public HCDInfo(GlypID.Readers.clsRawData argReader, int argScanNo)
{
int ParentScan = argReader.GetParentScan(argScanNo);
// Scorers and transforms
GlypID.HCDScoring.clsHCDScoring HCDScoring = new GlypID.HCDScoring.clsHCDScoring();
GlypID.HornTransform.clsHornTransform Transform = new GlypID.HornTransform.clsHornTransform();
// mzs , intensities
float[] hcd_mzs = null;
float[] hcd_intensities = null;
float[] parent_mzs = null;
float[] parent_intensities = null;
// Peaks
GlypID.Peaks.clsPeak[] parent_peaks;
GlypID.Peaks.clsPeak[] hcd_peaks;
// Peak Processors
GlypID.Peaks.clsPeakProcessor hcdPeakProcessor = new GlypID.Peaks.clsPeakProcessor();
GlypID.Peaks.clsPeakProcessor parentPeakProcessor = new GlypID.Peaks.clsPeakProcessor();
// Results
GlypID.HCDScoring.clsHCDScoringScanResults[] hcd_scoring_results;
GlypID.HornTransform.clsHornTransformResults[] transform_results;
// Params
GlypID.Scoring.clsScoringParameters scoring_parameters = new GlypID.Scoring.clsScoringParameters();
GlypID.HornTransform.clsHornTransformParameters transform_parameters = new GlypID.HornTransform.clsHornTransformParameters();
scoring_parameters.MinNumPeaksToConsider = 2;
scoring_parameters.PPMTolerance = 10;
scoring_parameters.UsePPM = true;
// Init
Transform.TransformParameters = transform_parameters;
// Loading parent
int parent_scan = argReader.GetParentScan(argScanNo);
double parent_mz = argReader.GetParentMz(argScanNo);
int scan_level = argReader.GetMSLevel(argScanNo);
int parent_level = argReader.GetMSLevel(parent_scan);
argReader.GetSpectrum(parent_scan, ref parent_mzs, ref parent_intensities);
// Parent processing
parent_peaks = new GlypID.Peaks.clsPeak[1];
parentPeakProcessor.ProfileType = GlypID.enmProfileType.PROFILE;
parentPeakProcessor.DiscoverPeaks(ref parent_mzs, ref parent_intensities, ref parent_peaks,
Convert.ToSingle(transform_parameters.MinMZ), Convert.ToSingle(transform_parameters.MaxMZ), true);
double bkg_intensity = parentPeakProcessor.GetBackgroundIntensity(ref parent_intensities);
double min_peptide_intensity = bkg_intensity * transform_parameters.PeptideMinBackgroundRatio;
transform_results = new GlypID.HornTransform.clsHornTransformResults[1];
bool found = Transform.FindPrecursorTransform(Convert.ToSingle(bkg_intensity), Convert.ToSingle(min_peptide_intensity), ref parent_mzs, ref parent_intensities, ref parent_peaks, Convert.ToSingle(parent_mz), ref transform_results);
if (!found && (argReader.GetMonoChargeFromHeader(ParentScan) > 0))
{
found = true;
double mono_mz = argReader.GetMonoMzFromHeader(ParentScan);
if (mono_mz == 0)
{
mono_mz = parent_mz;
}
short[] charges = new short[1];
charges[0] = argReader.GetMonoChargeFromHeader(ParentScan);
Transform.AllocateValuesToTransform(Convert.ToSingle(mono_mz), 0, ref charges, ref transform_results); // Change abundance value from 0 to parent_intensity if you wish
}
if (found && transform_results.Length == 1)
{
// Score HCD scan first
argReader.GetSpectrum(argScanNo, ref hcd_mzs, ref hcd_intensities);
double hcd_background_intensity = GlypID.Utils.GetAverage(ref hcd_intensities, ref hcd_mzs, Convert.ToSingle(scoring_parameters.MinHCDMz), Convert.ToSingle(scoring_parameters.MaxHCDMz));
hcdPeakProcessor.SetPeakIntensityThreshold(hcd_background_intensity);
hcd_peaks = new GlypID.Peaks.clsPeak[1];
//Check Header
string Header = argReader.GetScanDescription(argScanNo);
hcdPeakProcessor.ProfileType = GlypID.enmProfileType.PROFILE;
if (Header.Substring(Header.IndexOf("+") + 1).Trim().StartsWith("c"))
{
hcdPeakProcessor.ProfileType = GlypID.enmProfileType.CENTROIDED;
}
hcdPeakProcessor.DiscoverPeaks(ref hcd_mzs, ref hcd_intensities, ref hcd_peaks, Convert.ToSingle
(scoring_parameters.MinHCDMz), Convert.ToSingle(scoring_parameters.MaxHCDMz), false);
hcdPeakProcessor.InitializeUnprocessedData();
hcd_scoring_results = new GlypID.HCDScoring.clsHCDScoringScanResults[1];
HCDScoring.ScoringParameters = scoring_parameters;
_hcd_score = HCDScoring.ScoreHCDSpectra(ref hcd_peaks, ref hcd_mzs, ref hcd_intensities, ref transform_results, ref hcd_scoring_results);
_gType = (GlypID.enmGlycanType)hcd_scoring_results[0].menm_glycan_type;
}
}
private static MSScan GetScanFromFile(int argScanNo, double argSingleToNoise, double argPeakBackground, double argPeptideBackground, short argMaxCharge, GlypID.Readers.clsRawData Raw)
{
float[] _cidMzs = null;
float[] _cidIntensities = null;
GlypID.Peaks.clsPeak[] _cidPeaks = new GlypID.Peaks.clsPeak[1];
GlypID.Peaks.clsPeak[] _parentPeaks = new GlypID.Peaks.clsPeak[1];
GlypID.HornTransform.clsHornTransform mobjTransform = new GlypID.HornTransform.clsHornTransform();
GlypID.HornTransform.clsHornTransformParameters mobjTransformParameters = new GlypID.HornTransform.clsHornTransformParameters();
GlypID.HornTransform.clsHornTransformResults[] _transformResult;
GlypID.Peaks.clsPeakProcessor cidPeakProcessor = new GlypID.Peaks.clsPeakProcessor();
GlypID.Peaks.clsPeakProcessorParameters cidPeakParameters = new GlypID.Peaks.clsPeakProcessorParameters();
GlypID.Peaks.clsPeakProcessor parentPeakProcessor = new GlypID.Peaks.clsPeakProcessor();
GlypID.Peaks.clsPeakProcessorParameters parentPeakParameters = new GlypID.Peaks.clsPeakProcessorParameters();
//Start Read Scan
MSScan scan = new MSScan(argScanNo);
Raw.GetSpectrum(argScanNo, ref _cidMzs, ref _cidIntensities);
scan.MsLevel = Raw.GetMSLevel(Convert.ToInt32(argScanNo));
double min_peptide_intensity = 0;
scan.Time = Raw.GetScanTime(scan.ScanNo);
scan.ScanHeader = Raw.GetScanDescription(scan.ScanNo);
if (scan.MsLevel != 1)
{
float[] _parentRawMzs = null;
float[] _parentRawIntensitys = null;
string Header = Raw.GetScanDescription(argScanNo);
cidPeakProcessor.ProfileType = GlypID.enmProfileType.CENTROIDED;
if (Header.Substring(Header.IndexOf("+") + 1).Trim().StartsWith("p"))
{
cidPeakProcessor.ProfileType = GlypID.enmProfileType.PROFILE;
}
// cidPeakProcessor.DiscoverPeaks(ref _cidMzs, ref _cidIntensities, ref _cidPeaks,
// Convert.ToSingle(mobjTransformParameters.MinMZ), Convert.ToSingle(mobjTransformParameters.MaxMZ), false);
for (int chNum = 0; chNum < _cidMzs.Length; chNum++)
{
scan.MSPeaks.Add(new MSPeak(
Convert.ToSingle(_cidMzs[chNum]),
Convert.ToSingle(_cidIntensities[chNum])));
}
//for (int chNum = 0; chNum < _cidMzs.Length; chNum++)
//{
// scan.MSPeaks.Add(new MSPeak(
// Convert.ToSingle(_cidMzs[chNum]),
// Convert.ToSingle(_cidIntensities[chNum])));
//}
// Get parent information
scan.ParentScanNo = Raw.GetParentScan(scan.ScanNo);
Raw.GetSpectrum(scan.ParentScanNo, ref _parentRawMzs, ref _parentRawIntensitys);
parentPeakProcessor.ProfileType = GlypID.enmProfileType.PROFILE;
parentPeakProcessor.DiscoverPeaks(ref _parentRawMzs, ref _parentRawIntensitys, ref _parentPeaks, Convert.ToSingle(mobjTransformParameters.MinMZ), Convert.ToSingle(mobjTransformParameters.MaxMZ), true);
float _parentBackgroundIntensity = (float)parentPeakProcessor.GetBackgroundIntensity(ref _parentRawIntensitys);
_transformResult = new GlypID.HornTransform.clsHornTransformResults[1];
bool found = false;
if (Raw.IsFTScan(scan.ParentScanNo))
{
// High resolution data
found = mobjTransform.FindPrecursorTransform(Convert.ToSingle(_parentBackgroundIntensity), Convert.ToSingle(min_peptide_intensity), ref _parentRawMzs, ref _parentRawIntensitys, ref _parentPeaks, Convert.ToSingle(scan.ParentMZ), ref _transformResult);
}
if (!found)//de-isotope fail
{
// Low resolution data or bad high res spectra
short cs = Raw.GetMonoChargeFromHeader(scan.ScanNo);
double monoMZ = Raw.GetMonoMzFromHeader(scan.ScanNo);
List <float> ParentMzs = new List <float>(_parentRawMzs);
int CloseIdx = MassUtility.GetClosestMassIdx(ParentMzs, Convert.ToSingle(monoMZ));
if (cs > 0)
{
short[] charges = new short[1];
charges[0] = cs;
mobjTransform.AllocateValuesToTransform(Convert.ToSingle(scan.ParentMZ), Convert.ToInt32(_parentRawIntensitys[CloseIdx]), ref charges, ref _transformResult);
}
else
{
// instrument has no charge just store 2 and 3.
short[] charges = new short[2];
charges[0] = 2;
charges[1] = 3;
mobjTransform.AllocateValuesToTransform(Convert.ToSingle(scan.ParentMZ), Convert.ToInt32(_parentRawIntensitys[CloseIdx]), ref charges, ref _transformResult);
}
}
if (_transformResult[0].mint_peak_index == -1) //De-isotope parent scan
{
//Get parent info
MSScan _parentScan = GetScanFromFile(scan.ParentScanNo, argSingleToNoise, argPeakBackground, argPeptideBackground, argMaxCharge, Raw);
float[] _MSMzs = null;
float[] _MSIntensities = null;
Raw.GetSpectrum(scan.ParentScanNo, ref _MSMzs, ref _MSIntensities);
// Now find peaks
parentPeakParameters.SignalToNoiseThreshold = 0;
parentPeakParameters.PeakBackgroundRatio = 0.01;
parentPeakProcessor.SetOptions(parentPeakParameters);
parentPeakProcessor.ProfileType = GlypID.enmProfileType.PROFILE;
parentPeakProcessor.DiscoverPeaks(ref _MSMzs, ref _MSIntensities, ref _cidPeaks,
Convert.ToSingle(mobjTransformParameters.MinMZ), Convert.ToSingle(mobjTransformParameters.MaxMZ), true);
//Look for charge and mono.
float[] monoandcharge = FindChargeAndMono(_cidPeaks, Convert.ToSingle(Raw.GetParentMz(scan.ScanNo)), scan.ScanNo, Raw);
//scan.ParentMonoMW = _parentScan.MSPeaks[ClosedIdx].MonoMass;
//scan.ParentAVGMonoMW = _parentScan.MSPeaks[ClosedIdx].;
scan.ParentMZ = monoandcharge[0];
if (monoandcharge[1] == 0.0f)
{
scan.ParentCharge = Convert.ToInt32(Raw.GetMonoChargeFromHeader(scan.ParentScanNo));
}
else
{
scan.ParentCharge = Convert.ToInt32(monoandcharge[1]);
}
scan.ParentMonoMW = (monoandcharge[0] - Atoms.ProtonMass) * monoandcharge[1];
}
else
{
scan.ParentMonoMW = (float)_transformResult[0].mdbl_mono_mw;
scan.ParentAVGMonoMW = (float)_transformResult[0].mdbl_average_mw;
scan.ParentMZ = (float)_transformResult[0].mdbl_mz;
scan.ParentCharge = (int)_transformResult[0].mshort_cs;
}
scan.IsCIDScan = Raw.IsCIDScan(argScanNo);
scan.IsFTScan = Raw.IsFTScan(argScanNo);
Array.Clear(_transformResult, 0, _transformResult.Length);
Array.Clear(_cidPeaks, 0, _cidPeaks.Length);
Array.Clear(_cidMzs, 0, _cidMzs.Length);
Array.Clear(_cidIntensities, 0, _cidIntensities.Length);
Array.Clear(_parentRawMzs, 0, _parentRawMzs.Length);
Array.Clear(_parentRawIntensitys, 0, _parentRawIntensitys.Length);
}
else //MS Scan
{
scan.ParentMZ = 0.0f;
double mdbl_current_background_intensity = 0;
// Now find peaks
parentPeakParameters.SignalToNoiseThreshold = argSingleToNoise;
parentPeakParameters.PeakBackgroundRatio = argPeakBackground;
parentPeakProcessor.SetOptions(parentPeakParameters);
parentPeakProcessor.ProfileType = GlypID.enmProfileType.PROFILE;
parentPeakProcessor.DiscoverPeaks(ref _cidMzs, ref _cidIntensities, ref _cidPeaks,
Convert.ToSingle(mobjTransformParameters.MinMZ), Convert.ToSingle(mobjTransformParameters.MaxMZ), true);
mdbl_current_background_intensity = parentPeakProcessor.GetBackgroundIntensity(ref _cidIntensities);
// Settings
min_peptide_intensity = mdbl_current_background_intensity * mobjTransformParameters.PeptideMinBackgroundRatio;
if (mobjTransformParameters.UseAbsolutePeptideIntensity)
{
if (min_peptide_intensity < mobjTransformParameters.AbsolutePeptideIntensity)
{
min_peptide_intensity = mobjTransformParameters.AbsolutePeptideIntensity;
}
}
mobjTransformParameters.PeptideMinBackgroundRatio = argPeptideBackground;
mobjTransformParameters.MaxCharge = argMaxCharge;
mobjTransform.TransformParameters = mobjTransformParameters;
// Now perform deisotoping
_transformResult = new GlypID.HornTransform.clsHornTransformResults[1];
mobjTransform.PerformTransform(Convert.ToSingle(mdbl_current_background_intensity), Convert.ToSingle(min_peptide_intensity), ref _cidMzs, ref _cidIntensities, ref _cidPeaks, ref _transformResult);
// for getting results
for (int chNum = 0; chNum < _transformResult.Length; chNum++)
{
double sumintensity = 0.0;
double mostIntenseIntensity = 0.0;
for (int i = 0; i < _transformResult[chNum].marr_isotope_peak_indices.Length; i++)
{
sumintensity = sumintensity + _cidPeaks[_transformResult[chNum].marr_isotope_peak_indices[i]].mdbl_intensity;
if (Math.Abs(_transformResult[chNum].mdbl_most_intense_mw -
(_cidPeaks[_transformResult[chNum].marr_isotope_peak_indices[i]].mdbl_mz * _transformResult[chNum].mshort_cs - Atoms.ProtonMass * _transformResult[chNum].mshort_cs))
< 1.0 / _transformResult[chNum].mshort_cs)
{
mostIntenseIntensity = _cidPeaks[_transformResult[chNum].mint_peak_index].mdbl_intensity;
}
}
scan.MSPeaks.Add(new MSPeak(
Convert.ToSingle(_transformResult[chNum].mdbl_mono_mw),
_transformResult[chNum].mint_mono_intensity,
_transformResult[chNum].mshort_cs,
Convert.ToSingle(_transformResult[chNum].mdbl_mz),
Convert.ToSingle(_transformResult[chNum].mdbl_fit),
Convert.ToSingle(_transformResult[chNum].mdbl_most_intense_mw),
mostIntenseIntensity,
sumintensity
));
}
Array.Clear(_transformResult, 0, _transformResult.Length);
Array.Clear(_cidPeaks, 0, _cidPeaks.Length);
Array.Clear(_cidMzs, 0, _cidMzs.Length);
Array.Clear(_cidIntensities, 0, _cidIntensities.Length);
}
return(scan);
}
public Class1(string argFileName,int argScanNo)
{
_scanNum = argScanNo;
_filename = argFileName;
GlypID.HornTransform.clsHornTransform Transform = new GlypID.HornTransform.clsHornTransform();
GlypID.Peaks.clsPeakProcessor cidPeakProcessor = new GlypID.Peaks.clsPeakProcessor();
GlypID.Peaks.clsPeakProcessor parentPeakProcessor = new GlypID.Peaks.clsPeakProcessor();
GlypID.HornTransform.clsHornTransformParameters transform_parameters = new GlypID.HornTransform.clsHornTransformParameters();
GlypID.Peaks.clsPeakProcessorParameters peak_parameters = new GlypID.Peaks.clsPeakProcessorParameters();
Raw = new GlypID.Readers.clsRawData(_filename, GlypID.Readers.FileType.FINNIGAN);
Raw.GetSpectrum(_scanNum, ref _cidMzs, ref _cidIntensities);
Transform.TransformParameters = transform_parameters;
_msLevel = Raw.GetMSLevel(_scanNum);
if (_msLevel > 1)
{
_parentScanNum = Raw.GetParentScan(_scanNum);
_parentMz = (float)Raw.GetParentMz(_scanNum);
}
else
{
return; //MS scan
}
Raw.GetSpectrum(_parentScanNum, ref _parentRawMzs, ref _parentRawIntensitys);
_cidPeaks = new GlypID.Peaks.clsPeak[1];
cidPeakProcessor.ProfileType = GlypID.enmProfileType.CENTROIDED;
cidPeakProcessor.DiscoverPeaks(ref _cidMzs, ref _cidIntensities, ref _cidPeaks,
Convert.ToSingle(transform_parameters.MinMZ), Convert.ToSingle(transform_parameters.MaxMZ), false);
_parentPeaks = new GlypID.Peaks.clsPeak[1];
parentPeakProcessor.ProfileType = GlypID.enmProfileType.PROFILE;
parentPeakProcessor.DiscoverPeaks(ref _parentRawMzs, ref _parentRawIntensitys, ref _parentPeaks,
Convert.ToSingle(transform_parameters.MinMZ), Convert.ToSingle(transform_parameters.MaxMZ), true);
_parentBackgroundIntensity = (float)parentPeakProcessor.GetBackgroundIntensity(ref _parentRawIntensitys);
double min_peptide_intensity = _parentBackgroundIntensity * transform_parameters.PeptideMinBackgroundRatio;
if (transform_parameters.UseAbsolutePeptideIntensity)
{
if (min_peptide_intensity < transform_parameters.AbsolutePeptideIntensity)
min_peptide_intensity = transform_parameters.AbsolutePeptideIntensity;
}
_transformResult = new GlypID.HornTransform.clsHornTransformResults[1];
bool found = Transform.FindPrecursorTransform(Convert.ToSingle(_parentBackgroundIntensity), Convert.ToSingle(min_peptide_intensity), ref _parentRawMzs, ref _parentRawIntensitys, ref _parentPeaks, Convert.ToSingle(_parentMz), ref _transformResult);
if (Raw.IsFTScan(_parentScanNum))
{
// High resolution data
found = Transform.FindPrecursorTransform(Convert.ToSingle(_parentBackgroundIntensity), Convert.ToSingle(min_peptide_intensity), ref _parentRawMzs, ref _parentRawIntensitys, ref _parentPeaks, Convert.ToSingle(_parentMz), ref _transformResult);
}
if (!found)
{
// Low resolution data or bad high res spectra
short cs = Raw.GetMonoChargeFromHeader(_scanNum);
if (cs > 0)
{
short[] charges = new short[1];
charges[0] = cs;
Transform.AllocateValuesToTransform(Convert.ToSingle(_parentMz),500, ref charges, ref _transformResult);
}
else
{
// instrument has no charge just store 2 and 3.
short[] charges = new short[2];
charges[0] = 2;
charges[1] = 3;
Transform.AllocateValuesToTransform(Convert.ToSingle(_parentMz), 500,ref charges, ref _transformResult);
}
}
_parentMonoMW = (float)_transformResult[0].mdbl_mono_mw;
_parentCharge = (int)_transformResult[0].mshort_cs;
MaxIntensityPeak();
Raw.Close();
}
public Class1(string argFileName, int argScanNo)
{
_scanNum = argScanNo;
_filename = argFileName;
GlypID.HornTransform.clsHornTransform Transform = new GlypID.HornTransform.clsHornTransform();
GlypID.Peaks.clsPeakProcessor cidPeakProcessor = new GlypID.Peaks.clsPeakProcessor();
GlypID.Peaks.clsPeakProcessor parentPeakProcessor = new GlypID.Peaks.clsPeakProcessor();
GlypID.HornTransform.clsHornTransformParameters transform_parameters = new GlypID.HornTransform.clsHornTransformParameters();
GlypID.Peaks.clsPeakProcessorParameters peak_parameters = new GlypID.Peaks.clsPeakProcessorParameters();
Raw = new GlypID.Readers.clsRawData(_filename, GlypID.Readers.FileType.FINNIGAN);
Raw.GetSpectrum(_scanNum, ref _cidMzs, ref _cidIntensities);
Transform.TransformParameters = transform_parameters;
_msLevel = Raw.GetMSLevel(_scanNum);
if (_msLevel > 1)
{
_parentScanNum = Raw.GetParentScan(_scanNum);
_parentMz = (float)Raw.GetParentMz(_scanNum);
}
else
{
return; //MS scan
}
Raw.GetSpectrum(_parentScanNum, ref _parentRawMzs, ref _parentRawIntensitys);
_cidPeaks = new GlypID.Peaks.clsPeak[1];
cidPeakProcessor.ProfileType = GlypID.enmProfileType.CENTROIDED;
cidPeakProcessor.DiscoverPeaks(ref _cidMzs, ref _cidIntensities, ref _cidPeaks,
Convert.ToSingle(transform_parameters.MinMZ), Convert.ToSingle(transform_parameters.MaxMZ), false);
_parentPeaks = new GlypID.Peaks.clsPeak[1];
parentPeakProcessor.ProfileType = GlypID.enmProfileType.PROFILE;
parentPeakProcessor.DiscoverPeaks(ref _parentRawMzs, ref _parentRawIntensitys, ref _parentPeaks,
Convert.ToSingle(transform_parameters.MinMZ), Convert.ToSingle(transform_parameters.MaxMZ), true);
_parentBackgroundIntensity = (float)parentPeakProcessor.GetBackgroundIntensity(ref _parentRawIntensitys);
double min_peptide_intensity = _parentBackgroundIntensity * transform_parameters.PeptideMinBackgroundRatio;
if (transform_parameters.UseAbsolutePeptideIntensity)
{
if (min_peptide_intensity < transform_parameters.AbsolutePeptideIntensity)
{
min_peptide_intensity = transform_parameters.AbsolutePeptideIntensity;
}
}
_transformResult = new GlypID.HornTransform.clsHornTransformResults[1];
bool found = Transform.FindPrecursorTransform(Convert.ToSingle(_parentBackgroundIntensity), Convert.ToSingle(min_peptide_intensity), ref _parentRawMzs, ref _parentRawIntensitys, ref _parentPeaks, Convert.ToSingle(_parentMz), ref _transformResult);
if (Raw.IsFTScan(_parentScanNum))
{
// High resolution data
found = Transform.FindPrecursorTransform(Convert.ToSingle(_parentBackgroundIntensity), Convert.ToSingle(min_peptide_intensity), ref _parentRawMzs, ref _parentRawIntensitys, ref _parentPeaks, Convert.ToSingle(_parentMz), ref _transformResult);
}
if (!found)
{
// Low resolution data or bad high res spectra
short cs = Raw.GetMonoChargeFromHeader(_scanNum);
if (cs > 0)
{
short[] charges = new short[1];
charges[0] = cs;
Transform.AllocateValuesToTransform(Convert.ToSingle(_parentMz), 500, ref charges, ref _transformResult);
}
else
{
// instrument has no charge just store 2 and 3.
short[] charges = new short[2];
charges[0] = 2;
charges[1] = 3;
Transform.AllocateValuesToTransform(Convert.ToSingle(_parentMz), 500, ref charges, ref _transformResult);
}
}
_parentMonoMW = (float)_transformResult[0].mdbl_mono_mw;
_parentCharge = (int)_transformResult[0].mshort_cs;
MaxIntensityPeak();
Raw.Close();
}
private MSScan GetScanFromFile(int argScanNo)
{
MSScan scan = new MSScan(argScanNo);
float[] _cidMzs = null;
float[] _cidIntensities = null;
Raw.GetSpectrum(argScanNo, ref _cidMzs, ref _cidIntensities);
scan.MsLevel = Raw.GetMSLevel(argScanNo);
double min_peptide_intensity = 0;
scan.Time = Raw.GetScanTime(scan.ScanNo);
scan.ScanHeader = Raw.GetScanDescription(scan.ScanNo);
if (scan.MsLevel != 1)
{
float[] _parentRawMzs = null;
float[] _parentRawIntensitys = null;
scan.ParentMZ = (float)Raw.GetParentMz(argScanNo);
cidPeakProcessor.ProfileType = GlypID.enmProfileType.CENTROIDED;
cidPeakProcessor.DiscoverPeaks(ref _cidMzs, ref _cidIntensities, ref _cidPeaks,
Convert.ToSingle(mobjTransformParameters.MinMZ), Convert.ToSingle(mobjTransformParameters.MaxMZ), false);
for (int chNum = 0; chNum < _cidPeaks.Length; chNum++)
{
scan.MSPeaks.Add(new MSPeak(
Convert.ToSingle(_cidPeaks[chNum].mdbl_mz),
Convert.ToSingle(_cidPeaks[chNum].mdbl_intensity)));
}
//for (int chNum = 0; chNum < _cidMzs.Length; chNum++)
//{
// scan.MSPeaks.Add(new MSPeak(
// Convert.ToSingle(_cidMzs[chNum]),
// Convert.ToSingle(_cidIntensities[chNum])));
//}
// Get parent information
scan.ParentScanNo = Raw.GetParentScan(scan.ScanNo);
Raw.GetSpectrum(scan.ParentScanNo, ref _parentRawMzs, ref _parentRawIntensitys);
parentPeakProcessor.ProfileType = GlypID.enmProfileType.PROFILE;
parentPeakProcessor.DiscoverPeaks(ref _parentRawMzs, ref _parentRawIntensitys, ref _parentPeaks, Convert.ToSingle(mobjTransformParameters.MinMZ), Convert.ToSingle(mobjTransformParameters.MaxMZ), true);
float _parentBackgroundIntensity = (float)parentPeakProcessor.GetBackgroundIntensity(ref _parentRawIntensitys);
bool found = mobjTransform.FindPrecursorTransform(Convert.ToSingle(_parentBackgroundIntensity), Convert.ToSingle(min_peptide_intensity), ref _parentRawMzs, ref _parentRawIntensitys, ref _parentPeaks, Convert.ToSingle(scan.ParentMZ), ref _transformResult);
if (Raw.IsFTScan(scan.ParentScanNo))
{
// High resolution data
found = mobjTransform.FindPrecursorTransform(Convert.ToSingle(_parentBackgroundIntensity), Convert.ToSingle(min_peptide_intensity), ref _parentRawMzs, ref _parentRawIntensitys, ref _parentPeaks, Convert.ToSingle(scan.ParentMZ), ref _transformResult);
}
//if (!found) //de-isotope fail
//{
// // Low resolution data or bad high res spectra
// short cs = Raw.GetMonoChargeFromHeader(scan.ScanNo);
// if (cs > 0)
// {
// short[] charges = new short[1];
// charges[0] = cs;
// mobjTransform.AllocateValuesToTransform(Convert.ToSingle(scan.ParentMZ), ref charges, ref _transformResult);
// }
// else
// {
// // instrument has no charge just store 2 and 3.
// short[] charges = new short[2];
// charges[0] = 2;
// charges[1] = 3;
// mobjTransform.AllocateValuesToTransform(Convert.ToSingle(scan.ParentMZ), ref charges, ref _transformResult);
// }
//}
scan.ParentMonoMW = (float)_transformResult[0].mdbl_mono_mw;
scan.ParentAVGMonoMW = (float)_transformResult[0].mdbl_average_mw;
scan.ParentCharge = (int)_transformResult[0].mshort_cs;
Array.Clear(_transformResult, 0, _transformResult.Length);
Array.Clear(_cidPeaks, 0, _cidPeaks.Length);
Array.Clear(_cidMzs, 0, _cidMzs.Length);
Array.Clear(_cidIntensities, 0, _cidIntensities.Length);
Array.Clear(_parentRawMzs, 0, _parentRawMzs.Length);
Array.Clear(_parentRawIntensitys, 0, _parentRawIntensitys.Length);
}
else //MS Scan
{
scan.ParentMZ = 0.0f;
double mdbl_current_background_intensity = 0;
// Now find peaks
parentPeakParameters.SignalToNoiseThreshold = _singleToNoiseRatio;
parentPeakParameters.PeakBackgroundRatio = _peakBackgroundRatio;
parentPeakProcessor.SetOptions(parentPeakParameters);
parentPeakProcessor.ProfileType = GlypID.enmProfileType.PROFILE;
parentPeakProcessor.DiscoverPeaks(ref _cidMzs, ref _cidIntensities, ref _cidPeaks,
Convert.ToSingle(mobjTransformParameters.MinMZ), Convert.ToSingle(mobjTransformParameters.MaxMZ), true);
mdbl_current_background_intensity = parentPeakProcessor.GetBackgroundIntensity(ref _cidIntensities);
// Settings
min_peptide_intensity = mdbl_current_background_intensity * mobjTransformParameters.PeptideMinBackgroundRatio;
if (mobjTransformParameters.UseAbsolutePeptideIntensity)
{
if (min_peptide_intensity < mobjTransformParameters.AbsolutePeptideIntensity)
min_peptide_intensity = mobjTransformParameters.AbsolutePeptideIntensity;
}
mobjTransformParameters.PeptideMinBackgroundRatio = _peptideMinBackgroundRatio;
mobjTransformParameters.MaxCharge = _maxCharge;
mobjTransform.TransformParameters = mobjTransformParameters;
// Now perform deisotoping
_transformResult = new GlypID.HornTransform.clsHornTransformResults[1];
mobjTransform.PerformTransform(Convert.ToSingle(mdbl_current_background_intensity), Convert.ToSingle(min_peptide_intensity), ref _cidMzs, ref _cidIntensities, ref _cidPeaks, ref _transformResult);
// for getting results
for (int chNum = 0; chNum < _transformResult.Length; chNum++)
{
double sumintensity = 0.0;
double mostIntenseIntensity = 0.0;
for (int i = 0; i < _transformResult[chNum].marr_isotope_peak_indices.Length; i++)
{
sumintensity = sumintensity + _cidPeaks[_transformResult[chNum].marr_isotope_peak_indices[i]].mdbl_intensity;
if (Math.Abs(_transformResult[chNum].mdbl_most_intense_mw -
(_cidPeaks[_transformResult[chNum].marr_isotope_peak_indices[i]].mdbl_mz * _transformResult[chNum].mshort_cs - Atoms.ProtonMass * _transformResult[chNum].mshort_cs)
) < 1.0 / _transformResult[chNum].mshort_cs
)
{
mostIntenseIntensity = _cidPeaks[_transformResult[chNum].mint_peak_index].mdbl_intensity;
}
}
scan.MSPeaks.Add(new MSPeak(
Convert.ToSingle(_transformResult[chNum].mdbl_mono_mw),
_transformResult[chNum].mint_mono_intensity,
_transformResult[chNum].mshort_cs,
Convert.ToSingle(_transformResult[chNum].mdbl_mz),
Convert.ToSingle(_transformResult[chNum].mdbl_fit),
Convert.ToSingle(_transformResult[chNum].mdbl_most_intense_mw),
mostIntenseIntensity,
sumintensity));
}
Array.Clear(_transformResult, 0, _transformResult.Length);
Array.Clear(_cidPeaks, 0, _cidPeaks.Length);
Array.Clear(_cidMzs, 0, _cidMzs.Length);
Array.Clear(_cidIntensities, 0, _cidIntensities.Length);
}
return scan;
}