Exemplo n.º 1
0
    /**
    * Set the absolute detector position of a detector
    * @param instrument :: The instrument that contains the defined detector
    * @param detID :: Detector ID
    * @param pos :: new position of Dectector
    * @param sameParent :: true if detector has same parent as previous detector set here.
    */
    void ApplyCalibration::setDetectorPosition(const Geometry::Instrument_const_sptr & instrument, int detID, V3D pos, bool /*sameParent*/ )
    {
       Geometry::IDetector_const_sptr det = instrument->getDetector(detID);
       // Then find the corresponding relative position
       boost::shared_ptr<const Geometry::IComponent> parent = det->getParent();
       if (parent)
       {
         pos -= parent->getPos();
         Quat rot = parent->getRelativeRot();
         rot.inverse();
         rot.rotate(pos);
       }
       boost::shared_ptr<const Geometry::IComponent>grandparent = parent->getParent();
       if (grandparent)
       {
         Quat rot = grandparent->getRelativeRot();
         rot.inverse();
         rot.rotate(pos);
         boost::shared_ptr<const Geometry::IComponent>greatgrandparent = grandparent->getParent();
         if (greatgrandparent) {
           Quat rot2 = greatgrandparent->getRelativeRot();
            rot2.inverse();
            rot2.rotate(pos);
         }
       }

       // Add a parameter for the new position
       m_pmap->addV3D(det.get(), "pos", pos);
    }
Exemplo n.º 2
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void CalculateDIFC::calculate(API::Progress &progress,
                              API::MatrixWorkspace_sptr &outputWs,
                              DataObjects::OffsetsWorkspace_sptr &offsetsWS,
                              double l1, double beamlineNorm,
                              Kernel::V3D &beamline, Kernel::V3D &samplePos,
                              detid2det_map &allDetectors) {
  SpecialWorkspace2D_sptr localWS =
      boost::dynamic_pointer_cast<SpecialWorkspace2D>(outputWs);

  // Now go through all
  detid2det_map::const_iterator it = allDetectors.begin();
  for (; it != allDetectors.end(); ++it) {
    Geometry::IDetector_const_sptr det = it->second;
    if ((!det->isMasked()) && (!det->isMonitor())) {
      const detid_t detID = it->first;
      double offset = 0.;
      if (offsetsWS)
        offset = offsetsWS->getValue(detID, 0.);

      double difc = Geometry::Instrument::calcConversion(
          l1, beamline, beamlineNorm, samplePos, det, offset);
      difc = 1. / difc; // calcConversion gives 1/DIFC
      localWS->setValue(detID, difc);
    }

    progress.report("Calculate DIFC");
  }
}
Exemplo n.º 3
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/** Method calculates averaged polar coordinates of the detector's group
(which may consist of one detector)
*@param spDet    -- shared pointer to the Mantid Detector
*@param Observer -- sample position or the centre of the polar system of
coordinates to calculate detector's parameters.

*@param Detector  -- return Detector class containing averaged polar coordinates
of the detector or detector's group in
                     spherical coordinate system with centre at Observer
*/
void FindDetectorsPar::calcDetPar(const Geometry::IDetector_const_sptr &spDet,
                                  const Kernel::V3D &Observer,
                                  DetParameters &Detector) {

  // get number of basic detectors within the composit detector
  size_t nDetectors = spDet->nDets();
  // define summator
  AvrgDetector detSum;
  // do we want spherical or linear box sizes?
  detSum.setUseSpherical(!m_SizesAreLinear);

  if (nDetectors == 1) {
    detSum.addDetInfo(spDet, Observer);
  } else {
    // access contributing detectors;
    Geometry::DetectorGroup_const_sptr spDetGroup =
        boost::dynamic_pointer_cast<const Geometry::DetectorGroup>(spDet);
    if (!spDetGroup) {
      g_log.error() << "calc_cylDetPar: can not downcast IDetector_sptr to "
                       "detector group for det->ID: " << spDet->getID()
                    << std::endl;
      throw(std::bad_cast());
    }
    auto detectors = spDetGroup->getDetectors();
    auto it = detectors.begin();
    auto it_end = detectors.end();
    for (; it != it_end; it++) {
      detSum.addDetInfo(*it, Observer);
    }
  }
  // calculate averages and return the detector parameters
  detSum.returnAvrgDetPar(Detector);
}
Exemplo n.º 4
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/** Retrieves the detector postion for a given spectrum
 *  @param index ::    The workspace index of the spectrum
 *  @param l1 ::       Returns the source-sample distance
 *  @param l2 ::       Returns the sample-detector distance
 *  @param twoTheta :: Returns the detector's scattering angle
 */
void RemoveBins::calculateDetectorPosition(const int& index, double& l1, double& l2, double& twoTheta)
{
  // Get a pointer to the instrument contained in the workspace
  Geometry::Instrument_const_sptr instrument = m_inputWorkspace->getInstrument();
  // Get the distance between the source and the sample (assume in metres)
  Geometry::IObjComponent_const_sptr sample = instrument->getSample();
  // Check for valid instrument
  if (sample == NULL)
  {
    throw Exception::InstrumentDefinitionError("Instrument not sufficiently defined: failed to get sample");
  }

  l1 = instrument->getSource()->getDistance(*sample);
  Geometry::IDetector_const_sptr det = m_inputWorkspace->getDetector(index);
  // Get the sample-detector distance for this detector (in metres)
  if ( ! det->isMonitor() )
  {
    l2 = det->getDistance(*sample);
    // The scattering angle for this detector (in radians).
    twoTheta = m_inputWorkspace->detectorTwoTheta(det);
  }
  else  // If this is a monitor then make l1+l2 = source-detector distance and twoTheta=0
  {
    l2 = det->getDistance(*(instrument->getSource()));
    l2 = l2 - l1;
    twoTheta = 0.0;
  }
  g_log.debug() << "Detector for index " << index << " has L1+L2=" << l1+l2 << " & 2theta= " << twoTheta << std::endl;
  return;
}
Exemplo n.º 5
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void CalculateDIFC::calculate() {
  Instrument_const_sptr instrument = m_inputWS->getInstrument();

  SpecialWorkspace2D_sptr localWS =
      boost::dynamic_pointer_cast<SpecialWorkspace2D>(m_outputWS);

  double l1;
  Kernel::V3D beamline, samplePos;
  double beamline_norm;
  instrument->getInstrumentParameters(l1, beamline, beamline_norm, samplePos);

  // To get all the detector ID's
  detid2det_map allDetectors;
  instrument->getDetectors(allDetectors);

  // Now go through all
  detid2det_map::const_iterator it = allDetectors.begin();
  for (; it != allDetectors.end(); ++it) {
    Geometry::IDetector_const_sptr det = it->second;
    if ((!det->isMasked()) && (!det->isMonitor())) {
      const detid_t detID = it->first;
      double offset = 0.;
      if (m_offsetsWS)
        offset = m_offsetsWS->getValue(detID, 0.);

      double difc = Geometry::Instrument::calcConversion(
          l1, beamline, beamline_norm, samplePos, det, offset);
      difc = 1. / difc; // calcConversion gives 1/DIFC
      localWS->setValue(detID, difc);
    }
  }

}
Exemplo n.º 6
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void FindDetectorsPar::populate_values_from_file(
    const API::MatrixWorkspace_sptr &inputWS) {
  size_t nHist = inputWS->getNumberHistograms();

  if (this->current_ASCII_file.Type == PAR_type) {
    // in this case data in azimuthal width and polar width are in fact real
    // sizes in meters; have to transform it in into angular values
    for (size_t i = 0; i < nHist; i++) {
      azimuthalWidth[i] =
          atan2(azimuthalWidth[i], secondaryFlightpath[i]) * rad2deg;
      polarWidth[i] = atan2(polarWidth[i], secondaryFlightpath[i]) * rad2deg;
    }
    m_SizesAreLinear = false;
  } else {

    Geometry::IComponent_const_sptr sample =
        inputWS->getInstrument()->getSample();
    secondaryFlightpath.resize(nHist);
    // Loop over the spectra
    for (size_t i = 0; i < nHist; i++) {
      Geometry::IDetector_const_sptr spDet;
      try {
        spDet = inputWS->getDetector(i);
      } catch (Kernel::Exception::NotFoundError &) {
        continue;
      }
      // Check that we aren't writing a monitor...
      if (spDet->isMonitor())
        continue;
      /// this is the only value, which is not defined in phx file, so we
      /// calculate it
      secondaryFlightpath[i] = spDet->getDistance(*sample);
    }
  }
}
Exemplo n.º 7
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/** Makes sure that the input properties are set correctly
 *  @param inputWorkspace The input workspace
 *  @throw std::runtime_error If the properties are invalid
 */
void NormaliseToMonitor::checkProperties(API::MatrixWorkspace_sptr inputWorkspace)
{

   // Check where the monitor spectrum should come from
  Property* monSpec = getProperty("MonitorSpectrum");
  Property* monWS   = getProperty("MonitorWorkspace");
  Property* monID   = getProperty("MonitorID");
  // Is the monitor spectrum within the main input workspace
  const bool inWS = !monSpec->isDefault();
  // Or is it in a separate workspace
  bool sepWS = !monWS->isDefault();
  // or monitor ID
  bool monIDs = !monID->isDefault();  
  // something has to be set
  if ( !inWS && !sepWS && !monIDs)
  {
    const std::string mess("Neither the MonitorSpectrum, nor the MonitorID or the MonitorWorkspace property has been set");
    g_log.error()<<mess<<std::endl;
    throw std::runtime_error(mess);
  }
  // One and only one of these properties should have been set
  // input from separate workspace is owerwritten by monitor spectrum
  if ( inWS && sepWS ){
      g_log.information("Both input workspace MonitorSpectrum number and monitor workspace are specified. Ignoring Monitor Workspace");
      sepWS = false;
  }
  // input from detector ID is rejected in favour of monitor sp 
  if ( inWS && monIDs ){
      g_log.information("Both input workspace MonitorSpectrum number and detector ID are specified. Ignoring Detector ID");
      monIDs = false;
  }
  // separate ws takes over detectorID (this logic is dublicated within  getInWSMonitorSpectrum)
  if ( sepWS && monIDs ){
      g_log.information("Both input MonitorWorkspace and detector ID are specified. Ignoring Detector ID");
  }



  // Do a check for common binning and store
  m_commonBins = API::WorkspaceHelpers::commonBoundaries(inputWorkspace);

  
   int spec_num(-1);
  // Check the monitor spectrum or workspace and extract into new workspace
  m_monitor = sepWS ? this->getMonitorWorkspace(inputWorkspace,spec_num) : this->getInWSMonitorSpectrum(inputWorkspace,spec_num) ;

  // Check that the 'monitor' spectrum actually relates to a monitor - warn if not
  try {
    Geometry::IDetector_const_sptr mon = m_monitor->getDetector(0);
    if ( !mon->isMonitor() )
    {
      g_log.warning()<<"The spectrum N: "<<spec_num<<" in MonitorWorkspace does not refer to a monitor.\n"
                     <<"Continuing with normalisation regardless.";
    }
  } catch (Kernel::Exception::NotFoundError &) {
    g_log.warning("Unable to check if the spectrum provided relates to a monitor - "
                  "the instrument is not fully specified.\n"
                  "Continuing with normalisation regardless.");
  }
}
Exemplo n.º 8
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/** Calculates the total flightpath for the given detector.
 *  This is L1+L2 normally, but is the source-detector distance for a monitor.
 *  @param spectrum ::  The workspace index
 *  @param L1 ::        The primary flightpath
 *  @param isMonitor :: Output: true is this detector is a monitor
 *  @return The flightpath (Ld) for the detector linked to spectrum
 *  @throw Kernel::Exception::InstrumentDefinitionError if the detector position
 * can't be obtained
 */
double UnwrapMonitor::calculateFlightpath(const int &spectrum, const double &L1,
                                          bool &isMonitor) const {
  double Ld = -1.0;
  try {
    // Get the detector object for this histogram
    Geometry::IDetector_const_sptr det = m_inputWS->getDetector(spectrum);
    // Get the sample-detector distance for this detector (or source-detector if
    // a monitor)
    // This is the total flightpath
    isMonitor = det->isMonitor();
    // Get the L2 distance if this detector is not a monitor
    if (!isMonitor) {
      double L2 = det->getDistance(*(m_inputWS->getInstrument()->getSample()));
      Ld = L1 + L2;
    }
    // If it is a monitor, then the flightpath is the distance to the source
    else {
      Ld = det->getDistance(*(m_inputWS->getInstrument()->getSource()));
    }
  } catch (Exception::NotFoundError &) {
    // If the detector information is missing, return a negative number
  }

  return Ld;
}
Exemplo n.º 9
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/**
 * Corrects a spectra for the detector efficiency calculated from detector
 * information. Gets the detector information and uses this to calculate its
 * efficiency
 *  @param spectraIndex :: index of the spectrum to get the efficiency for
 *  @throw invalid_argument if the shape of a detector is isn't a cylinder
 *  aligned along one axis
 *  @throw runtime_error if the SpectraDetectorMap has not been filled
 *  @throw NotFoundError if the detector or its gas pressure or wall thickness
 *  were not found
 */
void He3TubeEfficiency::correctForEfficiency(std::size_t spectraIndex)
{
  Geometry::IDetector_const_sptr det = this->inputWS->getDetector(spectraIndex);
  if( det->isMonitor() || det->isMasked() )
  {
    return;
  }

  const double exp_constant = this->calculateExponential(spectraIndex, det);
  const double scale = this->getProperty("ScaleFactor");

  Mantid::MantidVec &yout = this->outputWS->dataY(spectraIndex);
  Mantid::MantidVec &eout = this->outputWS->dataE(spectraIndex);
  // Need the original values so this is not a reference
  const Mantid::MantidVec yValues = this->inputWS->readY(spectraIndex);
  const Mantid::MantidVec eValues = this->inputWS->readE(spectraIndex);

  std::vector<double>::const_iterator yinItr = yValues.begin();
  std::vector<double>::const_iterator einItr = eValues.begin();
  Mantid::MantidVec::const_iterator xItr = this->inputWS->readX(spectraIndex).begin();
  Mantid::MantidVec::iterator youtItr = yout.begin();
  Mantid::MantidVec::iterator eoutItr = eout.begin();

  for( ; youtItr != yout.end(); ++youtItr, ++eoutItr)
  {
    const double wavelength = (*xItr + *(xItr + 1)) / 2.0;
    const double effcorr = this->detectorEfficiency(exp_constant * wavelength, scale);
    *youtItr = (*yinItr) * effcorr;
    *eoutItr = (*einItr) * effcorr;
    ++yinItr; ++einItr;
    ++xItr;
  }

  return;
}
Exemplo n.º 10
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/** Purpose: Process mask workspace
 *  Requirement: m_maskWS is not None
 *  Guarantees: an array will be set up for masked detectors
 * @brief IntegratePeaksCWSD::processMaskWorkspace
 * @param maskws
 */
std::vector<detid_t> IntegratePeaksCWSD::processMaskWorkspace(
    DataObjects::MaskWorkspace_const_sptr maskws) {
  std::vector<detid_t> vecMaskedDetID;

  // Add the detector IDs of all masked detector to a vector
  size_t numspec = maskws->getNumberHistograms();
  for (size_t iws = 0; iws < numspec; ++iws) {
    Geometry::IDetector_const_sptr detector = maskws->getDetector(iws);
    const MantidVec &vecY = maskws->readY(iws);
    if (vecY[0] > 0.1) {
      // vecY[] > 0 is masked.  det->isMasked() may not be reliable.
      detid_t detid = detector->getID();
      vecMaskedDetID.push_back(detid);
    }
  }

  // Sort the vector for future lookup
  if (vecMaskedDetID.size() > 1)
    std::sort(vecMaskedDetID.begin(), vecMaskedDetID.end());

  g_log.warning() << "[DB] There are " << vecMaskedDetID.size()
                  << " detectors masked."
                  << "\n";

  return vecMaskedDetID;
}
Exemplo n.º 11
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  int LoadIsawPeaks::findPixelID(Instrument_const_sptr inst, std::string bankName, int col, int row)
  {
	  boost::shared_ptr<const IComponent> parent = inst->getComponentByName(bankName);
	  if (parent->type().compare("RectangularDetector") == 0)
	  {
          boost::shared_ptr<const RectangularDetector> RDet = boost::dynamic_pointer_cast<
					const RectangularDetector>(parent);

		  boost::shared_ptr<Detector> pixel = RDet->getAtXY(col, row);
		  return pixel->getID();
	  }
	  else
	  {
          std::vector<Geometry::IComponent_const_sptr> children;
          boost::shared_ptr<const Geometry::ICompAssembly> asmb = boost::dynamic_pointer_cast<const Geometry::ICompAssembly>(parent);
          asmb->getChildren(children, false);
          int col0 = (col%2==0 ? col/2+75 : (col-1)/2);
          boost::shared_ptr<const Geometry::ICompAssembly> asmb2 = boost::dynamic_pointer_cast<const Geometry::ICompAssembly>(children[col0]);
          std::vector<Geometry::IComponent_const_sptr> grandchildren;
          asmb2->getChildren(grandchildren,false);
          Geometry::IComponent_const_sptr first = grandchildren[row-1];
          Geometry::IDetector_const_sptr det = boost::dynamic_pointer_cast<const Geometry::IDetector>(first);
		  return det->getID();
	  }
  }
Exemplo n.º 12
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/** Extract a component's detectors and return it within detectors array
 *  It is a generalized version of bankToDetectors()
 *
 * @param componentnames -- vector of component names to process
 * @param detectors      -- vector of detector ids, which belongs to components
 *provided as input.
 */
void LoadMask::componentToDetectors(
    const std::vector<std::string> &componentnames,
    std::vector<detid_t> &detectors) {
  Geometry::Instrument_const_sptr minstrument = m_maskWS->getInstrument();

  for (auto &componentname : componentnames) {
    g_log.debug() << "Component name = " << componentname << '\n';

    // a) get component
    Geometry::IComponent_const_sptr component =
        minstrument->getComponentByName(componentname);
    if (component)
      g_log.debug() << "Component ID = " << component->getComponentID() << '\n';
    else {
      // A non-exiting component.  Ignore
      g_log.warning() << "Component " << componentname << " does not exist!\n";
      continue;
    }

    // b) component -> component assembly --> children (more than detectors)
    boost::shared_ptr<const Geometry::ICompAssembly> asmb =
        boost::dynamic_pointer_cast<const Geometry::ICompAssembly>(component);
    std::vector<Geometry::IComponent_const_sptr> children;
    asmb->getChildren(children, true);

    g_log.debug() << "Number of Children = " << children.size() << '\n';

    size_t numdets(0);
    detid_t id_min(std::numeric_limits<Mantid::detid_t>::max());
    detid_t id_max(0);

    for (const auto &child : children) {
      // c) convert component to detector
      Geometry::IDetector_const_sptr det =
          boost::dynamic_pointer_cast<const Geometry::IDetector>(child);

      if (det) {
        detid_t detid = det->getID();
        detectors.push_back(detid);
        numdets++;
        if (detid < id_min)
          id_min = detid;
        if (detid > id_max)
          id_max = detid;
      }
    }

    g_log.debug() << "Number of Detectors in Children = " << numdets
                  << "  Range = " << id_min << ", " << id_max << '\n';
  } // for component
}
Exemplo n.º 13
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/** Update the shape cache if necessary
* @param det :: a pointer to the detector to query
* @param detRadius :: An output parameter that contains the detector radius
* @param detAxis :: An output parameter that contains the detector axis vector
*/
void DetectorEfficiencyCor::getDetectorGeometry(const Geometry::IDetector_const_sptr & det, double & detRadius, V3D & detAxis)
{
  boost::shared_ptr<const Object> shape_sptr = det->shape();
  if(!shape_sptr->hasValidShape())
  {
    throw Exception::NotFoundError("Shape", "Detector has no shape");
  }

  std::map<const Geometry::Object *, std::pair<double, Kernel::V3D> >::const_iterator it = 
    m_shapeCache.find(shape_sptr.get());
  if( it == m_shapeCache.end() )
  {
    double xDist = distToSurface( V3D(DIST_TO_UNIVERSE_EDGE, 0, 0), shape_sptr.get() );
    double zDist = distToSurface( V3D(0, 0, DIST_TO_UNIVERSE_EDGE), shape_sptr.get() );
    if ( std::abs(zDist - xDist) < 1e-8 )
    {
      detRadius = zDist/2.0;
      detAxis = V3D(0,1,0);
      // assume radi in z and x and the axis is in the y
      PARALLEL_CRITICAL(deteff_shapecachea)
      {
        m_shapeCache.insert(std::pair<const Object *,std::pair<double, V3D> >(shape_sptr.get(), std::pair<double, V3D>(detRadius, detAxis)));
      }
      return;
    }
Exemplo n.º 14
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/**
 * Update the shape cache if necessary
 * @param det :: a pointer to the detector to query
 * @param detRadius :: An output parameter that contains the detector radius
 * @param detAxis :: An output parameter that contains the detector axis vector
 */
void He3TubeEfficiency::getDetectorGeometry(\
    Geometry::IDetector_const_sptr det,
    double & detRadius, Kernel::V3D & detAxis)
{
  boost::shared_ptr<const Geometry::Object> shape_sptr = det->shape();
  std::map<const Geometry::Object *, std::pair<double, Kernel::V3D> >::const_iterator it =
    this->shapeCache.find(shape_sptr.get());
  if( it == this->shapeCache.end() )
  {
    double xDist = distToSurface( Kernel::V3D(DIST_TO_UNIVERSE_EDGE, 0, 0),
        shape_sptr.get() );
    double zDist = distToSurface( Kernel::V3D(0, 0, DIST_TO_UNIVERSE_EDGE),
        shape_sptr.get() );
    if ( std::abs(zDist - xDist) < 1e-8 )
    {
      detRadius = zDist / 2.0;
      detAxis = Kernel::V3D(0, 1, 0);
      // assume radii in z and x and the axis is in the y
      PARALLEL_CRITICAL(deteff_shapecachea)
      {
        this->shapeCache.insert(std::pair<const Geometry::Object *,
            std::pair<double, Kernel::V3D> >(shape_sptr.get(),
                std::pair<double, Kernel::V3D>(detRadius, detAxis)));
      }
      return;
    }
Exemplo n.º 15
0
/// helper function to preprocess the detectors directions
void 
ConvertToQ3DdE::process_detectors_positions(const DataObjects::Workspace2D_const_sptr inputWS)
{

    const size_t nHist = inputWS->getNumberHistograms();

    det_loc.det_dir.resize(nHist);
    det_loc.det_id.resize(nHist);
     // Loop over the spectra
   size_t ic(0);
   for (size_t i = 0; i < nHist; i++){

     Geometry::IDetector_const_sptr spDet;
     try{
        spDet= inputWS->getDetector(i);
     }catch(Kernel::Exception::NotFoundError &){
        continue;
     }
 
    // Check that we aren't dealing with monitor...
    if (spDet->isMonitor())continue;   

     det_loc.det_id[ic] = spDet->getID();
    // dist     =  spDet->getDistance(*sample);
     double polar    =  inputWS->detectorTwoTheta(spDet);
     double azim     =  spDet->getPhi();    

     double sPhi=sin(polar);
     double ez = cos(polar);
     double ex = sPhi*cos(azim);
     double ey = sPhi*sin(azim);
 
     det_loc.det_dir[ic].setX(ex);
     det_loc.det_dir[ic].setY(ey);
     det_loc.det_dir[ic].setZ(ez);

     ic++;
   }
   // 
   if(ic<nHist){
       det_loc.det_dir.resize(ic);
       det_loc.det_id.resize(ic);
   }
}
    /**
     * Set the new detector position given the r,theta and phi.
     * @param det :: A pointer to the detector
     * @param l2 :: A single l2
     * @param theta :: A single theta
     * @param phi :: A single phi
     */
    void UpdateInstrumentFromFile::setDetectorPosition(const Geometry::IDetector_const_sptr & det, const float l2,
                                                       const float theta, const float phi)
    {
      if( m_ignoreMonitors && det->isMonitor() ) return;

      Geometry::ParameterMap & pmap = m_workspace->instrumentParameters();
      Kernel::V3D pos;
      if (!m_ignorePhi)
      {
        pos.spherical(l2, theta, phi);
      }
      else
      {
        double r,t,p;
        det->getPos().getSpherical(r,t,p);
        pos.spherical(l2, theta, p);
      }
      Geometry::ComponentHelper::moveComponent(*det, pmap, pos, Geometry::ComponentHelper::Absolute);
    }
Exemplo n.º 17
0
std::pair<double, double> LoadILLSANS::calculateQMaxQMin() {
  double min = std::numeric_limits<double>::max(),
         max = std::numeric_limits<double>::min();
  g_log.debug("Calculating Qmin Qmax...");
  std::size_t nHist = m_localWorkspace->getNumberHistograms();
  for (std::size_t i = 0; i < nHist; ++i) {
    Geometry::IDetector_const_sptr det = m_localWorkspace->getDetector(i);
    if (!det->isMonitor()) {
      const MantidVec &lambdaBinning = m_localWorkspace->readX(i);
      Kernel::V3D detPos = det->getPos();
      double r, theta, phi;
      detPos.getSpherical(r, theta, phi);
      double v1 = calculateQ(*(lambdaBinning.begin()), theta);
      double v2 = calculateQ(*(lambdaBinning.end() - 1), theta);
      // std::cout << "i=" << i << " theta="<<theta << " lambda_i=" <<
      // *(lambdaBinning.begin()) << " lambda_f=" << *(lambdaBinning.end()-1) <<
      // " v1=" << v1 << " v2=" << v2 << '\n';
      if (i == 0) {
        min = v1;
        max = v1;
      }
      if (v1 < min) {
        min = v1;
      }
      if (v2 < min) {
        min = v2;
      }
      if (v1 > max) {
        max = v1;
      }
      if (v2 > max) {
        max = v2;
      }
    } else
      g_log.debug() << "Detector " << i << " is a Monitor : " << det->getID()
                    << '\n';
  }

  g_log.debug() << "Calculating Qmin Qmax. Done : [" << min << "," << max
                << "]\n";

  return std::pair<double, double>(min, max);
}
Exemplo n.º 18
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    /**
     *
     * @param pmap A reference to the ParameterMap instance to update
     * @param det A pointer to the detector whose parameters should be updated
     * @param l2 The new l2 value
     * @param theta The new theta value
     * @param phi The new phi value
     * @param delay The new delay time
     * @param pressure The new pressure value
     * @param thickness The new thickness value
     */
    void LoadDetectorInfo::updateParameterMap(Geometry::ParameterMap & pmap,
                                              const Geometry::IDetector_const_sptr & det,
                                              const double l2, const double theta, const double phi,
                                              const double delay, const double pressure,
                                              const double thickness) const
    {
      // store detector params that are different to instrument level
      if(fabs(delay - m_instDelta) > 1e-06) pmap.addDouble(det->getComponentID(), DELAY_PARAM, delay);
      if(fabs(pressure - m_instPressure) > 1e-06) pmap.addDouble(det->getComponentID(), PRESSURE_PARAM, pressure);
      if(fabs(thickness - m_instThickness) > 1e-06) pmap.addDouble(det->getComponentID(), THICKNESS_PARAM, thickness);

      // move
      if(m_moveDets)
      {
        V3D newPos;
        newPos.spherical(l2, theta, phi);
        // The sample position may not be at 0,0,0
        newPos += m_samplePos;
        ComponentHelper::moveComponent(*det, pmap, newPos, ComponentHelper::Absolute);
      }
    }
Exemplo n.º 19
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/**
 * This function calculates the exponential contribution to the He3 tube
 * efficiency.
 * @param spectraIndex :: the current index to calculate
 * @param idet :: the current detector pointer
 * @throw out_of_range if twice tube thickness is greater than tube diameter
 * @return the exponential contribution for the given detector
 */
double He3TubeEfficiency::calculateExponential(std::size_t spectraIndex, Geometry::IDetector_const_sptr idet)
{
  // Get the parameters for the current associated tube
  double pressure = this->getParameter("TubePressure", spectraIndex,
      "tube_pressure", idet);
  double tubethickness = this->getParameter("TubeThickness", spectraIndex,
      "tube_thickness", idet);
  double temperature = this->getParameter("TubeTemperature", spectraIndex,
      "tube_temperature", idet);

  double detRadius(0.0);
  Kernel::V3D detAxis;
  this->getDetectorGeometry(idet, detRadius, detAxis);
  double detDiameter = 2.0 * detRadius;
  double twiceTubeThickness = 2.0 * tubethickness;

  // now get the sin of the angle, it's the magnitude of the cross product of
  // unit vector along the detector tube axis and a unit vector directed from
  // the sample to the detector center
  Kernel::V3D vectorFromSample = idet->getPos() - this->samplePos;
  vectorFromSample.normalize();
  Kernel::Quat rot = idet->getRotation();
  // rotate the original cylinder object axis to get the detector axis in the
  // actual instrument
  rot.rotate(detAxis);
  detAxis.normalize();
  // Scalar product is quicker than cross product
  double cosTheta = detAxis.scalar_prod(vectorFromSample);
  double sinTheta = std::sqrt(1.0 - cosTheta * cosTheta);

  const double straight_path = detDiameter - twiceTubeThickness;
  if (std::fabs(straight_path - 0.0) < TOL)
  {
    throw std::out_of_range("Twice tube thickness cannot be greater than "\
        "or equal to the tube diameter");
  }

  const double pathlength = straight_path / sinTheta;
  return EXP_SCALAR_CONST * (pressure / temperature) * pathlength;
}
Exemplo n.º 20
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/** Method updates the column, which describes if current detector/spectra is
   masked
    It is used if one tries to process multiple workspaces obtained from a
   series of experiments  where the masked detectors can change */
void PreprocessDetectorsToMD::updateMasksState(
    const API::MatrixWorkspace_const_sptr &inputWS,
    DataObjects::TableWorkspace_sptr &targWS) {
  int *pMasksArray = targWS->getColDataArray<int>("detMask");
  if (!pMasksArray)
    throw std::invalid_argument(
        "target workspace " + targWS->getName() +
        " does not have defined masks column to update");

  size_t nHist = targWS->rowCount();
  const size_t nRows = inputWS->getNumberHistograms();
  if (nHist != nRows)
    throw std::invalid_argument(
        " source workspace " + inputWS->getName() + " and target workspace " +
        targWS->getName() +
        " are inconsistent as have different numner of detectors");

  uint32_t liveDetectorsCount(0);
  for (size_t i = 0; i < nHist; i++) {
    // get detector or detector group which corresponds to the spectra i
    Geometry::IDetector_const_sptr spDet;
    try {
      spDet = inputWS->getDetector(i);
    } catch (Kernel::Exception::NotFoundError &) {
      continue;
    }

    // Check that we aren't dealing with monitor...
    if (spDet->isMonitor())
      continue;

    // if masked detectors state is not used, masked detectors just ignored;
    bool maskDetector = spDet->isMasked();
    *(pMasksArray + liveDetectorsCount) = maskDetector ? 1 : 0;

    liveDetectorsCount++;
  }
}
Exemplo n.º 21
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/**
 * If the InstrumentParameter property is set then it attempts to retrieve the parameter
 * from the component, else it returns the value of the Factor property
 * @param inputWS A pointer to the input workspace
 * @param index The current index to inspect
 * @return Value for the scale factor
 */
double ScaleX::getScaleFactor(const API::MatrixWorkspace_const_sptr & inputWS, const size_t index)
{
  if(m_parname.empty()) return m_algFactor;

  // Try and get factor from component. If we see a DetectorGroup use this will use the first component
  Geometry::IDetector_const_sptr det;
  auto inst = inputWS->getInstrument();

  auto *spec = inputWS->getSpectrum(index);
  const auto & ids = spec->getDetectorIDs();
  const size_t ndets(ids.size());
  if(ndets > 0)
  {
    try
    {
      det = inst->getDetector(*ids.begin());
    }
    catch(Exception::NotFoundError&)
    {
      return 0.0;
    }
  }
  else return 0.0;

  const auto & pmap = inputWS->constInstrumentParameters();
  auto par = pmap.getRecursive(det->getComponentID(), m_parname);
  if(par)
  {
    if(!m_combine) return par->value<double>();
    else return m_binOp(m_algFactor,par->value<double>());
  }
  else
  {
    std::ostringstream os;
    os << "Spectrum at index '" << index << "' has no parameter named '" << m_parname << "'\n";
    throw std::runtime_error(os.str());
  }
}
Exemplo n.º 22
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/**Calculates the distance a neutron coming from the sample will have deviated
* from a
*  straight tragetory before hitting a detector. If calling this function many
* times
*  for the same detector you can call this function once, with waveLength=1, and
* use
*  the fact drop is proportional to wave length squared .This function has no
* knowledge
*  of which axis is vertical for a given instrument
*  @param ws :: workspace
*  @param det :: the detector that the neutron entered
*  @param waveLength :: the neutrons wave length in meters
*  @param extraLength :: additional length
*  @return the deviation in meters
*/
double GravitySANSHelper::gravitationalDrop(API::MatrixWorkspace_const_sptr ws,
                                            Geometry::IDetector_const_sptr det,
                                            const double waveLength,
                                            const double extraLength) const {
  using namespace PhysicalConstants;
  /// Pre-factor in gravity calculation: gm^2/2h^2
  static const double gm2_OVER_2h2 =
      g * NeutronMass * NeutronMass / (2.0 * h * h);

  const V3D samplePos = ws->getInstrument()->getSample()->getPos();
  const double pathLength = det->getPos().distance(samplePos) + extraLength;
  // Want L2 (sample-pixel distance) squared, times the prefactor g^2/h^2
  const double L2 = gm2_OVER_2h2 * std::pow(pathLength, 2);

  return waveLength * waveLength * L2;
}
Exemplo n.º 23
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 /**
  * Return the efixed for this detector
  * @param det :: A pointer to a detector object
  * @return The value of efixed
  */
 double SofQW3::getEFixed(Geometry::IDetector_const_sptr det) const
 {
   double efixed(0.0);
   if( m_emode == 1 ) //Direct
   {
     efixed = m_efixed;
   }
   else // Indirect
   {
     if( m_efixedGiven ) efixed = m_efixed; // user provided a value
     else
     {
       std::vector<double> param = det->getNumberParameter("EFixed");
       if( param.empty() ) throw std::runtime_error("Cannot find EFixed parameter for component \"" + det->getName()
                                                    + "\". This is required in indirect mode. Please check the IDF contains these values.");
       efixed = param[0];
     }
   }
   return efixed;
 }
/**Calculates the distance a neutron coming from the sample will have deviated
* from a
*  straight tragetory before hitting a detector. If calling this function many
* times
*  for the same detector you can call this function once, with waveLength=1, and
* use
*  the fact drop is proportional to wave length squared .This function has no
* knowledge
*  of which axis is vertical for a given instrument
*  @param ws :: workspace
*  @param det :: the detector that the neutron entered
*  @param waveLength :: the neutrons wave length in meters
*  @param extraLength :: additional length
*  @return the deviation in meters
*/
double GravitySANSHelper::gravitationalDrop(API::MatrixWorkspace_const_sptr ws,
        Geometry::IDetector_const_sptr det,
        const double waveLength,
        const double extraLength) const {
    using namespace PhysicalConstants;
    /// Pre-factor in gravity calculation: gm^2/2h^2
    static const double gm2_OVER_2h2 =
        g * NeutronMass * NeutronMass / (2.0 * h * h);

    const V3D samplePos = ws->getInstrument()->getSample()->getPos();

    // Perform a path length correction if an Lextra is specified.
    // The correction is Lcorr^2 = (L + Lextra)^2 -(LExtra)^2
    const auto pathLengthWithExtraLength =
        det->getPos().distance(samplePos) + extraLength;
    const auto pathLengthSquared =
        std::pow(pathLengthWithExtraLength, 2) - std::pow(extraLength, 2);

    // Want L2 (sample-pixel distance) squared, times the prefactor g^2/h^2
    const double L2 = gm2_OVER_2h2 * pathLengthSquared;

    return waveLength * waveLength * L2;
}
Exemplo n.º 25
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/**
*  Move the user selected spectra in the input workspace into groups in the output workspace
*  @param inputWS :: user selected input workspace for the algorithm
*  @param outputWS :: user selected output workspace for the algorithm
*  @param prog4Copy :: the amount of algorithm progress to attribute to moving a single spectra
*  @return number of new grouped spectra
*/
size_t GroupDetectors2::formGroupsEvent( DataObjects::EventWorkspace_const_sptr inputWS, DataObjects::EventWorkspace_sptr  outputWS,
            const double prog4Copy)
{
  // get "Behaviour" string
  const std::string behaviour = getProperty("Behaviour");
  int bhv = 0;
  if ( behaviour == "Average" ) bhv = 1;

  API::MatrixWorkspace_sptr beh = API::WorkspaceFactory::Instance().create(
    "Workspace2D", static_cast<int>(m_GroupSpecInds.size()), 1, 1);

  g_log.debug() << name() << ": Preparing to group spectra into " << m_GroupSpecInds.size() << " groups\n";


  // where we are copying spectra to, we start copying to the start of the output workspace
  size_t outIndex = 0;
  // Only used for averaging behaviour. We may have a 1:1 map where a Divide would be waste as it would be just dividing by 1
  bool requireDivide(false);
  for ( storage_map::const_iterator it = m_GroupSpecInds.begin(); it != m_GroupSpecInds.end() ; ++it )
  {
    // This is the grouped spectrum
    EventList & outEL = outputWS->getEventList(outIndex);

    // The spectrum number of the group is the key
    outEL.setSpectrumNo(it->first);
    // Start fresh with no detector IDs
    outEL.clearDetectorIDs();

    // the Y values and errors from spectra being grouped are combined in the output spectrum
    // Keep track of number of detectors required for masking
    size_t nonMaskedSpectra(0);
    beh->dataX(outIndex)[0] = 0.0;
    beh->dataE(outIndex)[0] = 0.0;
    for( std::vector<size_t>::const_iterator wsIter = it->second.begin(); wsIter != it->second.end(); ++wsIter)
    {
      const size_t originalWI = *wsIter;

      const EventList & fromEL=inputWS->getEventList(originalWI);
      //Add the event lists with the operator
      outEL += fromEL;


      // detectors to add to the output spectrum
      outEL.addDetectorIDs(fromEL.getDetectorIDs() );
      try
      {
        Geometry::IDetector_const_sptr det = inputWS->getDetector(originalWI);
        if( !det->isMasked() ) ++nonMaskedSpectra;
      }
      catch(Exception::NotFoundError&)
      {
        // If a detector cannot be found, it cannot be masked
        ++nonMaskedSpectra;
      }
    }
    if( nonMaskedSpectra == 0 ) ++nonMaskedSpectra; // Avoid possible divide by zero
    if(!requireDivide) requireDivide = (nonMaskedSpectra > 1);
    beh->dataY(outIndex)[0] = static_cast<double>(nonMaskedSpectra);

    // make regular progress reports and check for cancelling the algorithm
    if ( outIndex % INTERVAL == 0 )
    {
      m_FracCompl += INTERVAL*prog4Copy;
      if ( m_FracCompl > 1.0 )
        m_FracCompl = 1.0;
      progress(m_FracCompl);
      interruption_point();
    }
    outIndex ++;
  }

  // Refresh the spectraDetectorMap
  outputWS->doneAddingEventLists();

  if ( bhv == 1 && requireDivide )
  {
    g_log.debug() << "Running Divide algorithm to perform averaging.\n";
    Mantid::API::IAlgorithm_sptr divide = createChildAlgorithm("Divide");
    divide->initialize();
    divide->setProperty<API::MatrixWorkspace_sptr>("LHSWorkspace", outputWS);
    divide->setProperty<API::MatrixWorkspace_sptr>("RHSWorkspace", beh);
    divide->setProperty<API::MatrixWorkspace_sptr>("OutputWorkspace", outputWS);
    divide->execute();
  }


  g_log.debug() << name() << " created " << outIndex << " new grouped spectra\n";
  return outIndex;
}
Exemplo n.º 26
0
/**
*  Move the user selected spectra in the input workspace into groups in the output workspace
*  @param inputWS :: user selected input workspace for the algorithm
*  @param outputWS :: user selected output workspace for the algorithm
*  @param prog4Copy :: the amount of algorithm progress to attribute to moving a single spectra
*  @return number of new grouped spectra
*/
size_t GroupDetectors2::formGroups( API::MatrixWorkspace_const_sptr inputWS, API::MatrixWorkspace_sptr outputWS, 
            const double prog4Copy)
{
  // get "Behaviour" string
  const std::string behaviour = getProperty("Behaviour");
  int bhv = 0;
  if ( behaviour == "Average" ) bhv = 1;

  API::MatrixWorkspace_sptr beh = API::WorkspaceFactory::Instance().create(
    "Workspace2D", static_cast<int>(m_GroupSpecInds.size()), 1, 1);

  g_log.debug() << name() << ": Preparing to group spectra into " << m_GroupSpecInds.size() << " groups\n";

  // where we are copying spectra to, we start copying to the start of the output workspace
  size_t outIndex = 0;
  // Only used for averaging behaviour. We may have a 1:1 map where a Divide would be waste as it would be just dividing by 1
  bool requireDivide(false);
  for ( storage_map::const_iterator it = m_GroupSpecInds.begin(); it != m_GroupSpecInds.end() ; ++it )
  {
    // This is the grouped spectrum
    ISpectrum * outSpec = outputWS->getSpectrum(outIndex);

    // The spectrum number of the group is the key
    outSpec->setSpectrumNo(it->first);
    // Start fresh with no detector IDs
    outSpec->clearDetectorIDs();

    // Copy over X data from first spectrum, the bin boundaries for all spectra are assumed to be the same here
    outSpec->dataX() = inputWS->readX(0);

    // the Y values and errors from spectra being grouped are combined in the output spectrum
    // Keep track of number of detectors required for masking
    size_t nonMaskedSpectra(0);
    beh->dataX(outIndex)[0] = 0.0;
    beh->dataE(outIndex)[0] = 0.0;
    for( std::vector<size_t>::const_iterator wsIter = it->second.begin(); wsIter != it->second.end(); ++wsIter)
    {
      const size_t originalWI = *wsIter;

      // detectors to add to firstSpecNum
      const ISpectrum * fromSpectrum = inputWS->getSpectrum(originalWI);

      // Add up all the Y spectra and store the result in the first one
      // Need to keep the next 3 lines inside loop for now until ManagedWorkspace mru-list works properly
      MantidVec &firstY = outSpec->dataY();
      MantidVec::iterator fYit;
      MantidVec::iterator fEit = outSpec->dataE().begin();
      MantidVec::const_iterator Yit = fromSpectrum->dataY().begin();
      MantidVec::const_iterator Eit = fromSpectrum->dataE().begin();
      for (fYit = firstY.begin(); fYit != firstY.end(); ++fYit, ++fEit, ++Yit, ++Eit)
      {
        *fYit += *Yit;
        // Assume 'normal' (i.e. Gaussian) combination of errors
        *fEit = std::sqrt( (*fEit)*(*fEit) + (*Eit)*(*Eit) );
      }

      // detectors to add to the output spectrum
      outSpec->addDetectorIDs(fromSpectrum->getDetectorIDs() );
      try
      {
        Geometry::IDetector_const_sptr det = inputWS->getDetector(originalWI);
        if( !det->isMasked() ) ++nonMaskedSpectra;
      }
      catch(Exception::NotFoundError&)
      {
        // If a detector cannot be found, it cannot be masked
        ++nonMaskedSpectra;
      }
    }
    if( nonMaskedSpectra == 0 ) ++nonMaskedSpectra; // Avoid possible divide by zero
    if(!requireDivide) requireDivide = (nonMaskedSpectra > 1);
    beh->dataY(outIndex)[0] = static_cast<double>(nonMaskedSpectra);

    // make regular progress reports and check for cancelling the algorithm
    if ( outIndex % INTERVAL == 0 )
    {
      m_FracCompl += INTERVAL*prog4Copy;
      if ( m_FracCompl > 1.0 )
        m_FracCompl = 1.0;
      progress(m_FracCompl);
      interruption_point();
    }
    outIndex ++;
  }
  
  // Refresh the spectraDetectorMap
  outputWS->generateSpectraMap();

  if ( bhv == 1 && requireDivide )
  {
    g_log.debug() << "Running Divide algorithm to perform averaging.\n";
    Mantid::API::IAlgorithm_sptr divide = createChildAlgorithm("Divide");
    divide->initialize();
    divide->setProperty<API::MatrixWorkspace_sptr>("LHSWorkspace", outputWS);
    divide->setProperty<API::MatrixWorkspace_sptr>("RHSWorkspace", beh);
    divide->setProperty<API::MatrixWorkspace_sptr>("OutputWorkspace", outputWS);
    divide->execute();
  }

  g_log.debug() << name() << " created " << outIndex << " new grouped spectra\n";
  return outIndex;
}
Exemplo n.º 27
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/** method to cacluate the detectors parameters and add them to the detectors
*averages
*@param spDet    -- shared pointer to the Mantid Detector
*@param Observer -- sample position or the centre of the polar system of
*coordinates to calculate detector's parameters.
*/
void AvrgDetector::addDetInfo(const Geometry::IDetector_const_sptr &spDet,
                              const Kernel::V3D &Observer) {
  m_nComponents++;
  Kernel::V3D detPos = spDet->getPos();
  Kernel::V3D toDet = (detPos - Observer);

  double dist2Det, Polar, Azimut, ringPolar, ringAzim;
  // identify the detector' position in the beam coordinate system:
  toDet.getSpherical(dist2Det, Polar, Azimut);
  if (m_nComponents <= 1) {
    m_FlightPathSum = dist2Det;
    m_PolarSum = Polar;
    m_AzimutSum = Azimut;

    m_AzimBase = Polar;
    m_PolarBase = Azimut;
    ringPolar = Polar;
    ringAzim = Azimut;
  } else {
    ringPolar = nearAngle(m_AzimBase, Polar);
    ringAzim = nearAngle(m_PolarBase, Azimut);
    m_FlightPathSum += dist2Det;
    m_PolarSum += ringPolar;
    m_AzimutSum += ringAzim;
  }

  // centre of the azimuthal ring (the ring  detectors form around the beam)
  Kernel::V3D ringCentre(0, 0, toDet.Z());

  // Get the bounding box
  Geometry::BoundingBox bbox;
  std::vector<Kernel::V3D> coord(3);

  Kernel::V3D er(0, 1, 0), e_th,
      ez(0, 0, 1); // ez along beamline, which is always oz;
  if (dist2Det)
    er = toDet / dist2Det; // direction to the detector
  Kernel::V3D e_tg =
      er.cross_prod(ez); // tangential to the ring and anticloakwise;
  e_tg.normalize();
  // make orthogonal -- projections are calculated in this coordinate system
  ez = e_tg.cross_prod(er);

  coord[0] = er;   // new X
  coord[1] = ez;   // new y
  coord[2] = e_tg; // new z
  bbox.setBoxAlignment(ringCentre, coord);

  spDet->getBoundingBox(bbox);

  // linear extensions of the bounding box orientied tangentially to the equal
  // scattering angle circle
  double azimMin = bbox.zMin();
  double azimMax = bbox.zMax();
  double polarMin = bbox.yMin(); // bounding box has been rotated according to
                                 // coord above, so z is along e_tg
  double polarMax = bbox.yMax();

  if (m_useSphericalSizes) {
    if (dist2Det == 0)
      dist2Det = 1;

    // convert to angular units
    double polarHalfSize =
        rad2deg * atan2(0.5 * (polarMax - polarMin), dist2Det);
    double azimHalfSize = rad2deg * atan2(0.5 * (azimMax - azimMin), dist2Det);

    polarMin = ringPolar - polarHalfSize;
    polarMax = ringPolar + polarHalfSize;
    azimMin = ringAzim - azimHalfSize;
    azimMax = ringAzim + azimHalfSize;
  }
  if (m_AzimMin > azimMin)
    m_AzimMin = azimMin;
  if (m_AzimMax < azimMax)
    m_AzimMax = azimMax;

  if (m_PolarMin > polarMin)
    m_PolarMin = polarMin;
  if (m_PolarMax < polarMax)
    m_PolarMax = polarMax;
}
Exemplo n.º 28
0
/** Executes the algorithm
 *@param localworkspace :: the input workspace
 *@param indices :: set of indices to sum up
 */
void SumSpectra::execEvent(EventWorkspace_const_sptr localworkspace,
                           std::set<int> &indices) {
  // Make a brand new EventWorkspace
  EventWorkspace_sptr outputWorkspace =
      boost::dynamic_pointer_cast<EventWorkspace>(
          API::WorkspaceFactory::Instance().create("EventWorkspace", 1, 2, 1));
  // Copy geometry over.
  API::WorkspaceFactory::Instance().initializeFromParent(localworkspace,
                                                         outputWorkspace, true);

  Progress progress(this, 0, 1, indices.size());

  // Get the pointer to the output event list
  EventList &outEL = outputWorkspace->getEventList(0);
  outEL.setSpectrumNo(m_outSpecId);
  outEL.clearDetectorIDs();

  // Loop over spectra
  std::set<int>::iterator it;
  size_t numSpectra(0);
  size_t numMasked(0);
  size_t numZeros(0);
  // for (int i = m_minSpec; i <= m_maxSpec; ++i)
  for (it = indices.begin(); it != indices.end(); ++it) {
    int i = *it;
    // Don't go outside the range.
    if ((i >= m_numberOfSpectra) || (i < 0)) {
      g_log.error() << "Invalid index " << i
                    << " was specified. Sum was aborted.\n";
      break;
    }

    try {
      // Get the detector object for this spectrum
      Geometry::IDetector_const_sptr det = localworkspace->getDetector(i);
      // Skip monitors, if the property is set to do so
      if (!m_keepMonitors && det->isMonitor())
        continue;
      // Skip masked detectors
      if (det->isMasked()) {
        numMasked++;
        continue;
      }
    } catch (...) {
      // if the detector not found just carry on
    }
    numSpectra++;

    // Add the event lists with the operator
    const EventList &tOutEL = localworkspace->getEventList(i);
    if (tOutEL.empty()) {
      ++numZeros;
    }
    outEL += tOutEL;

    progress.report();
  }

  // Set all X bins on the output
  cow_ptr<MantidVec> XValues;
  XValues.access() = localworkspace->readX(0);
  outputWorkspace->setAllX(XValues);

  outputWorkspace->mutableRun().addProperty("NumAllSpectra", int(numSpectra),
                                            "", true);
  outputWorkspace->mutableRun().addProperty("NumMaskSpectra", int(numMasked),
                                            "", true);
  outputWorkspace->mutableRun().addProperty("NumZeroSpectra", int(numZeros), "",
                                            true);

  // Assign it to the output workspace property
  setProperty("OutputWorkspace",
              boost::dynamic_pointer_cast<MatrixWorkspace>(outputWorkspace));
}
Exemplo n.º 29
0
/**
 * This function handles the logic for summing RebinnedOutput workspaces.
 * @param outputWorkspace the workspace to hold the summed input
 * @param progress the progress indicator
 * @param numSpectra
 * @param numMasked
 * @param numZeros
 */
void SumSpectra::doRebinnedOutput(MatrixWorkspace_sptr outputWorkspace,
                                  Progress &progress, size_t &numSpectra,
                                  size_t &numMasked, size_t &numZeros) {
  // Get a copy of the input workspace
  MatrixWorkspace_sptr temp = getProperty("InputWorkspace");

  // First, we need to clean the input workspace for nan's and inf's in order
  // to treat the data correctly later. This will create a new private
  // workspace that will be retrieved as mutable.
  IAlgorithm_sptr alg = this->createChildAlgorithm("ReplaceSpecialValues");
  alg->setProperty<MatrixWorkspace_sptr>("InputWorkspace", temp);
  std::string outName = "_" + temp->getName() + "_clean";
  alg->setProperty("OutputWorkspace", outName);
  alg->setProperty("NaNValue", 0.0);
  alg->setProperty("NaNError", 0.0);
  alg->setProperty("InfinityValue", 0.0);
  alg->setProperty("InfinityError", 0.0);
  alg->executeAsChildAlg();
  MatrixWorkspace_sptr localworkspace = alg->getProperty("OutputWorkspace");

  // Transform to real workspace types
  RebinnedOutput_sptr inWS =
      boost::dynamic_pointer_cast<RebinnedOutput>(localworkspace);
  RebinnedOutput_sptr outWS =
      boost::dynamic_pointer_cast<RebinnedOutput>(outputWorkspace);

  // Get references to the output workspaces's data vectors
  ISpectrum *outSpec = outputWorkspace->getSpectrum(0);
  MantidVec &YSum = outSpec->dataY();
  MantidVec &YError = outSpec->dataE();
  MantidVec &FracSum = outWS->dataF(0);
  MantidVec Weight;
  std::vector<size_t> nZeros;
  if (m_calculateWeightedSum) {
    Weight.assign(YSum.size(), 0);
    nZeros.assign(YSum.size(), 0);
  }
  numSpectra = 0;
  numMasked = 0;
  numZeros = 0;

  // Loop over spectra
  std::set<int>::iterator it;
  // for (int i = m_minSpec; i <= m_maxSpec; ++i)
  for (it = m_indices.begin(); it != m_indices.end(); ++it) {
    int i = *it;
    // Don't go outside the range.
    if ((i >= m_numberOfSpectra) || (i < 0)) {
      g_log.error() << "Invalid index " << i
                    << " was specified. Sum was aborted.\n";
      break;
    }

    try {
      // Get the detector object for this spectrum
      Geometry::IDetector_const_sptr det = localworkspace->getDetector(i);
      // Skip monitors, if the property is set to do so
      if (!m_keepMonitors && det->isMonitor())
        continue;
      // Skip masked detectors
      if (det->isMasked()) {
        numMasked++;
        continue;
      }
    } catch (...) {
      // if the detector not found just carry on
    }
    numSpectra++;

    // Retrieve the spectrum into a vector
    const MantidVec &YValues = localworkspace->readY(i);
    const MantidVec &YErrors = localworkspace->readE(i);
    const MantidVec &FracArea = inWS->readF(i);

    if (m_calculateWeightedSum) {
      for (int k = 0; k < this->m_yLength; ++k) {
        if (YErrors[k] != 0) {
          double errsq = YErrors[k] * YErrors[k] * FracArea[k] * FracArea[k];
          YError[k] += errsq;
          Weight[k] += 1. / errsq;
          YSum[k] += YValues[k] * FracArea[k] / errsq;
          FracSum[k] += FracArea[k];
        } else {
          nZeros[k]++;
          FracSum[k] += FracArea[k];
        }
      }
    } else {
      for (int k = 0; k < this->m_yLength; ++k) {
        YSum[k] += YValues[k] * FracArea[k];
        YError[k] += YErrors[k] * YErrors[k] * FracArea[k] * FracArea[k];
        FracSum[k] += FracArea[k];
      }
    }

    // Map all the detectors onto the spectrum of the output
    outSpec->addDetectorIDs(localworkspace->getSpectrum(i)->getDetectorIDs());

    progress.report();
  }

  if (m_calculateWeightedSum) {
    numZeros = 0;
    for (size_t i = 0; i < Weight.size(); i++) {
      if (nZeros[i] == 0)
        YSum[i] *= double(numSpectra) / Weight[i];
      else
        numZeros += nZeros[i];
    }
  }

  // Create the correct representation
  outWS->finalize();
}
Exemplo n.º 30
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/**
 * This function deals with the logic necessary for summing a Workspace2D.
 * @param localworkspace The input workspace for summing.
 * @param outSpec The spectrum for the summed output.
 * @param progress The progress indicator.
 * @param numSpectra The number of spectra contributed to the sum.
 * @param numMasked The spectra dropped from the summations because they are
 * masked.
 * @param numZeros The number of zero bins in histogram workspace or empty
 * spectra for event workspace.
 */
void SumSpectra::doWorkspace2D(MatrixWorkspace_const_sptr localworkspace,
                               ISpectrum *outSpec, Progress &progress,
                               size_t &numSpectra, size_t &numMasked,
                               size_t &numZeros) {
  // Get references to the output workspaces's data vectors
  MantidVec &YSum = outSpec->dataY();
  MantidVec &YError = outSpec->dataE();

  MantidVec Weight;
  std::vector<size_t> nZeros;
  if (m_calculateWeightedSum) {
    Weight.assign(YSum.size(), 0);
    nZeros.assign(YSum.size(), 0);
  }
  numSpectra = 0;
  numMasked = 0;
  numZeros = 0;

  // Loop over spectra
  std::set<int>::iterator it;
  // for (int i = m_minSpec; i <= m_maxSpec; ++i)
  for (it = this->m_indices.begin(); it != this->m_indices.end(); ++it) {
    int i = *it;
    // Don't go outside the range.
    if ((i >= this->m_numberOfSpectra) || (i < 0)) {
      g_log.error() << "Invalid index " << i
                    << " was specified. Sum was aborted.\n";
      break;
    }

    try {
      // Get the detector object for this spectrum
      Geometry::IDetector_const_sptr det = localworkspace->getDetector(i);
      // Skip monitors, if the property is set to do so
      if (!m_keepMonitors && det->isMonitor())
        continue;
      // Skip masked detectors
      if (det->isMasked()) {
        numMasked++;
        continue;
      }
    } catch (...) {
      // if the detector not found just carry on
    }
    numSpectra++;

    // Retrieve the spectrum into a vector
    const MantidVec &YValues = localworkspace->readY(i);
    const MantidVec &YErrors = localworkspace->readE(i);
    if (m_calculateWeightedSum) {
      for (int k = 0; k < this->m_yLength; ++k) {
        if (YErrors[k] != 0) {
          double errsq = YErrors[k] * YErrors[k];
          YError[k] += errsq;
          Weight[k] += 1. / errsq;
          YSum[k] += YValues[k] / errsq;
        } else {
          nZeros[k]++;
        }
      }
    } else {
      for (int k = 0; k < this->m_yLength; ++k) {
        YSum[k] += YValues[k];
        YError[k] += YErrors[k] * YErrors[k];
      }
    }

    // Map all the detectors onto the spectrum of the output
    outSpec->addDetectorIDs(localworkspace->getSpectrum(i)->getDetectorIDs());

    progress.report();
  }

  if (m_calculateWeightedSum) {
    numZeros = 0;
    for (size_t i = 0; i < Weight.size(); i++) {
      if (nZeros[i] == 0)
        YSum[i] *= double(numSpectra) / Weight[i];
      else
        numZeros += nZeros[i];
    }
  }
}