OpenMS  2.5.0
TwoDOptimization.h
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34 
35 #pragma once
36 
37 //#define DEBUG_2D
38 #undef DEBUG_2D
39 
40 #ifdef DEBUG_2D
41 #include <iostream>
42 #include <fstream>
43 #endif
44 
45 #include <vector>
46 #include <utility>
47 #include <cmath>
48 #include <set>
49 
60 
61 #include <Eigen/Core>
62 #include <unsupported/Eigen/NonLinearOptimization>
63 
64 #ifndef OPENMS_SYSTEM_STOPWATCH_H
65 #endif
66 
67 #include <boost/math/special_functions/acosh.hpp>
70 
71 namespace OpenMS
72 {
73 
88  class OPENMS_DLLAPI TwoDOptimization :
89  public DefaultParamHandler
90  {
91 public:
92 
95 
98 
100  ~TwoDOptimization() override{}
101 
103  TwoDOptimization& operator=(const TwoDOptimization& opt);
104 
105 
107  inline double getMZTolerance() const {return tolerance_mz_; }
109  inline void setMZTolerance(double tolerance_mz)
110  {
111  tolerance_mz_ = tolerance_mz;
112  param_.setValue("2d:tolerance_mz", tolerance_mz);
113  }
114 
116  inline double getMaxPeakDistance() const {return max_peak_distance_; }
118  inline void setMaxPeakDistance(double max_peak_distance)
119  {
120  max_peak_distance_ = max_peak_distance;
121  param_.setValue("2d:max_peak_distance", max_peak_distance);
122  }
123 
125  inline UInt getMaxIterations() const {return max_iteration_; }
127  inline void setMaxIterations(UInt max_iteration)
128  {
129  max_iteration_ = max_iteration;
130  param_.setValue("iterations", max_iteration);
131  }
132 
134  inline const OptimizationFunctions::PenaltyFactorsIntensity& getPenalties() const {return penalties_; }
137  {
138  penalties_ = penalties;
139  param_.setValue("penalties:position", penalties.pos);
140  param_.setValue("penalties:height", penalties.height);
141  param_.setValue("penalties:left_width", penalties.lWidth);
142  param_.setValue("penalties:right_width", penalties.rWidth);
143  }
144 
161  template <typename InputSpectrumIterator>
162  void optimize(InputSpectrumIterator first,
163  InputSpectrumIterator last,
164  PeakMap& ms_exp, bool real2D = true);
165 
166 
167 protected:
169  struct Data
170  {
171  std::vector<std::pair<SignedSize, SignedSize> > signal2D;
172  std::multimap<double, IsotopeCluster>::iterator iso_map_iter;
174  std::map<Int, std::vector<PeakIndex> > matching_peaks;
178  std::vector<double> positions;
179  std::vector<double> signal;
180  };
181 
182  class OPENMS_DLLAPI TwoDOptFunctor
183  {
184  public:
185  int inputs() const { return m_inputs; }
186  int values() const { return m_values; }
187 
188  TwoDOptFunctor(unsigned dimensions, unsigned num_data_points, const TwoDOptimization::Data* data)
189  : m_inputs(dimensions), m_values(num_data_points), m_data(data) {}
190 
191  int operator()(const Eigen::VectorXd &x, Eigen::VectorXd &fvec);
192  // compute Jacobian matrix for the different parameters
193  int df(const Eigen::VectorXd &x, Eigen::MatrixXd &J);
194 
195  private:
196  const int m_inputs, m_values;
198  };
199 
200 
202  std::multimap<double, IsotopeCluster> iso_map_;
203 
205  std::multimap<double, IsotopeCluster>::const_iterator curr_region_;
206 
209 
212 
214  // std::map<Int, std::vector<PeakMap::SpectrumType::Iterator > > matching_peaks_;
215  std::map<Int, std::vector<PeakIndex> > matching_peaks_;
216 
217 
220 
222  bool real_2D_;
223 
224 
227 
228 
233  std::vector<double>::iterator searchInScan_(std::vector<double>::iterator scan_begin,
234  std::vector<double>::iterator scan_end,
235  double current_mz);
236 
238  template <typename InputSpectrumIterator>
239  void optimizeRegions_(InputSpectrumIterator& first,
240  InputSpectrumIterator& last,
241  PeakMap& ms_exp);
242 
244  template <typename InputSpectrumIterator>
245  void optimizeRegionsScanwise_(InputSpectrumIterator& first,
246  InputSpectrumIterator& last,
247  PeakMap& ms_exp);
248 
249 
251  template <typename InputSpectrumIterator>
252  void getRegionEndpoints_(PeakMap& exp,
253  InputSpectrumIterator& first,
254  InputSpectrumIterator& last,
255  Size iso_map_idx,
256  double noise_level,
258 
260  void findMatchingPeaks_(std::multimap<double, IsotopeCluster>::iterator& it,
261  PeakMap& ms_exp);
262 
264 
266  void updateMembers_() override;
267  };
268 
269 
270  template <typename InputSpectrumIterator>
271  void TwoDOptimization::optimize(InputSpectrumIterator first, InputSpectrumIterator last, PeakMap& ms_exp, bool real2D)
272  {
273  //#define DEBUG_2D
274  //check if the input maps have the same number of spectra
275  if ((UInt)distance(first, last) != ms_exp.size())
276  {
277  throw Exception::IllegalArgument(__FILE__, __LINE__, OPENMS_PRETTY_FUNCTION, "Error in Two2Optimization: Raw and peak map do not have the same number of spectra");
278  }
279  //do nothing if there are no scans
280  if (ms_exp.empty())
281  {
282  return;
283  }
284  //check if required meta data arrays are present (for each scan)
285  for (Size i = 0; i < ms_exp.size(); ++i)
286  {
287  //check if enough meta data arrays are present
288  if (ms_exp[i].getFloatDataArrays().size() < 6)
289  {
290  throw Exception::IllegalArgument(__FILE__, __LINE__, OPENMS_PRETTY_FUNCTION, "Error in Two2Optimization: Not enough meta data arrays present (1:area, 5:shape, 3:left width, 4:right width)");
291  }
292  bool area = ms_exp[i].getFloatDataArrays()[1].getName() == "maximumIntensity";
293  bool wleft = ms_exp[i].getFloatDataArrays()[3].getName() == "leftWidth";
294  bool wright = ms_exp[i].getFloatDataArrays()[4].getName() == "rightWidth";
295  bool shape = ms_exp[i].getFloatDataArrays()[5].getName() == "peakShape";
296 
297  if (!area || !wleft || !wright || !shape)
298  {
299  throw Exception::IllegalArgument(__FILE__, __LINE__, OPENMS_PRETTY_FUNCTION, "Error in Two2Optimization: One or several meta data arrays missing (1:intensity, 5:shape, 3:left width, 4:right width)");
300  }
301  }
302  real_2D_ = real2D;
303  typedef MSSpectrum SpectrumType;
304 
305  typename PeakMap::Iterator ms_exp_it = ms_exp.begin();
306  typename PeakMap::Iterator ms_exp_it_end = ms_exp.end();
307  if (ms_exp.empty())
308  {
309  return;
310  }
311  // stores the monoisotopic peaks of isotopic clusters
312  std::vector<double> iso_last_scan;
313  std::vector<double> iso_curr_scan;
314  std::vector<std::multimap<double, IsotopeCluster>::iterator> clusters_last_scan;
315  std::vector<std::multimap<double, IsotopeCluster>::iterator> clusters_curr_scan;
316  std::multimap<double, IsotopeCluster>::iterator cluster_iter;
317  double current_rt = ms_exp_it->getRT(), last_rt = 0;
318 
319  // retrieve values for accepted peaks distances
320  max_peak_distance_ = param_.getValue("2d:max_peak_distance");
321  double tolerance_mz = param_.getValue("2d:tolerance_mz");
322 
323  UInt current_charge = 0; // charge state of the current isotopic cluster
324  double mz_in_hash = 0; // used as reference to the current isotopic peak
325 
326  // sweep through scans
327  for (UInt curr_scan = 0; ms_exp_it + curr_scan != ms_exp_it_end; ++curr_scan)
328  {
329  Size nr_peaks_in_scan = (ms_exp_it + curr_scan)->size();
330  if (nr_peaks_in_scan == 0)
331  continue;
332 
333  //last_rt = current_rt;
334  current_rt = (ms_exp_it + curr_scan)->getRT();
335  typename PeakMap::SpectrumType::Iterator peak_it = (ms_exp_it + curr_scan)->begin();
336 
337  // copy cluster information of least scan
338  iso_last_scan = iso_curr_scan;
339  iso_curr_scan.clear();
340  clusters_last_scan = clusters_curr_scan;
341  clusters_curr_scan.clear();
342 
343 #ifdef DEBUG_2D
344  std::cout << "Next scan with rt: " << current_rt << std::endl;
345  std::cout << "Next scan, rt = " << current_rt << " last_rt: " << last_rt << std::endl;
346  std::cout << "---------------------------------------------------------------------------" << std::endl;
347 #endif
348  MSSpectrum s;
349  s.setRT(current_rt);
350  // check if there were scans in between
351  if (last_rt == 0 || // are we in the first scan
352  ((lower_bound(first, last, s, typename SpectrumType::RTLess()) - 1)->getRT() == last_rt))
353  {
354 
355 
356  for (UInt curr_peak = 0; curr_peak < (ms_exp_it + curr_scan)->size() - 1; ++curr_peak)
357  {
358 
359  // store the m/z of the current peak
360  double curr_mz = (peak_it + curr_peak)->getMZ();
361  double dist2nextpeak = (peak_it + curr_peak + 1)->getMZ() - curr_mz;
362 
363  if (dist2nextpeak <= max_peak_distance_) // one single peak without neighbors isn't optimized
364  {
365 #ifdef DEBUG_2D
366  std::cout << "Isotopic pattern found ! " << std::endl;
367  std::cout << "We are at: " << (peak_it + curr_peak)->getMZ() << " " << curr_mz << std::endl;
368 #endif
369  if (!iso_last_scan.empty()) // Did we find any isotopic cluster in the last scan?
370  {
371  std::sort(iso_last_scan.begin(), iso_last_scan.end());
372  // there were some isotopic clusters in the last scan...
373  std::vector<double>::iterator it =
374  searchInScan_(iso_last_scan.begin(), iso_last_scan.end(), curr_mz);
375 
376  double delta_mz = fabs(*it - curr_mz);
377  //std::cout << delta_mz << " "<< tolerance_mz << std::endl;
378  if (delta_mz > tolerance_mz) // check if first peak of last cluster is close enough
379  {
380  mz_in_hash = curr_mz; // update current hash key
381 
382  // create new isotopic cluster
383 // #ifdef DEBUG_2D
384 // std::cout << "Last peak cluster too far, creating new cluster at "<<curr_mz << std::endl;
385 // #endif
386  IsotopeCluster new_cluster;
387  new_cluster.peaks.charge = current_charge;
388  new_cluster.scans.push_back(curr_scan);
389  cluster_iter = iso_map_.insert(std::pair<double, IsotopeCluster>(mz_in_hash, new_cluster));
390 
391  }
392  else
393  {
394 // //#ifdef DEBUG_2D
395 // std::cout << "Found neighbouring peak with distance (m/z) " << delta_mz << std::endl;
396 // //#endif
397  cluster_iter = clusters_last_scan[distance(iso_last_scan.begin(), it)];
398 
399  // check whether this scan is already contained
400  if (find(cluster_iter->second.scans.begin(), cluster_iter->second.scans.end(), curr_scan)
401  == cluster_iter->second.scans.end())
402  {
403  cluster_iter->second.scans.push_back(curr_scan);
404  }
405 
406 // //#ifdef DEBUG_2D
407 // std::cout << "Cluster with " << cluster_iter->second.peaks.size()
408 // << " peaks retrieved." << std::endl;
409 // //#endif
410  }
411 
412  }
413  else // last scan did not contain any isotopic cluster
414  {
415 // //#ifdef DEBUG_2D
416 // std::cout << "Last scan was empty => creating new cluster." << std::endl;
417 // std::cout << "Creating new cluster at m/z: " << curr_mz << std::endl;
418 // //#endif
419 
420  mz_in_hash = curr_mz; // update current hash key
421 
422  // create new isotopic cluster
423  IsotopeCluster new_cluster;
424  new_cluster.peaks.charge = current_charge;
425  new_cluster.scans.push_back(curr_scan);
426  cluster_iter = iso_map_.insert(std::pair<double, IsotopeCluster>(mz_in_hash, new_cluster));
427 
428  }
429 
430 // //#ifdef DEBUG_2D
431 // std::cout << "Storing found peak in current isotopic cluster" << std::endl;
432 // //#endif
433 
434 
435 
436  cluster_iter->second.peaks.insert(std::pair<UInt, UInt>(curr_scan, curr_peak));
437 
438  iso_curr_scan.push_back(mz_in_hash);
439  clusters_curr_scan.push_back(cluster_iter);
440  ++curr_peak;
441 
442  cluster_iter->second.peaks.insert(std::pair<UInt, UInt>(curr_scan, curr_peak));
443  iso_curr_scan.push_back((peak_it + curr_peak)->getMZ());
444  clusters_curr_scan.push_back(cluster_iter);
445 
446  // check distance to next peak
447  if ((curr_peak + 1) >= nr_peaks_in_scan)
448  break;
449  dist2nextpeak = (peak_it + curr_peak + 1)->getMZ() - (peak_it + curr_peak)->getMZ();
450 
451 
452  // loop until end of isotopic pattern in this scan
453  while (dist2nextpeak <= max_peak_distance_
454  && curr_peak < (nr_peaks_in_scan - 1))
455  {
456  cluster_iter->second.peaks.insert(std::pair<UInt, UInt>(curr_scan, curr_peak + 1)); // save peak in cluster
457  iso_curr_scan.push_back((peak_it + curr_peak + 1)->getMZ());
458  clusters_curr_scan.push_back(cluster_iter);
459  // std::cout << "new entered: "<<(peak_it+curr_peak+1)->getMZ()<<" im while"<<std::endl;
460  ++curr_peak;
461  if (curr_peak >= nr_peaks_in_scan - 1)
462  break;
463  dist2nextpeak = (peak_it + curr_peak + 1)->getMZ() - (peak_it + curr_peak)->getMZ(); // get distance to next peak
464 
465 
466  } // end while(...)
467 
468 
469 
470  } // end of if (dist2nextpeak <= max_peak_distance_)
471  else
472  {
473  if (!iso_last_scan.empty()) // Did we find any isotopic cluster in the last scan?
474  {
475  std::sort(iso_last_scan.begin(), iso_last_scan.end());
476  // there were some isotopic clusters in the last scan...
477  std::vector<double>::iterator it =
478  searchInScan_(iso_last_scan.begin(), iso_last_scan.end(), curr_mz);
479 
480  double delta_mz = fabs(*it - curr_mz);
481  // std::cout << delta_mz << " "<< tolerance_mz << std::endl;
482  if (delta_mz > tolerance_mz) // check if first peak of last cluster is close enough
483  {
484  mz_in_hash = curr_mz; // update current hash key
485 
486  // create new isotopic cluster
487 // //#ifdef DEBUG_2D
488 // std::cout << "Last peak cluster too far, creating new cluster at "<<curr_mz << std::endl;
489 // //#endif
490  IsotopeCluster new_cluster;
491  new_cluster.peaks.charge = current_charge;
492  new_cluster.scans.push_back(curr_scan);
493  cluster_iter = iso_map_.insert(std::pair<double, IsotopeCluster>(mz_in_hash, new_cluster));
494 
495  }
496  else
497  {
498 // //#ifdef DEBUG_2D
499 // std::cout << "Found neighbouring peak with distance (m/z) " << delta_mz << std::endl;
500 // //#endif
501  cluster_iter = clusters_last_scan[distance(iso_last_scan.begin(), it)];
502 
503  // check whether this scan is already contained
504  if (find(cluster_iter->second.scans.begin(), cluster_iter->second.scans.end(), curr_scan)
505  == cluster_iter->second.scans.end())
506  {
507  cluster_iter->second.scans.push_back(curr_scan);
508  }
509 
510 // //#ifdef DEBUG_2D
511 // std::cout << "Cluster with " << cluster_iter->second.peaks.size()
512 // << " peaks retrieved." << std::endl;
513 // //#endif
514  }
515 
516  }
517  else // last scan did not contain any isotopic cluster
518  {
519 // //#ifdef DEBUG_2D
520 // std::cout << "Last scan was empty => creating new cluster." << std::endl;
521 // std::cout << "Creating new cluster at m/z: " << curr_mz << std::endl;
522 // //#endif
523 
524  mz_in_hash = curr_mz; // update current hash key
525 
526  // create new isotopic cluster
527  IsotopeCluster new_cluster;
528  new_cluster.peaks.charge = current_charge;
529  new_cluster.scans.push_back(curr_scan);
530  cluster_iter = iso_map_.insert(std::pair<double, IsotopeCluster>(mz_in_hash, new_cluster));
531 
532  }
533 
534 // //#ifdef DEBUG_2D
535 // std::cout << "Storing found peak in current isotopic cluster" << std::endl;
536 // //#endif
537 
538 
539 
540  cluster_iter->second.peaks.insert(std::pair<UInt, UInt>(curr_scan, curr_peak));
541 
542  iso_curr_scan.push_back(mz_in_hash);
543  clusters_curr_scan.push_back(cluster_iter);
544 
545 
546  }
547 
548  current_charge = 0; // reset charge
549  } // end for (...)
550  }
551  last_rt = current_rt;
552  }
553  curr_region_ = iso_map_.begin();
554 #ifdef DEBUG_2D
555  std::cout << iso_map_.size() << " isotopic clusters were found ! " << std::endl;
556 #endif
557 
558  if (real_2D_)
559  optimizeRegions_(first, last, ms_exp);
560  else
561  optimizeRegionsScanwise_(first, last, ms_exp);
562  //#undef DEBUG_2D
563  }
564 
565 
566 
567  template <typename InputSpectrumIterator>
568  void TwoDOptimization::optimizeRegions_(InputSpectrumIterator& first,
569  InputSpectrumIterator& last,
570  PeakMap& ms_exp)
571  {
572  Int counter = 0;
573  // go through the clusters
574  for (std::multimap<double, IsotopeCluster>::iterator it = iso_map_.begin();
575  it != iso_map_.end();
576  ++it)
577  {
578 #ifdef DEBUG_2D
579  std::cout << "element: " << counter << std::endl;
580  std::cout << "mz: " << it->first << std::endl << "rts: ";
581 // for(Size i=0;i<it->second.scans.size();++i) std::cout << it->second.scans[i] << "\n";
582  std::cout << std::endl << "peaks: ";
583  IsotopeCluster::IndexSet::const_iterator iter = it->second.peaks.begin();
584  for (; iter != it->second.peaks.end(); ++iter)
585  std::cout << ms_exp[iter->first].getRT() << " " << (ms_exp[iter->first][iter->second]).getMZ() << std::endl;
586 
587 //for(Size i=0;i<it->second.peaks.size();++i) std::cout << ms_exp[it->first].getRT() << " "<<(ms_exp[it->first][it->second]).getMZ()<<std::endl;
588  std::cout << std::endl << std::endl;
589 
590 #endif
591 
592  // prepare for optimization:
593  // determine the matching peaks
594  matching_peaks_.clear();
595  findMatchingPeaks_(it, ms_exp);
596  TwoDOptimization::Data twoD_data;
597  twoD_data.penalties = penalties_;
598  twoD_data.matching_peaks = matching_peaks_;
599  // and the endpoints of each isotope pattern in the cluster
600  getRegionEndpoints_(ms_exp, first, last, counter, 400, twoD_data);
601 
602  // peaks have to be stored globally
603  twoD_data.iso_map_iter = it;
604 
605  twoD_data.picked_peaks = ms_exp;
606  twoD_data.raw_data_first = first;
607 
608  Size nr_diff_peaks = matching_peaks_.size();
609  twoD_data.total_nr_peaks = it->second.peaks.size();
610 
611  Size nr_parameters = nr_diff_peaks * 3 + twoD_data.total_nr_peaks;
612 
613  // initialize and set parameters for optimization
614  Eigen::VectorXd x_init (nr_parameters);
615  x_init.setZero();
616 
617  std::map<Int, std::vector<PeakIndex> >::iterator m_peaks_it = twoD_data.matching_peaks.begin();
618  Int peak_counter = 0;
619  Int diff_peak_counter = 0;
620  // go through the matching peaks
621  for (; m_peaks_it != twoD_data.matching_peaks.end(); ++m_peaks_it)
622  {
623  double av_mz = 0, av_lw = 0, av_rw = 0, avr_height = 0, height;
624  std::vector<PeakIndex>::iterator iter_iter = (m_peaks_it)->second.begin();
625  for (; iter_iter != m_peaks_it->second.end(); ++iter_iter)
626  {
627  height = ms_exp[(iter_iter)->spectrum].getFloatDataArrays()[1][(iter_iter)->peak]; //(iter_iter)->getPeak(ms_exp).getIntensity();
628  avr_height += height;
629  av_mz += (iter_iter)->getPeak(ms_exp).getMZ() * height;
630  av_lw += ms_exp[(iter_iter)->spectrum].getFloatDataArrays()[3][(iter_iter)->peak] * height; //left width
631  av_rw += ms_exp[(iter_iter)->spectrum].getFloatDataArrays()[4][(iter_iter)->peak] * height; //right width
632  x_init(peak_counter) = height;
633  ++peak_counter;
634  }
635  x_init(twoD_data.total_nr_peaks + 3 * diff_peak_counter) = av_mz / avr_height;
636  x_init(twoD_data.total_nr_peaks + 3 * diff_peak_counter + 1) = av_lw / avr_height;
637  x_init(twoD_data.total_nr_peaks + 3 * diff_peak_counter + 2) = av_rw / avr_height;
638  ++diff_peak_counter;
639  }
640 
641 #ifdef DEBUG_2D
642  std::cout << "----------------------------\n\nstart_value: " << std::endl;
643  for (Size k = 0; k < start_value->size; ++k)
644  {
645  std::cout << x_init(k) << std::endl;
646  }
647 #endif
648  Int num_positions = 0;
649  for (Size i = 0; i < twoD_data.signal2D.size(); i += 2)
650  {
651  num_positions += (twoD_data.signal2D[i + 1].second - twoD_data.signal2D[i].second + 1);
652 #ifdef DEBUG_2D
653  std::cout << twoD_data.signal2D[i + 1].second << " - " << twoD_data.signal2D[i].second << " +1 " << std::endl;
654 #endif
655 
656  }
657 #ifdef DEBUG_2D
658  std::cout << "num_positions : " << num_positions << std::endl;
659 #endif
660 
661  TwoDOptFunctor functor (nr_parameters, std::max(num_positions + 1, (Int)(nr_parameters)), &twoD_data);
662  Eigen::LevenbergMarquardt<TwoDOptFunctor> lmSolver (functor);
663  Eigen::LevenbergMarquardtSpace::Status status = lmSolver.minimize(x_init);
664 
665  //the states are poorly documented. after checking the source, we believe that
666  //all states except NotStarted, Running and ImproperInputParameters are good
667  //termination states.
668  if (status <= Eigen::LevenbergMarquardtSpace::ImproperInputParameters)
669  {
670  throw Exception::UnableToFit(__FILE__, __LINE__, OPENMS_PRETTY_FUNCTION, "UnableToFit-TwoDOptimization:", "Could not fit the data: Error " + String(status));
671  }
672 
673  Int peak_idx = 0;
674  std::map<Int, std::vector<PeakIndex> >::iterator itv
675  = twoD_data.matching_peaks.begin();
676  for (; itv != twoD_data.matching_peaks.end(); ++itv)
677  {
678  Int i = distance(twoD_data.matching_peaks.begin(), itv);
679  for (Size j = 0; j < itv->second.size(); ++j)
680  {
681 
682 #ifdef DEBUG_2D
683  std::cout << "pos: " << itv->second[j].getPeak(ms_exp).getMZ() << "\nint: " << itv->second[j].getSpectrum(ms_exp).getFloatDataArrays()[1][itv->second[j].peak] //itv->second[j].getPeak(ms_exp).getIntensity()
684  << "\nlw: " << itv->second[j].getSpectrum(ms_exp).getFloatDataArrays()[3][itv->second[j].peak]
685  << "\nrw: " << itv->second[j].getSpectrum(ms_exp).getFloatDataArrays()[4][itv->second[j].peak] << "\n";
686 
687 #endif
688  double mz = x_init(twoD_data.total_nr_peaks + 3 * i);
689  ms_exp[itv->second[j].spectrum][itv->second[j].peak].setMZ(mz);
690  double height = x_init(peak_idx);
691  ms_exp[itv->second[j].spectrum].getFloatDataArrays()[1][itv->second[j].peak] = height;
692  double left_width = x_init(twoD_data.total_nr_peaks + 3 * i + 1);
693  ms_exp[itv->second[j].spectrum].getFloatDataArrays()[3][itv->second[j].peak] = left_width;
694  double right_width = x_init(twoD_data.total_nr_peaks + 3 * i + 2);
695 
696  ms_exp[itv->second[j].spectrum].getFloatDataArrays()[4][itv->second[j].peak] = right_width;
697  // calculate area
698  if ((PeakShape::Type)(Int)ms_exp[itv->second[j].spectrum].getFloatDataArrays()[5][itv->second[j].peak] == PeakShape::LORENTZ_PEAK)
699  {
700  double x_left_endpoint = mz - 1 / left_width* sqrt(height / 1 - 1);
701  double x_right_endpoint = mz + 1 / right_width* sqrt(height / 1 - 1);
702  double area_left = -height / left_width* atan(left_width * (x_left_endpoint - mz));
703  double area_right = -height / right_width* atan(right_width * (mz - x_right_endpoint));
704  ms_exp[itv->second[j].spectrum][itv->second[j].peak].setIntensity(area_left + area_right);
705  }
706  else // it's a sech peak
707  {
708  double x_left_endpoint = mz - 1 / left_width* boost::math::acosh(sqrt(height / 0.001));
709  double x_right_endpoint = mz + 1 / right_width* boost::math::acosh(sqrt(height / 0.001));
710  double area_left = -height / left_width * (sinh(left_width * (mz - x_left_endpoint)) / cosh(left_width * (mz - x_left_endpoint)));
711  double area_right = -height / right_width * (sinh(right_width * (mz - x_right_endpoint)) / cosh(right_width * (mz - x_right_endpoint)));
712  ms_exp[itv->second[j].spectrum][itv->second[j].peak].setIntensity(area_left + area_right);
713  }
714 
715 
716 #ifdef DEBUG_2D
717  std::cout << "pos: " << itv->second[j].getPeak(ms_exp).getMZ() << "\nint: " << itv->second[j].getSpectrum(ms_exp).getFloatDataArrays()[1][itv->second[j].peak] //itv->second[j].getPeak(ms_exp).getIntensity()
718  << "\nlw: " << itv->second[j].getSpectrum(ms_exp).getFloatDataArrays()[3][itv->second[j].peak]
719  << "\nrw: " << itv->second[j].getSpectrum(ms_exp).getFloatDataArrays()[4][itv->second[j].peak] << "\n";
720 #endif
721 
722  ++peak_idx;
723 
724 
725  }
726  }
727 
728  ++counter;
729  } // end for
730  //#undef DEBUG_2D
731  }
732 
733  template <typename InputSpectrumIterator>
734  void TwoDOptimization::optimizeRegionsScanwise_(InputSpectrumIterator& first,
735  InputSpectrumIterator& last,
736  PeakMap& ms_exp)
737  {
738  Int counter = 0;
740  d.picked_peaks = ms_exp;
741  d.raw_data_first = first;
742 
743  //std::cout << "richtig hier" << std::endl;
745 
746 
747  DataValue dv = param_.getValue("penalties:position");
748  if (dv.isEmpty() || dv.toString() == "")
749  penalties.pos = 0.;
750  else
751  penalties.pos = (float)dv;
752 
753  dv = param_.getValue("penalties:left_width");
754  if (dv.isEmpty() || dv.toString() == "")
755  penalties.lWidth = 1.;
756  else
757  penalties.lWidth = (float)dv;
758 
759  dv = param_.getValue("penalties:right_width");
760  if (dv.isEmpty() || dv.toString() == "")
761  penalties.rWidth = 1.;
762  else
763  penalties.rWidth = (float)dv;
764 #ifdef DEBUG_2D
765  std::cout << penalties.pos << " "
766  << penalties.rWidth << " "
767  << penalties.lWidth << std::endl;
768 #endif
769 // PeakMap::const_iterator help = first;
770 // // std::cout << "\n\n\n\n---------------------------------------------------------------";
771 // while(help!=last)
772 // {
773 // // std::cout<<help->getRT()<<std::endl;
774 // ++help;
775 // }
776  // std::cout << "---------------------------------------------------------------\n\n\n\n";
777 
778  UInt max_iteration;
779  dv = param_.getValue("iterations");
780  if (dv.isEmpty() || dv.toString() == "")
781  max_iteration = 15;
782  else
783  max_iteration = (UInt)dv;
784 
785  std::vector<PeakShape> peak_shapes;
786 
787 
788  // go through the clusters
789  for (std::multimap<double, IsotopeCluster>::iterator it = iso_map_.begin();
790  it != iso_map_.end();
791  ++it)
792  {
793  d.iso_map_iter = it;
794 #ifdef DEBUG_2D
795  std::cerr << "element: " << counter << std::endl;
796  std::cerr << "mz: " << it->first << std::endl << "rts: ";
797  for (Size i = 0; i < it->second.scans.size(); ++i)
798  std::cerr << it->second.scans[i] << "\n";
799  std::cerr << std::endl << "peaks: ";
800  IsotopeCluster::IndexSet::const_iterator iter = it->second.peaks.begin();
801  for (; iter != it->second.peaks.end(); ++iter)
802  std::cerr << ms_exp[iter->first].getRT() << " " << (ms_exp[iter->first][iter->second]).getMZ() << std::endl;
803  //for(Size i=0;i<it->second.peaks_.size();++i) std::cout << ms_exp[it->first].getRT() << " "<<(ms_exp[it->first][it->second]).getMZ()<<std::endl;
804  std::cerr << std::endl << std::endl;
805 
806 #endif
807  // prepare for optimization:
808  // determine the matching peaks
809  // and the endpoints of each isotope pattern in the cluster
810 
811  getRegionEndpoints_(ms_exp, first, last, counter, 400, d);
812  OptimizePick::Data data;
813 
814 
815  Size idx = 0;
816  for (Size i = 0; i < d.signal2D.size() / 2; ++i)
817  {
818  data.positions.clear();
819  data.signal.clear();
820 
822  (d.raw_data_first + d.signal2D[2 * i].first)->begin() + d.signal2D[2 * i].second;
823  Int size = distance(ms_it, (d.raw_data_first + d.signal2D[2 * i].first)->begin() + d.signal2D[2 * i + 1].second);
824  data.positions.reserve(size);
825  data.signal.reserve(size);
826 
827  while (ms_it != (d.raw_data_first + d.signal2D[2 * i].first)->begin() + d.signal2D[2 * i + 1].second)
828  {
829  data.positions.push_back(ms_it->getMZ());
830  data.signal.push_back(ms_it->getIntensity());
831  ++ms_it;
832  }
833 
834 
836  pair.first = d.iso_map_iter->second.peaks.begin()->first + idx;
837 
838  IsotopeCluster::IndexSet::const_iterator set_iter = lower_bound(d.iso_map_iter->second.peaks.begin(),
839  d.iso_map_iter->second.peaks.end(),
841 
842 
843  // find the last entry with this rt-value
844  ++pair.first;
845  IsotopeCluster::IndexSet::const_iterator set_iter2 = lower_bound(d.iso_map_iter->second.peaks.begin(),
846  d.iso_map_iter->second.peaks.end(),
848 
849  while (set_iter != set_iter2)
850  {
851  const Size peak_index = set_iter->second;
852  const MSSpectrum& spec = ms_exp[set_iter->first];
853  PeakShape shape(spec.getFloatDataArrays()[1][peak_index], //intensity
854  spec[peak_index].getMZ(),
855  spec.getFloatDataArrays()[3][peak_index], //left width
856  spec.getFloatDataArrays()[4][peak_index], //right width
857  spec[peak_index].getIntensity(), //area is stored in peak intensity
858  PeakShape::Type(Int(spec.getFloatDataArrays()[5][peak_index]))); //shape
859  peak_shapes.push_back(shape);
860  ++set_iter;
861  }
862 #ifdef DEBUG_2D
863  std::cout << "rt "
864  << (d.raw_data_first + d.signal2D[2 * i].first)->getRT()
865  << "\n";
866 #endif
867  OptimizePick opt(penalties, max_iteration);
868 #ifdef DEBUG_2D
869  std::cout << "vorher\n";
870 
871  for (Size p = 0; p < peak_shapes.size(); ++p)
872  {
873  std::cout << peak_shapes[p].mz_position << "\t" << peak_shapes[p].height
874  << "\t" << peak_shapes[p].left_width << "\t" << peak_shapes[p].right_width << std::endl;
875  }
876 #endif
877  opt.optimize(peak_shapes, data);
878 #ifdef DEBUG_2D
879  std::cout << "nachher\n";
880  for (Size p = 0; p < peak_shapes.size(); ++p)
881  {
882  std::cout << peak_shapes[p].mz_position << "\t" << peak_shapes[p].height
883  << "\t" << peak_shapes[p].left_width << "\t" << peak_shapes[p].right_width << std::endl;
884  }
885 #endif
886  std::sort(peak_shapes.begin(), peak_shapes.end(), PeakShape::PositionLess());
887  pair.first = d.iso_map_iter->second.peaks.begin()->first + idx;
888 
889  set_iter = lower_bound(d.iso_map_iter->second.peaks.begin(),
890  d.iso_map_iter->second.peaks.end(),
892  Size p = 0;
893  while (p < peak_shapes.size())
894  {
895  MSSpectrum& spec = ms_exp[set_iter->first];
896  spec[set_iter->second].setMZ(peak_shapes[p].mz_position);
897  spec.getFloatDataArrays()[3][set_iter->second] = peak_shapes[p].left_width;
898  spec.getFloatDataArrays()[4][set_iter->second] = peak_shapes[p].right_width;
899  spec.getFloatDataArrays()[1][set_iter->second] = peak_shapes[p].height; // maximum intensity
900  // calculate area
901  if (peak_shapes[p].type == PeakShape::LORENTZ_PEAK)
902  {
903  PeakShape& ps = peak_shapes[p];
904  double x_left_endpoint = ps.mz_position - 1 / ps.left_width* sqrt(ps.height / 1 - 1);
905  double x_right_endpoint = ps.mz_position + 1 / ps.right_width* sqrt(ps.height / 1 - 1);
906  double area_left = -ps.height / ps.left_width* atan(ps.left_width * (x_left_endpoint - ps.mz_position));
907  double area_right = -ps.height / ps.right_width* atan(ps.right_width * (ps.mz_position - x_right_endpoint));
908  spec[set_iter->second].setIntensity(area_left + area_right); // area is stored as peak intensity
909  }
910  else //It's a Sech - Peak
911  {
912  PeakShape& ps = peak_shapes[p];
913  double x_left_endpoint = ps.mz_position - 1 / ps.left_width* boost::math::acosh(sqrt(ps.height / 0.001));
914  double x_right_endpoint = ps.mz_position + 1 / ps.right_width* boost::math::acosh(sqrt(ps.height / 0.001));
915  double area_left = ps.height / ps.left_width * (sinh(ps.left_width * (ps.mz_position - x_left_endpoint)) / cosh(ps.left_width * (ps.mz_position - x_left_endpoint)));
916  double area_right = -ps.height / ps.right_width * (sinh(ps.right_width * (ps.mz_position - x_right_endpoint)) / cosh(ps.right_width * (ps.mz_position - x_right_endpoint)));
917  spec[set_iter->second].setIntensity(area_left + area_right); // area is stored as peak intensity
918  }
919  ++set_iter;
920  ++p;
921  }
922  ++idx;
923  peak_shapes.clear();
924  }
925 
926  ++counter;
927  }
928  }
929 
930  template <typename InputSpectrumIterator>
932  InputSpectrumIterator& first,
933  InputSpectrumIterator& last,
934  Size iso_map_idx,
935  double noise_level,
937  {
938  d.signal2D.clear();
939  typedef typename InputSpectrumIterator::value_type InputExperimentType;
940  typedef typename InputExperimentType::value_type InputPeakType;
941  typedef std::multimap<double, IsotopeCluster> MapType;
942 
943  double rt, first_peak_mz, last_peak_mz;
944 
945  typename PeakMap::SpectrumType spec;
946  InputPeakType peak;
947 
948  MapType::iterator iso_map_iter = iso_map_.begin();
949  for (Size i = 0; i < iso_map_idx; ++i)
950  ++iso_map_iter;
951 
952 #ifdef DEBUG2D
953  std::cout << "rt begin: " << exp[iso_map_iter->second.scans[0]].getRT()
954  << "\trt end: " << exp[iso_map_iter->second.scans[iso_map_iter->second.scans.size() - 1]].getRT()
955  << " \t" << iso_map_iter->second.scans.size() << " scans"
956  << std::endl;
957 #endif
958 
959  // get left and right endpoint for all scans in the current cluster
960  for (Size i = 0; i < iso_map_iter->second.scans.size(); ++i)
961  {
962  typename PeakMap::iterator exp_it;
963 
964  // first the right scan through binary search
965  rt = exp[iso_map_iter->second.scans[i]].getRT();
966  spec.setRT(rt);
967  InputSpectrumIterator iter = lower_bound(first, last, spec, MSSpectrum::RTLess());
968  // if(iter->getRT() != rt) --iter;
969  exp_it = exp.RTBegin(rt);
970 #ifdef DEBUG2D
971  std::cout << exp_it->getRT() << " vs " << iter->getRT() << std::endl;
972 #endif
973  // now the right mz
975  pair.first = iso_map_iter->second.peaks.begin()->first + i;
976  // get iterator in peaks-set that points to the first peak in the current scan
977  IsotopeCluster::IndexSet::const_iterator set_iter = lower_bound(iso_map_iter->second.peaks.begin(),
978  iso_map_iter->second.peaks.end(),
980 
981  // consider a bit more of the signal to the left
982  first_peak_mz = (exp_it->begin() + set_iter->second)->getMZ() - 1;
983 
984  // find the last entry with this rt-value
985  ++pair.first;
986  IsotopeCluster::IndexSet::const_iterator set_iter2 = lower_bound(iso_map_iter->second.peaks.begin(),
987  iso_map_iter->second.peaks.end(),
989 
990  if (i == iso_map_iter->second.scans.size() - 1)
991  {
992  set_iter2 = iso_map_iter->second.peaks.end();
993  --set_iter2;
994  }
995  else if (set_iter2 != iso_map_iter->second.peaks.begin())
996  --set_iter2;
997 
998  last_peak_mz = (exp_it->begin() + set_iter2->second)->getMZ() + 1;
999 
1000  //std::cout << rt<<": first peak mz "<<first_peak_mz << "\tlast peak mz "<<last_peak_mz <<std::endl;
1001  peak.setPosition(first_peak_mz);
1002  typename PeakMap::SpectrumType::const_iterator raw_data_iter
1003  = lower_bound(iter->begin(), iter->end(), peak, typename InputPeakType::PositionLess());
1004  if (raw_data_iter != iter->begin())
1005  {
1006  --raw_data_iter;
1007  }
1008  double intensity = raw_data_iter->getIntensity();
1009  // while the intensity is falling go to the left
1010  while (raw_data_iter != iter->begin() && (raw_data_iter - 1)->getIntensity() < intensity &&
1011  (raw_data_iter - 1)->getIntensity() > noise_level)
1012  {
1013  --raw_data_iter;
1014  intensity = raw_data_iter->getIntensity();
1015  }
1016  ++raw_data_iter;
1017  IsotopeCluster::IndexPair left, right;
1018  left.first = distance(first, iter);
1019  left.second = raw_data_iter - iter->begin();
1020 #ifdef DEBUG2D
1021  std::cout << "left: " << iter->getRT() << "\t" << raw_data_iter->getMZ() << std::endl;
1022 #endif
1023  // consider a bit more of the signal to the right
1024  peak.setPosition(last_peak_mz + 1);
1025  raw_data_iter
1026  = upper_bound(iter->begin(), iter->end(), peak, typename InputPeakType::PositionLess());
1027  if (raw_data_iter == iter->end())
1028  --raw_data_iter;
1029  intensity = raw_data_iter->getIntensity();
1030  // while the intensity is falling go to the right
1031  while (raw_data_iter + 1 != iter->end() && (raw_data_iter + 1)->getIntensity() < intensity)
1032  {
1033  ++raw_data_iter;
1034  intensity = raw_data_iter->getIntensity();
1035  if ((raw_data_iter + 1 != iter->end()) && (raw_data_iter + 1)->getIntensity() > noise_level)
1036  break;
1037  }
1038  right.first = left.first;
1039  right.second = raw_data_iter - iter->begin();
1040 #ifdef DEBUG2D
1041  std::cout << "right: " << iter->getRT() << "\t" << raw_data_iter->getMZ() << std::endl;
1042 #endif
1043  // region endpoints are stored in global vector
1044  d.signal2D.push_back(left);
1045  d.signal2D.push_back(right);
1046  }
1047 #ifdef DEBUG2D
1048  //std::cout << "fertig"<< std::endl;
1049  std::cout << first_peak_mz << "\t" << last_peak_mz << std::endl;
1050 #endif
1051  }
1052 
1053 }
1054 
DefaultParamHandler.h
OpenMS::PeakShape::LORENTZ_PEAK
Definition: PeakShape.h:70
OpenMS::TwoDOptimization::getMZTolerance
double getMZTolerance() const
Non-mutable access to the matching epsilon.
Definition: TwoDOptimization.h:107
PeakIndex.h
OpenMS::PeakShape::mz_position
double mz_position
Centroid position.
Definition: PeakShape.h:119
MapType
PeakMap MapType
Definition: PeakPickerIterative.cpp:84
OpenMS::TwoDOptimization::optimize
void optimize(InputSpectrumIterator first, InputSpectrumIterator last, PeakMap &ms_exp, bool real2D=true)
Find two dimensional peak clusters and optimize their peak parameters.
Definition: TwoDOptimization.h:271
OpenMS::TwoDOptimization::Data::penalties
OptimizationFunctions::PenaltyFactorsIntensity penalties
Definition: TwoDOptimization.h:177
OpenMS::PairComparatorFirstElement
Class for comparison of std::pair using first ONLY e.g. for use with std::sort.
Definition: ComparatorUtils.h:325
OpenMS::Exception::IllegalArgument
A method or algorithm argument contains illegal values.
Definition: Exception.h:648
OpenMS::TwoDOptimization::curr_region_
std::multimap< double, IsotopeCluster >::const_iterator curr_region_
Pointer to the current region.
Definition: TwoDOptimization.h:205
OpenMS::MSSpectrum::RTLess
Comparator for the retention time.
Definition: MSSpectrum.h:75
OpenMS::TwoDOptimization::max_peak_distance_
double max_peak_distance_
upper bound for distance between two peaks belonging to the same region
Definition: TwoDOptimization.h:208
OpenMS::TwoDOptimization::real_2D_
bool real_2D_
Optimization considering all scans of a cluster or optimization of each scan separately.
Definition: TwoDOptimization.h:222
OpenMS::IsotopeCluster::IndexPair
std::pair< Size, Size > IndexPair
An index e.g. in an MSExperiment.
Definition: IsotopeCluster.h:47
OpenMS::OptimizePick::optimize
void optimize(std::vector< PeakShape > &peaks, Data &data)
Start the optimization of the peak shapes peaks. The original peak shapes will be substituted by the ...
OpenMS::TwoDOptimization::TwoDOptFunctor::m_data
const TwoDOptimization::Data * m_data
Definition: TwoDOptimization.h:197
OpenMS::PeakShape::Type
Type
Peak shape type (asymmetric Lorentzian or asymmetric hyperbolic secans squared).
Definition: PeakShape.h:68
OpenMS::TwoDOptimization::Data::picked_peaks
PeakMap picked_peaks
Definition: TwoDOptimization.h:175
OpenMS::TwoDOptimization::Data::signal2D
std::vector< std::pair< SignedSize, SignedSize > > signal2D
Definition: TwoDOptimization.h:171
OpenMS::Constants::k
const double k
OpenMS::String
A more convenient string class.
Definition: String.h:58
OpenMS::TwoDOptimization::TwoDOptFunctor::TwoDOptFunctor
TwoDOptFunctor(unsigned dimensions, unsigned num_data_points, const TwoDOptimization::Data *data)
Definition: TwoDOptimization.h:188
OpenMS::MSExperiment::begin
Iterator begin()
Definition: MSExperiment.h:157
OpenMS::TwoDOptimization::TwoDOptFunctor::m_values
const int m_values
Definition: TwoDOptimization.h:196
OpenMS::TwoDOptimization
This class provides the two-dimensional optimization of the picked peak parameters.
Definition: TwoDOptimization.h:88
OpenMS::MSExperiment
In-Memory representation of a mass spectrometry experiment.
Definition: MSExperiment.h:77
OpenMS::Size
size_t Size
Size type e.g. used as variable which can hold result of size()
Definition: Types.h:127
OpenMS::PeakShape::left_width
double left_width
Left width parameter.
Definition: PeakShape.h:121
OpenMS::TwoDOptimization::setMaxPeakDistance
void setMaxPeakDistance(double max_peak_distance)
Mutable access to the maximal peak distance in a cluster.
Definition: TwoDOptimization.h:118
OpenMS::Param::getValue
const DataValue & getValue(const String &key) const
Returns a value of a parameter.
OpenMS::OptimizationFunctions::PenaltyFactors
Class for the penalty factors used during the optimization.
Definition: OptimizePick.h:62
OpenMS::MSExperiment::const_iterator
Base::const_iterator const_iterator
Definition: MSExperiment.h:125
OpenMS::TwoDOptimization::getRegionEndpoints_
void getRegionEndpoints_(PeakMap &exp, InputSpectrumIterator &first, InputSpectrumIterator &last, Size iso_map_idx, double noise_level, TwoDOptimization::Data &d)
Get the indices of the first and last raw data point of this region.
Definition: TwoDOptimization.h:931
OpenMS::TwoDOptimization::penalties_
OptimizationFunctions::PenaltyFactorsIntensity penalties_
Penalty factors for some parameters in the optimization.
Definition: TwoDOptimization.h:226
OpenMS::OptimizePick::Data::signal
std::vector< double > signal
Definition: OptimizePick.h:103
OpenMS::IsotopeCluster::ChargedIndexSet::charge
Int charge
charge estimate (convention: zero means "no charge estimate")
Definition: IsotopeCluster.h:61
OpenMS::MSExperiment::size
Size size() const
Definition: MSExperiment.h:127
OpenMS::TwoDOptimization::getMaxPeakDistance
double getMaxPeakDistance() const
Non-mutable access to the maximal peak distance in a cluster.
Definition: TwoDOptimization.h:116
OpenMS::DefaultParamHandler
A base class for all classes handling default parameters.
Definition: DefaultParamHandler.h:91
OpenMS::IsotopeCluster
Stores information about an isotopic cluster (i.e. potential peptide charge variants)
Definition: IsotopeCluster.h:44
PeakShape.h
OpenMS::OptimizePick::Data
Definition: OptimizePick.h:99
OpenMS::TwoDOptimization::getMaxIterations
UInt getMaxIterations() const
Non-mutable access to the maximal number of iterations.
Definition: TwoDOptimization.h:125
OpenMS::Int
int Int
Signed integer type.
Definition: Types.h:102
OpenMS
Main OpenMS namespace.
Definition: FeatureDeconvolution.h:46
OpenMS::MSExperiment::Iterator
std::vector< SpectrumType >::iterator Iterator
Mutable iterator.
Definition: MSExperiment.h:111
OpenMS::TwoDOptimization::setMaxIterations
void setMaxIterations(UInt max_iteration)
Mutable access to the maximal number of iterations.
Definition: TwoDOptimization.h:127
OpenMS::TwoDOptimization::~TwoDOptimization
~TwoDOptimization() override
Destructor.
Definition: TwoDOptimization.h:100
OpenMS::OptimizePick
This class provides the non-linear optimization of the peak parameters.
Definition: OptimizePick.h:95
Exception.h
OpenMS::DataValue
Class to hold strings, numeric values, lists of strings and lists of numeric values.
Definition: DataValue.h:56
OpenMS::IsotopeCluster::scans
std::vector< Size > scans
the scans of this cluster
Definition: IsotopeCluster.h:74
OpenMS::MSExperiment::iterator
Base::iterator iterator
Definition: MSExperiment.h:124
int
OpenMS::TwoDOptimization::max_iteration_
UInt max_iteration_
Convergence Parameter: Maximal number of iterations.
Definition: TwoDOptimization.h:219
OpenMS::TwoDOptimization::Data::positions
std::vector< double > positions
Definition: TwoDOptimization.h:178
OpenMS::PeakShape
Internal representation of a peak shape (used by the PeakPickerCWT)
Definition: PeakShape.h:50
MathFunctions.h
OpenMS::PeakShape::right_width
double right_width
Right width parameter.
Definition: PeakShape.h:123
OpenMS::TwoDOptimization::TwoDOptFunctor::values
int values() const
Definition: TwoDOptimization.h:186
OpenMS::Internal::SpectrumType
MSSpectrum SpectrumType
Definition: MzDataHandler.h:60
OpenMS::TwoDOptimization::Data::signal
std::vector< double > signal
Definition: TwoDOptimization.h:179
OpenMS::TwoDOptimization::getPenalties
const OptimizationFunctions::PenaltyFactorsIntensity & getPenalties() const
Non-mutable access to the minimal number of adjacent scans.
Definition: TwoDOptimization.h:134
OpenMS::PeakShape::height
double height
Maximum intensity of the peak shape.
Definition: PeakShape.h:117
OpenMS::TwoDOptimization::Data::total_nr_peaks
Size total_nr_peaks
Definition: TwoDOptimization.h:173
OpenMS::TwoDOptimization::Data::matching_peaks
std::map< Int, std::vector< PeakIndex > > matching_peaks
Definition: TwoDOptimization.h:174
OpenMS::TwoDOptimization::Data::raw_data_first
PeakMap::ConstIterator raw_data_first
Definition: TwoDOptimization.h:176
OpenMS::TwoDOptimization::optimizeRegionsScanwise_
void optimizeRegionsScanwise_(InputSpectrumIterator &first, InputSpectrumIterator &last, PeakMap &ms_exp)
Definition: TwoDOptimization.h:734
OptimizePeakDeconvolution.h
OpenMS::MSExperiment::empty
bool empty() const
Definition: MSExperiment.h:137
seqan::find
bool find(TFinder &finder, const Pattern< TNeedle, FuzzyAC > &me, PatternAuxData< TNeedle > &dh)
Definition: AhoCorasickAmbiguous.h:884
OpenMS::TwoDOptimization::TwoDOptFunctor::inputs
int inputs() const
Definition: TwoDOptimization.h:185
OpenMS::UInt
unsigned int UInt
Unsigned integer type.
Definition: Types.h:94
OpenMS::MSSpectrum::getFloatDataArrays
const FloatDataArrays & getFloatDataArrays() const
Returns a const reference to the float meta data arrays.
OpenMS::TwoDOptimization::setPenalties
void setPenalties(OptimizationFunctions::PenaltyFactorsIntensity &penalties)
Mutable access to the minimal number of adjacent scans.
Definition: TwoDOptimization.h:136
OpenMS::OptimizationFunctions::PenaltyFactors::pos
double pos
Penalty factor for the peak shape's position.
Definition: OptimizePick.h:80
OpenMS::TwoDOptimization::TwoDOptFunctor
Definition: TwoDOptimization.h:182
OpenMS::TwoDOptimization::iso_map_
std::multimap< double, IsotopeCluster > iso_map_
stores the retention time of each isotopic cluster
Definition: TwoDOptimization.h:202
MSExperiment.h
OpenMS::TwoDOptimization::findMatchingPeaks_
void findMatchingPeaks_(std::multimap< double, IsotopeCluster >::iterator &it, PeakMap &ms_exp)
Identify matching peak in a peak cluster.
OpenMS::MSExperiment::end
Iterator end()
Definition: MSExperiment.h:167
OpenMS::OptimizationFunctions::PenaltyFactorsIntensity::height
double height
Definition: OptimizePeakDeconvolution.h:76
OptimizePick.h
OpenMS::TwoDOptimization::tolerance_mz_
double tolerance_mz_
threshold for the difference in the peak position of two matching peaks
Definition: TwoDOptimization.h:211
OpenMS::TwoDOptimization::searchInScan_
std::vector< double >::iterator searchInScan_(std::vector< double >::iterator scan_begin, std::vector< double >::iterator scan_end, double current_mz)
OpenMS::TwoDOptimization::matching_peaks_
std::map< Int, std::vector< PeakIndex > > matching_peaks_
Indices of peaks in the adjacent scans matching peaks in the scan with no. ref_scan.
Definition: TwoDOptimization.h:215
OpenMS::TwoDOptimization::Data::iso_map_iter
std::multimap< double, IsotopeCluster >::iterator iso_map_iter
Definition: TwoDOptimization.h:172
OpenMS::OptimizationFunctions::PenaltyFactorsIntensity
Class for the penalty factors used during the optimization.
Definition: OptimizePeakDeconvolution.h:57
OpenMS::PeakShape::PositionLess
Comparison of mz_positions.
Definition: PeakShape.h:140
OpenMS::OptimizePick::Data::positions
std::vector< double > positions
Positions and intensity values of the profile data.
Definition: OptimizePick.h:102
OpenMS::TwoDOptimization::Data
Helper struct (contains the size of an area and a raw data container)
Definition: TwoDOptimization.h:169
OpenMS::OptimizationFunctions::PenaltyFactors::lWidth
double lWidth
Penalty factor for the peak shape's left width parameter.
Definition: OptimizePick.h:82
OpenMS::MSExperiment::ConstIterator
std::vector< SpectrumType >::const_iterator ConstIterator
Non-mutable iterator.
Definition: MSExperiment.h:113
OpenMS::TwoDOptimization::setMZTolerance
void setMZTolerance(double tolerance_mz)
Mutable access to the matching epsilon.
Definition: TwoDOptimization.h:109
OpenMS::OptimizationFunctions::PenaltyFactors::rWidth
double rWidth
Penalty factor for the peak shape's right width parameter.
Definition: OptimizePick.h:84
OpenMS::MSSpectrum
The representation of a 1D spectrum.
Definition: MSSpectrum.h:67
OpenMS::TwoDOptimization::optimizeRegions_
void optimizeRegions_(InputSpectrumIterator &first, InputSpectrumIterator &last, PeakMap &ms_exp)
Definition: TwoDOptimization.h:568
OpenMS::MSSpectrum::setRT
void setRT(double rt)
Sets the absolute retention time (in seconds)
OpenMS::Exception::UnableToFit
Exception used if an error occurred while fitting a model to a given dataset.
Definition: Exception.h:676
IsotopeCluster.h
StandardTypes.h
OpenMS::IsotopeCluster::peaks
ChargedIndexSet peaks
peaks in this cluster
Definition: IsotopeCluster.h:71
MSSpectrum.h
OpenMS::MSExperiment::RTBegin
ConstIterator RTBegin(CoordinateType rt) const
Fast search for spectrum range begin.
OpenMS::DefaultParamHandler::param_
Param param_
Container for current parameters.
Definition: DefaultParamHandler.h:149