << xMax_ << ", " < xMin_ << ", " << timeResolution(xMin_) << ", " << timeResolution(xVal) << std::endl;
51 
52  if (xVal < xMin_)
53  return timeResolution(xMin_);
54  else if (xVal > xMax_)
55  return cTerm_;
56  else
57  return timeResolution(xVal);
58 
59  return -1;
60  }
61  return -1;
62 }
63 
64 //time-interval based on that ~210ps wide and with the highest number of hits
65 //extension valid in high PU of taking smallest interval with (order of)68% of hits
67  std::vector<float>& time, std::vector<float> weight, unsigned int minNhits, float deltaT, float timeWidthBy) {
68  if (time.size() < minNhits)
69  return std::pair<float, float>(-99., -1.);
70 
71  if (weight.empty())
72  weight.resize(time.size(), 1.);
73 
74  std::vector<float> t(time.size(), 0.);
75  std::vector<float> w(time.size(), 0.);
76  std::vector<size_t> sortedIndex = decrease_sorted_indices(time);
77  for (std::size_t i = 0; i < sortedIndex.size(); ++i) {
78  t[i] = time[sortedIndex[i]];
79  w[i] = weight[sortedIndex[i]];
80  }
81 
82  int max_elements = 0;
83  int start_el = 0;
84  int end_el = 0;
85  float timeW = 0.f;
86  float tolerance = 0.05f;
87 
88  for (auto start = t.begin(); start != t.end(); ++start) {
89  const auto startRef = *start;
90  int c = count_if(start, t.end(), [&](float el) { return el - startRef <= deltaT + tolerance; });
91  if (c > max_elements) {
92  max_elements = c;
93  auto last_el = find_if_not(start, t.end(), [&](float el) { return el - startRef <= deltaT + tolerance; });
94  auto valTostartDiff = *(--last_el) - startRef;
95  if (std::abs(deltaT - valTostartDiff) < tolerance) {
96  tolerance = std::abs(deltaT - valTostartDiff);
97  }
98  start_el = distance(t.begin(), start);
99  end_el = distance(t.begin(), last_el);
100  timeW = valTostartDiff;
101  }
102  }
103 
104  // further adjust time width around the chosen one based on the hits density
105  // proved to improve the resolution: get as many hits as possible provided they are close in time
106  float HalfTimeDiff = timeW * timeWidthBy;
107  float sum = 0.;
108  float num = 0;
109  int totSize = t.size();
110 
111  for (int ij = 0; ij <= start_el; ++ij) {
112  if (t[ij] > (t[start_el] - HalfTimeDiff)) {
113  for (int kl = ij; kl < totSize; ++kl) {
114  if (t[kl] < (t[end_el] + HalfTimeDiff)) {
115  sum += t[kl] * w[kl];
116  num += w[kl];
117  } else
118  break;
119  }
120  break;
121  }
122  }
123 
124  if (num == 0) {
125  return std::pair<float, float>(-99., -1.);
126  }
127  return std::pair<float, float>(sum / num, 1. / sqrt(num));
128 }
Definition: start.py:1
T w() const
const double tolerance
Definition: weight.py:1
std::pair< float, float > fixSizeHighestDensity(std::vector< float > &time, std::vector< float > weight=std::vector< float >(), unsigned int minNhits=3, float deltaT=0.210, float timeWidthBy=0.5)
T sqrt(T t)
Definition: SSEVec.h:23
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
float getTimeError(std::string type, float xVal)
void setParameters(float Xmix, float Xmax, float Cterm, float Aterm)
float x
std::vector< size_t > decrease_sorted_indices(const std::vector< float > &v)
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:29
uint32_t T const *__restrict__ uint32_t const *__restrict__ int32_t totSize