//static
bool
DataprocHandler::apply_calibration( adcontrols::MassSpectrum& ms, const adcontrols::MSCalibration& calib )
{
adcontrols::segment_wrapper<> segments( ms );
if ( calib.algorithm() == adcontrols::MSCalibration::MULTITURN_NORMALIZED ) {
for ( auto& fms: segments ) {
const adcontrols::MSProperty& prop = fms.getMSProperty();
auto sp = adcontrols::MassSpectrometer::create( prop.dataInterpreterClsid() );
sp->setAcceleratorVoltage( prop.acceleratorVoltage(), prop.tDelay() );
if ( auto scanLaw = sp->scanLaw() ) {
adcontrols::ComputeMass< adcontrols::ScanLaw > mass_calculator( *scanLaw, calib );
for ( size_t i = 0; i < fms.size(); ++i ) {
double mass = mass_calculator( fms.getTime( i ), prop.mode() );
fms.setMass( i, mass );
}
fms.setCalibration( calib );
}
}
return true;
} else {
for ( auto& fms: segments )
fms.setCalibration( calib, true );
}
return false;
}
//static
bool
DataprocHandler::apply_calibration( adcontrols::MassSpectrum& ms, const adcontrols::MSCalibration& calib )
{
adcontrols::segment_wrapper<> segments( ms );
if ( calib.algorithm() == adcontrols::MSCalibration::MULTITURN_NORMALIZED ) {
for ( auto& fms: segments ) {
const adcontrols::MSProperty& prop = fms.getMSProperty();
adcontrols::ComputeMass< adcontrols::ScanLaw > mass_calculator( *fms.scanLaw(), calib );
for ( size_t i = 0; i < fms.size(); ++i ) {
double mass = mass_calculator( fms.getTime( i ), prop.mode() );
fms.setMass( i, mass );
}
fms.setCalibration( calib );
}
return true;
} else {
for ( auto& fms: segments )
fms.setCalibration( calib, true );
}
return false;
}
