bool MSSpectrum::RTLess::operator()(const MSSpectrum &a, const MSSpectrum &b) const { return a.getRT() < b.getRT(); }
END_SECTION START_SECTION((const String& getName() const)) MSSpectrum s; TEST_STRING_EQUAL(s.getName(),"") END_SECTION START_SECTION((void setName(const String &name))) MSSpectrum s; s.setName("bla"); TEST_STRING_EQUAL(s.getName(),"bla") END_SECTION START_SECTION((double getRT() const )) MSSpectrum s; TEST_REAL_SIMILAR(s.getRT(),-1.0) END_SECTION START_SECTION((void setRT(double rt))) MSSpectrum s; s.setRT(0.451); TEST_REAL_SIMILAR(s.getRT(),0.451) END_SECTION START_SECTION((double getDriftTime() const )) MSSpectrum s; TEST_REAL_SIMILAR(s.getDriftTime(),-1.0) END_SECTION START_SECTION((void setDriftTime(double dt))) MSSpectrum s;
void PeakPickerHiRes::pick(const MSSpectrum& input, MSSpectrum& output, std::vector<PeakBoundary>& boundaries, bool check_spacings) const { // copy meta data of the input spectrum output.clear(true); output.SpectrumSettings::operator=(input); output.MetaInfoInterface::operator=(input); output.setRT(input.getRT()); output.setMSLevel(input.getMSLevel()); output.setName(input.getName()); output.setType(SpectrumSettings::CENTROID); if (report_FWHM_) { output.getFloatDataArrays().resize(1); output.getFloatDataArrays()[0].setName( report_FWHM_as_ppm_ ? "FWHM_ppm" : "FWHM"); } // don't pick a spectrum with less than 5 data points if (input.size() < 5) return; // if both spacing constraints are disabled, don't check spacings at all: if ((spacing_difference_ == std::numeric_limits<double>::infinity()) && (spacing_difference_gap_ == std::numeric_limits<double>::infinity())) { check_spacings = false; } // signal-to-noise estimation SignalToNoiseEstimatorMedian<MSSpectrum > snt; snt.setParameters(param_.copy("SignalToNoise:", true)); if (signal_to_noise_ > 0.0) { snt.init(input); } // find local maxima in profile data for (Size i = 2; i < input.size() - 2; ++i) { double central_peak_mz = input[i].getMZ(), central_peak_int = input[i].getIntensity(); double left_neighbor_mz = input[i - 1].getMZ(), left_neighbor_int = input[i - 1].getIntensity(); double right_neighbor_mz = input[i + 1].getMZ(), right_neighbor_int = input[i + 1].getIntensity(); // do not interpolate when the left or right support is a zero-data-point if (std::fabs(left_neighbor_int) < std::numeric_limits<double>::epsilon()) continue; if (std::fabs(right_neighbor_int) < std::numeric_limits<double>::epsilon()) continue; // MZ spacing sanity checks double left_to_central = 0.0, central_to_right = 0.0, min_spacing = 0.0; if (check_spacings) { left_to_central = central_peak_mz - left_neighbor_mz; central_to_right = right_neighbor_mz - central_peak_mz; min_spacing = (left_to_central < central_to_right) ? left_to_central : central_to_right; } double act_snt = 0.0, act_snt_l1 = 0.0, act_snt_r1 = 0.0; if (signal_to_noise_ > 0.0) { act_snt = snt.getSignalToNoise(input[i]); act_snt_l1 = snt.getSignalToNoise(input[i - 1]); act_snt_r1 = snt.getSignalToNoise(input[i + 1]); } // look for peak cores meeting MZ and intensity/SNT criteria if ((central_peak_int > left_neighbor_int) && (central_peak_int > right_neighbor_int) && (act_snt >= signal_to_noise_) && (act_snt_l1 >= signal_to_noise_) && (act_snt_r1 >= signal_to_noise_) && (!check_spacings || ((left_to_central < spacing_difference_ * min_spacing) && (central_to_right < spacing_difference_ * min_spacing)))) { // special case: if a peak core is surrounded by more intense // satellite peaks (indicates oscillation rather than // real peaks) -> remove double act_snt_l2 = 0.0, act_snt_r2 = 0.0; if (signal_to_noise_ > 0.0) { act_snt_l2 = snt.getSignalToNoise(input[i - 2]); act_snt_r2 = snt.getSignalToNoise(input[i + 2]); } // checking signal-to-noise? if ((i > 1) && (i + 2 < input.size()) && (left_neighbor_int < input[i - 2].getIntensity()) && (right_neighbor_int < input[i + 2].getIntensity()) && (act_snt_l2 >= signal_to_noise_) && (act_snt_r2 >= signal_to_noise_) && (!check_spacings || ((left_neighbor_mz - input[i - 2].getMZ() < spacing_difference_ * min_spacing) && (input[i + 2].getMZ() - right_neighbor_mz < spacing_difference_ * min_spacing)))) { ++i; continue; } std::map<double, double> peak_raw_data; peak_raw_data[central_peak_mz] = central_peak_int; peak_raw_data[left_neighbor_mz] = left_neighbor_int; peak_raw_data[right_neighbor_mz] = right_neighbor_int; // peak core found, now extend it // to the left Size k = 2; bool previous_zero_left(false); // no need to extend peak if previous intensity was zero Size missing_left(0); Size left_boundary(i - 1); // index of the left boundary for the spline interpolation while ((k <= i) && // prevent underflow (i - k + 1 > 0) && !previous_zero_left && (missing_left <= missing_) && (input[i - k].getIntensity() <= peak_raw_data.begin()->second) && (!check_spacings || (peak_raw_data.begin()->first - input[i - k].getMZ() < spacing_difference_gap_ * min_spacing))) { double act_snt_lk = 0.0; if (signal_to_noise_ > 0.0) { act_snt_lk = snt.getSignalToNoise(input[i - k]); } if ((act_snt_lk >= signal_to_noise_) && (!check_spacings || (peak_raw_data.begin()->first - input[i - k].getMZ() < spacing_difference_ * min_spacing))) { peak_raw_data[input[i - k].getMZ()] = input[i - k].getIntensity(); } else { ++missing_left; if (missing_left <= missing_) { peak_raw_data[input[i - k].getMZ()] = input[i - k].getIntensity(); } } previous_zero_left = (input[i - k].getIntensity() == 0); left_boundary = i - k; ++k; } // to the right k = 2; bool previous_zero_right(false); // no need to extend peak if previous intensity was zero Size missing_right(0); Size right_boundary(i+1); // index of the right boundary for the spline interpolation while ((i + k < input.size()) && !previous_zero_right && (missing_right <= missing_) && (input[i + k].getIntensity() <= peak_raw_data.rbegin()->second) && (!check_spacings || (input[i + k].getMZ() - peak_raw_data.rbegin()->first < spacing_difference_gap_ * min_spacing))) { double act_snt_rk = 0.0; if (signal_to_noise_ > 0.0) { act_snt_rk = snt.getSignalToNoise(input[i + k]); } if ((act_snt_rk >= signal_to_noise_) && (!check_spacings || (input[i + k].getMZ() - peak_raw_data.rbegin()->first < spacing_difference_ * min_spacing))) { peak_raw_data[input[i + k].getMZ()] = input[i + k].getIntensity(); } else { ++missing_right; if (missing_right <= missing_) { peak_raw_data[input[i + k].getMZ()] = input[i + k].getIntensity(); } } previous_zero_right = (input[i + k].getIntensity() == 0); right_boundary = i + k; ++k; } // skip if the minimal number of 3 points for fitting is not reached if (peak_raw_data.size() < 3) continue; CubicSpline2d peak_spline (peak_raw_data); // calculate maximum by evaluating the spline's 1st derivative // (bisection method) double max_peak_mz = central_peak_mz; double max_peak_int = central_peak_int; double threshold = 1e-6; OpenMS::Math::spline_bisection(peak_spline, left_neighbor_mz, right_neighbor_mz, max_peak_mz, max_peak_int, threshold); // // compute FWHM // if (report_FWHM_) { double fwhm_int = max_peak_int / 2.0; threshold = 0.01 * fwhm_int; double mz_mid, int_mid; // left: double mz_left = peak_raw_data.begin()->first; double mz_center = max_peak_mz; if (peak_spline.eval(mz_left) > fwhm_int) { // the spline ends before half max is reached -- take the leftmost point (probably an underestimation) mz_mid = mz_left; } else { do { mz_mid = mz_left / 2 + mz_center / 2; int_mid = peak_spline.eval(mz_mid); if (int_mid < fwhm_int) { mz_left = mz_mid; } else { mz_center = mz_mid; } } while (fabs(int_mid - fwhm_int) > threshold); } const double fwhm_left_mz = mz_mid; // right ... double mz_right = peak_raw_data.rbegin()->first; mz_center = max_peak_mz; if (peak_spline.eval(mz_right) > fwhm_int) { // the spline ends before half max is reached -- take the rightmost point (probably an underestimation) mz_mid = mz_right; } else { do { mz_mid = mz_right / 2 + mz_center / 2; int_mid = peak_spline.eval(mz_mid); if (int_mid < fwhm_int) { mz_right = mz_mid; } else { mz_center = mz_mid; } } while (fabs(int_mid - fwhm_int) > threshold); } const double fwhm_right_mz = mz_mid; const double fwhm_absolute = fwhm_right_mz - fwhm_left_mz; output.getFloatDataArrays()[0].push_back( report_FWHM_as_ppm_ ? fwhm_absolute / max_peak_mz * 1e6 : fwhm_absolute); } // FWHM // save picked peak into output spectrum Peak1D peak; PeakBoundary peak_boundary; peak.setMZ(max_peak_mz); peak.setIntensity(max_peak_int); peak_boundary.mz_min = input[left_boundary].getMZ(); peak_boundary.mz_max = input[right_boundary].getMZ(); output.push_back(peak); boundaries.push_back(peak_boundary); // jump over profile data points that have been considered already i = i + k - 1; } } return; }