int PeakList::findPeakWithMaxIntensity(mass_t expectedMass, mass_t tolerance) const
{
PeakRange pr = findPeaksInRange(expectedMass-tolerance, expectedMass+tolerance);
if (pr.num_peaks==0)
return -1;
if (pr.num_peaks ==1)
return pr.low_idx;
const float doubleTolerance = tolerance + tolerance;
mass_t maxWeightedValue = (doubleTolerance - fabs(peaks_[pr.low_idx].mass - expectedMass)) *
peaks_[pr.low_idx].intensity;
int maxPeakIdx=pr.low_idx;
// find closest peak to exp_pos
for (int i=1; i<pr.num_peaks; i++)
{
const int peakIdx = pr.low_idx + i;
const mass_t weightedValue = (doubleTolerance - fabs(peaks_[peakIdx].mass -
expectedMass)) * peaks_[peakIdx].intensity;
if (weightedValue>maxWeightedValue)
{
maxWeightedValue=weightedValue;
maxPeakIdx = peakIdx;
}
else
break;
}
return maxPeakIdx;
}
// There are fixed magic numbers in this function that should not be changed
// (even though actual tolerances or values in config file might differ)
// changing these numbers without retraining all models might give unanticipated results
void PeakList::calculateLogRandomProbabilities(vector<float>& logIntensities,
vector<float>& logRandomProbabilities) const
{
if (numPeaks_<2)
return;
const float oneOverSqrt2pi = 1.0 / sqrt(2.0*3.1415927);
const float logBias = log(1.2); // to fine tune the zero probabilites
const mass_t peakWindowSize = 0.6; // this is fixed and independent of the tolerance!!!
const mass_t margin = 25.0; // fixed and independent of values in config file
const mass_t windowSize = 100.0; // fixed and independent of values in config file
const mass_t minPeakMass = peaks_[0].mass;
const mass_t maxPeakMass = peaks_[numPeaks_-1].mass;
const mass_t visibleRange = (maxPeakMass - minPeakMass);
logRandomProbabilities.resize(numPeaks_);
int i;
for (i=0; i<numPeaks_; i++)
{
const mass_t peakMass = peaks_[i].mass;
const mass_t relativePosition = (peakMass-minPeakMass)/visibleRange;
const mass_t leftWindow = margin + relativePosition * windowSize;
const mass_t rightWindow = margin + windowSize - leftWindow;
const PeakRange pr = findPeaksInRange(peakMass - leftWindow, peakMass + rightWindow);
const float peakWindowProb = peakWindowSize /(leftWindow + rightWindow);
// some freak cases have 0 peak counts (only in unix)
const int numPeaksInRange = (pr.num_peaks>0 ? pr.num_peaks : 1);
const float zeroProbability = pow((1.0 - peakWindowProb),numPeaksInRange);
if (numPeaksInRange<5)
{
logRandomProbabilities[i] = log(1.0-zeroProbability) + logBias;
}
else // compute special probability based on peak densitiy model
{
vector<float> windowLogIntensities;
int j;
for (j=pr.low_idx; j<=pr.high_idx; j++)
windowLogIntensities.push_back(logIntensities[j]);
float mean=0,sd=1;
calc_mean_sd(windowLogIntensities,&mean,&sd);
const float e = (logIntensities[i] - mean)/sd;
if (e<0)
{
logRandomProbabilities[i] = log(1 - zeroProbability) + logBias;
}
else
{
const float normalizedValue = (oneOverSqrt2pi/ sd) * exp(-0.5*e*e);
const float normalizationConstant = (1.0 - zeroProbability) / (oneOverSqrt2pi / sd); //
logRandomProbabilities[i] = log(normalizedValue*normalizationConstant);
}
}
}
}
/***********************************************************************
calcs for each peak the probability of observing it at random (based on
the neighbor's distribution. Assumes the log_intens are distributed
according to a normal disribution.
************************************************************************/
void Spectrum::set_log_random_probs()
{
if (numPeaks_<2)
return;
const float log_add = log(1.2);
const float one_over_sqr_2pi = 1.0 / sqrt(2*3.1415927);
const mass_t peak_window_size = 0.6; // this is fixed and independent of the tolerance!
const mass_t margin = 25.0;
const mass_t window_size = 100.0;
const mass_t min_mass = peaks_[0].mass;
const mass_t max_mass = peaks_[numPeaks_-1].mass;
const mass_t viz_range = (max_mass - min_mass);
logRandomProbabilities_.resize(numPeaks_);
int i;
for (i=0; i<numPeaks_; i++)
{
const mass_t peak_mass = peaks_[i].mass;
const mass_t rel_position = (peak_mass-min_mass)/viz_range;
const mass_t left_window = margin + rel_position * window_size;
const mass_t right_window = margin + window_size - left_window;
const PeakRange pr = findPeaksInRange(peak_mass-left_window,peak_mass+right_window);
const float peak_window_prob = peak_window_size /(left_window + right_window);
// some freak cases have 0 peak counts (only in unix)
const int num_peaks_in_range = (pr.num_peaks>0 ? pr.num_peaks : 1);
const float zero_prob = pow((1.0 - peak_window_prob),num_peaks_in_range);
if (pr.num_peaks<5)
{
logRandomProbabilities_[i] = log(1.0-zero_prob) + log_add;
}
else
{
vector<float> log_intens;
int j;
for (j=pr.low_idx; j<=pr.high_idx; j++)
log_intens.push_back(logIntensities_[j]);
float mean=0,sd=1;
calc_mean_sd(log_intens,&mean,&sd);
const float e = (logIntensities_[i] - mean)/sd;
if (e<0)
{
logRandomProbabilities_[i] = log(1 - zero_prob) + log_add;
}
else
{
const float norm = (one_over_sqr_2pi/ sd) * exp(-0.5*e*e);
const float norm_const = (1 - zero_prob) / (one_over_sqr_2pi/ sd); //
logRandomProbabilities_[i] = log(norm*norm_const);
}
}
}
}
void PeakList::calculateLogLocalRanks(mass_t windowSize, vector<float>& logLocalRanks) const
{
const mass_t halfWindowSize = windowSize * 0.5;
logLocalRanks.resize(numPeaks_);
int i;
for (i=0; i<numPeaks_; i++)
{
const PeakRange pr= findPeaksInRange(peaks_[i].mass - halfWindowSize,
peaks_[i].mass + halfWindowSize);
int above=0;
int j;
for (j=pr.low_idx; j<=pr.high_idx && j<numPeaks_; j++)
if (peaks_[j].intensity>peaks_[i].intensity)
above++;
logLocalRanks[i] = log(1.0 + static_cast<float>(above));
}
}
/*********************************************************************
// gives each peak it log local rank
// good be done more effciently...
**********************************************************************/
void Spectrum::calc_log_local_ranks()
{
const mass_t half_window_size = config_->get_local_window_size() * 0.5;
logLocalRanks_.resize(numPeaks_);
int i;
for (i=0; i<numPeaks_; i++)
{
const mass_t peak_mass = peaks_[i].mass;
const PeakRange pr= findPeaksInRange(peak_mass - half_window_size,
peak_mass + half_window_size);
int above=0;
int j;
for (j=pr.low_idx; j<=pr.high_idx && j<numPeaks_; j++)
if (peaks_[j].intensity>peaks_[i].intensity)
above++;
logLocalRanks_[i] = log(1.0 + static_cast<float>(above));
}
}
