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source: git/external/fastjet/ClusterSequenceAreaBase.hh@ 215ee01

Last change on this file since 215ee01 was 35cdc46, checked in by Pavel Demin <demin@…>, 10 years ago

upgrade FastJet to version 3.1.0-beta.1, upgrade Nsubjettiness to version 2.1.0, add SoftKiller version 1.0.0

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File size: 13.3 KB
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[35cdc46]1//FJSTARTHEADER
2// $Id: ClusterSequenceAreaBase.hh 3433 2014-07-23 08:17:03Z salam $
[d7d2da3]3//
[35cdc46]4// Copyright (c) 2005-2014, Matteo Cacciari, Gavin P. Salam and Gregory Soyez
[d7d2da3]5//
6//----------------------------------------------------------------------
7// This file is part of FastJet.
8//
9// FastJet is free software; you can redistribute it and/or modify
10// it under the terms of the GNU General Public License as published by
11// the Free Software Foundation; either version 2 of the License, or
12// (at your option) any later version.
13//
14// The algorithms that underlie FastJet have required considerable
[35cdc46]15// development. They are described in the original FastJet paper,
16// hep-ph/0512210 and in the manual, arXiv:1111.6097. If you use
[d7d2da3]17// FastJet as part of work towards a scientific publication, please
[35cdc46]18// quote the version you use and include a citation to the manual and
19// optionally also to hep-ph/0512210.
[d7d2da3]20//
21// FastJet is distributed in the hope that it will be useful,
22// but WITHOUT ANY WARRANTY; without even the implied warranty of
23// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
24// GNU General Public License for more details.
25//
26// You should have received a copy of the GNU General Public License
27// along with FastJet. If not, see <http://www.gnu.org/licenses/>.
28//----------------------------------------------------------------------
[35cdc46]29//FJENDHEADER
[d7d2da3]30
31#ifndef __FASTJET_CLUSTERSEQUENCEAREABASE_HH__
32#define __FASTJET_CLUSTERSEQUENCEAREABASE_HH__
33
34#include "fastjet/ClusterSequence.hh"
35#include "fastjet/LimitedWarning.hh"
36#include "fastjet/Selector.hh"
37
38FASTJET_BEGIN_NAMESPACE
39
40/// @ingroup area_classes
41/// \class ClusterSequenceAreaBase
42/// base class that sets interface for extensions of ClusterSequence
43/// that provide information about the area of each jet
44///
45/// the virtual functions here all return 0, since no area determination
46/// is implemented.
47class ClusterSequenceAreaBase : public ClusterSequence {
48public:
49
50 /// a constructor which just carries out the construction of the
51 /// parent class
52 template<class L> ClusterSequenceAreaBase
53 (const std::vector<L> & pseudojets,
54 const JetDefinition & jet_def_in,
55 const bool & writeout_combinations = false) :
56 ClusterSequence(pseudojets, jet_def_in, writeout_combinations) {}
57
58
59 /// default constructor
60 ClusterSequenceAreaBase() {}
61
62
63 /// destructor
64 virtual ~ClusterSequenceAreaBase() {}
65
66
67 /// return the area associated with the given jet; this base class
68 /// returns 0.
69 virtual double area (const PseudoJet & ) const {return 0.0;}
70
71 /// return the error (uncertainty) associated with the determination
72 /// of the area of this jet; this base class returns 0.
73 virtual double area_error (const PseudoJet & ) const {return 0.0;}
74
75 /// return a PseudoJet whose 4-vector is defined by the following integral
76 ///
77 /// \int drap d\phi PseudoJet("rap,phi,pt=one") *
78 /// * Theta("rap,phi inside jet boundary")
79 ///
80 /// where PseudoJet("rap,phi,pt=one") is a 4-vector with the given
81 /// rapidity (rap), azimuth (phi) and pt=1, while Theta("rap,phi
82 /// inside jet boundary") is a function that is 1 when rap,phi
83 /// define a direction inside the jet boundary and 0 otherwise.
84 ///
85 /// This base class returns a null 4-vector.
86 virtual PseudoJet area_4vector(const PseudoJet & ) const {
87 return PseudoJet(0.0,0.0,0.0,0.0);}
88
89 /// true if a jet is made exclusively of ghosts
90 ///
91 /// NB: most area classes do not give any explicit ghost jets, but
92 /// some do, and they should replace this function with their own
93 /// version.
94 virtual bool is_pure_ghost(const PseudoJet & ) const {
95 return false;
96 }
97
98 /// returns true if ghosts are explicitly included within
99 /// jets for this ClusterSequence;
100 ///
101 /// Derived classes that do include explicit ghosts should provide
102 /// an alternative version of this routine and set it properly.
103 virtual bool has_explicit_ghosts() const {
104 return false;
105 }
106
107 /// return the total area, corresponding to the given Selector, that
108 /// is free of jets, in general based on the inclusive jets.
109 ///
110 /// The selector passed as an argument has to have a finite area and
111 /// apply jet-by-jet (see the BackgroundEstimator and Subtractor
112 /// tools for more generic usages)
113 virtual double empty_area(const Selector & selector) const;
114
115 /// return the total area, corresponding to the given Selector, that
116 /// is free of jets, based on the supplied all_jets
117 ///
118 /// The selector passed as an argument has to have a finite area and
119 /// apply jet-by-jet (see the BackgroundEstimator and Subtractor
120 /// tools for more generic usages)
121 double empty_area_from_jets(const std::vector<PseudoJet> & all_jets,
122 const Selector & selector) const;
123
124 /// return something similar to the number of pure ghost jets
125 /// in the given selector's range in an active area case.
126 /// For the local implementation we return empty_area/(0.55 pi R^2),
127 /// based on measured properties of ghost jets with kt and cam
128 /// (cf arXiv:0802.1188).
129 ///
130 /// Note that the number returned is a double.
131 ///
132 /// The selector passed as an argument has to have a finite area and
133 /// apply jet-by-jet (see the BackgroundEstimator and Subtractor
134 /// tools for more generic usages)
135 virtual double n_empty_jets(const Selector & selector) const {
136 double R = jet_def().R();
137 return empty_area(selector)/(0.55*pi*R*R);
138 }
139
140 /// the median of (pt/area) for jets contained within the selector
141 /// range, making use also of the info on n_empty_jets
142 ///
143 /// The selector passed as an argument has to have a finite area and
144 /// apply jet-by-jet (see the BackgroundEstimator and Subtractor
145 /// tools for more generic usages)
146 double median_pt_per_unit_area(const Selector & selector) const;
147
148 /// the median of (pt/area_4vector) for jets contained within the
149 /// selector range, making use also of the info on n_empty_jets
150 ///
151 /// The selector passed as an argument has to have a finite area and
152 /// apply jet-by-jet
153 double median_pt_per_unit_area_4vector(const Selector & selector) const;
154
155 /// the function that does the work for median_pt_per_unit_area and
156 /// median_pt_per_unit_area_4vector:
157 /// - something_is_area_4vect = false -> use plain area
158 /// - something_is_area_4vect = true -> use 4-vector area
159 double median_pt_per_unit_something(
160 const Selector & selector, bool use_area_4vector) const;
161
162 /// using jets withing the selector range (and with 4-vector areas if
163 /// use_area_4vector), calculate the median pt/area, as well as an
164 /// "error" (uncertainty), which is defined as the 1-sigma
165 /// half-width of the distribution of pt/A, obtained by looking for
166 /// the point below which we have (1-0.6827)/2 of the jets
167 /// (including empty jets).
168 ///
169 /// The subtraction for a jet with uncorrected pt pt^U and area A is
170 ///
171 /// pt^S = pt^U - median*A +- sigma*sqrt(A)
172 ///
173 /// where the error is only that associated with the fluctuations
174 /// in the noise and not that associated with the noise having
175 /// caused changes in the hard-particle content of the jet.
176 ///
177 /// The selector passed as an argument has to have a finite area and
178 /// apply jet-by-jet (see the BackgroundEstimator and Subtractor
179 /// tools for more generic usages)
180 ///
181 /// NB: subtraction may also be done with 4-vector area of course,
182 /// and this is recommended for jets with larger values of R, as
183 /// long as rho has also been determined with a 4-vector area;
184 /// using a scalar area causes one to neglect terms of relative
185 /// order $R^2/8$ in the jet $p_t$.
186 virtual void get_median_rho_and_sigma(const Selector & selector,
187 bool use_area_4vector,
188 double & median, double & sigma,
189 double & mean_area) const;
190
191 /// a more advanced version of get_median_rho_and_sigma, which allows
192 /// one to use any "view" of the event containing all jets (so that,
193 /// e.g. one might use Cam on a different resolution scale without
194 /// have to rerun the algorithm).
195 ///
196 /// By default it will assume that "all" are not inclusive jets,
197 /// so that in dealing with empty area it has to calculate
198 /// the number of empty jets based on the empty area and the
199 /// the observed <area> of jets rather than a surmised area
200 ///
201 /// Note that for small effective radii, this can cause problems
202 /// because the harder jets get an area >> <ghost-jet-area>
203 /// and so the estimate comes out all wrong. In these situations
204 /// it is highly advisable to use an area with explicit ghosts, since
205 /// then the "empty" jets are actually visible.
206 ///
207 /// The selector passed as an argument has to have a finite area and
208 /// apply jet-by-jet (see the BackgroundEstimator and Subtractor
209 /// tools for more generic usages)
210 virtual void get_median_rho_and_sigma(const std::vector<PseudoJet> & all_jets,
211 const Selector & selector,
212 bool use_area_4vector,
213 double & median, double & sigma,
214 double & mean_area,
215 bool all_are_inclusive = false) const;
216
217 /// same as the full version of get_median_rho_and_error, but without
218 /// access to the mean_area
219 ///
220 /// The selector passed as an argument has to have a finite area and
221 /// apply jet-by-jet (see the BackgroundEstimator and Subtractor
222 /// tools for more generic usages)
223 virtual void get_median_rho_and_sigma(const Selector & selector,
224 bool use_area_4vector,
225 double & median, double & sigma) const {
226 double mean_area;
227 get_median_rho_and_sigma(selector, use_area_4vector,
228 median, sigma, mean_area);
229 }
230
231
232 /// fits a form pt_per_unit_area(y) = a + b*y^2 in the selector range.
233 /// exclude_above allows one to exclude large values of pt/area from fit.
234 /// (if negative, the cut is discarded)
235 /// use_area_4vector = true uses the 4vector areas.
236 ///
237 /// The selector passed as an argument has to have a finite area and
238 /// apply jet-by-jet (see the BackgroundEstimator and Subtractor
239 /// tools for more generic usages)
240 virtual void parabolic_pt_per_unit_area(double & a, double & b,
241 const Selector & selector,
242 double exclude_above=-1.0,
243 bool use_area_4vector=false) const;
244
245 /// return a vector of all subtracted jets, using area_4vector, given rho.
246 /// Only inclusive_jets above ptmin are subtracted and returned.
247 /// the ordering is the same as that of sorted_by_pt(cs.inclusive_jets()),
248 /// i.e. not necessarily ordered in pt once subtracted
249 std::vector<PseudoJet> subtracted_jets(const double rho,
250 const double ptmin=0.0) const;
251
252 /// return a vector of subtracted jets, using area_4vector.
253 /// Only inclusive_jets above ptmin are subtracted and returned.
254 /// the ordering is the same as that of sorted_by_pt(cs.inclusive_jets()),
255 /// i.e. not necessarily ordered in pt once subtracted
256 ///
257 /// The selector passed as an argument has to have a finite area and
258 /// apply jet-by-jet (see the BackgroundEstimator and Subtractor
259 /// tools for more generic usages)
260 std::vector<PseudoJet> subtracted_jets(const Selector & selector,
261 const double ptmin=0.0) const;
262
263 /// return a subtracted jet, using area_4vector, given rho
264 PseudoJet subtracted_jet(const PseudoJet & jet,
265 const double rho) const;
266
267 /// return a subtracted jet, using area_4vector; note
268 /// that this is potentially inefficient if repeatedly used for many
269 /// different jets, because rho will be recalculated each time
270 /// around.
271 ///
272 /// The selector passed as an argument has to have a finite area and
273 /// apply jet-by-jet (see the BackgroundEstimator and Subtractor
274 /// tools for more generic usages)
275 PseudoJet subtracted_jet(const PseudoJet & jet,
276 const Selector & selector) const;
277
278 /// return the subtracted pt, given rho
279 double subtracted_pt(const PseudoJet & jet,
280 const double rho,
281 bool use_area_4vector=false) const;
282
283 /// return the subtracted pt; note that this is
284 /// potentially inefficient if repeatedly used for many different
285 /// jets, because rho will be recalculated each time around.
286 ///
287 /// The selector passed as an argument has to have a finite area and
288 /// apply jet-by-jet (see the BackgroundEstimator and Subtractor
289 /// tools for more generic usages)
290 double subtracted_pt(const PseudoJet & jet,
291 const Selector & selector,
292 bool use_area_4vector=false) const;
293
294protected:
295 /// check the selector is suited for the computations i.e. applies jet by jet and has a finite area
296 void _check_selector_good_for_median(const Selector &selector) const;
297
298
299private:
300 /// handle warning messages
301 static LimitedWarning _warnings;
302 static LimitedWarning _warnings_zero_area;
303 static LimitedWarning _warnings_empty_area;
304
305 /// check the jet algorithm is suitable (and if not issue a warning)
306 void _check_jet_alg_good_for_median() const;
307
308};
309
310
311
312FASTJET_END_NAMESPACE
313
314#endif // __FASTJET_CLUSTERSEQUENCEAREABASE_HH__
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