Exemplo n.º 1
0
/**
 * Make a map of the conversion factors between tof and D-spacing
 * for all pixel IDs in a workspace.
 *
 * @param DFileName name of dspacemap file
 * @param offsetsWS :: OffsetsWorkspace with instrument and offsets
 */
void SaveDspacemap::CalculateDspaceFromCal(
    Mantid::DataObjects::OffsetsWorkspace_sptr offsetsWS,
    std::string DFileName) {
  const char *filename = DFileName.c_str();
  // Get a pointer to the instrument contained in the workspace
  Instrument_const_sptr instrument = offsetsWS->getInstrument();
  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);

  detid2det_map::const_iterator it;
  detid_t maxdetID = 0;
  for (it = allDetectors.begin(); it != allDetectors.end(); ++it) {
    detid_t detectorID = it->first;
    if (detectorID > maxdetID)
      maxdetID = detectorID;
  }
  detid_t paddetID = detid_t(getProperty("PadDetID"));
  if (maxdetID < paddetID)
    maxdetID = paddetID;

  // Now write the POWGEN-style Dspace mapping file
  std::ofstream fout(filename, std::ios_base::out | std::ios_base::binary);
  Progress prog(this, 0.0, 1.0, maxdetID);

  for (detid_t i = 0; i != maxdetID; i++) {
    // Compute the factor
    double factor;
    Geometry::IDetector_const_sptr det;
    // Find the detector with that detector id
    it = allDetectors.find(i);
    if (it != allDetectors.end()) {
      det = it->second;
      factor =
          Instrument::calcConversion(l1, beamline, beamline_norm, samplePos,
                                     det, offsetsWS->getValue(i, 0.0));
      // Factor of 10 between ISAW and Mantid
      factor *= 0.1;
      if (factor < 0)
        factor = 0.0;
      fout.write(reinterpret_cast<char *>(&factor), sizeof(double));
    } else {
      factor = 0;
      fout.write(reinterpret_cast<char *>(&factor), sizeof(double));
    }
    // Report progress
    prog.report();
  }
  fout.close();
}
Exemplo n.º 2
0
/**
 * Make a map of the conversion factors between tof and D-spacing
 * for all pixel IDs in a workspace.
 *
 * @param DFileName :: name of dspacemap file
 * @param offsetsWS :: OffsetsWorkspace to be filled.
 */
void LoadDspacemap::CalculateOffsetsFromDSpacemapFile(
    const std::string DFileName,
    Mantid::DataObjects::OffsetsWorkspace_sptr offsetsWS) {
  // Get a pointer to the instrument contained in the workspace
  Instrument_const_sptr instrument = offsetsWS->getInstrument();
  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);

  // Read in the POWGEN-style Dspace mapping file
  const char *filename = DFileName.c_str();
  std::ifstream fin(filename, std::ios_base::in | std::ios_base::binary);

  std::vector<double> dspace;
  double read;
  while (!fin.eof()) {
    fin.read(reinterpret_cast<char *>(&read), sizeof read);
    // Factor of 10 between ISAW and Mantid
    read *= 10.;
    dspace.push_back(read);
  }

  detid2det_map::const_iterator it;
  for (it = allDetectors.begin(); it != allDetectors.end(); ++it) {
    detid_t detectorID = it->first;
    Geometry::IDetector_const_sptr det = it->second;

    // Compute the factor
    double offset = 0.0;
    double factor = Instrument::calcConversion(l1, beamline, beamline_norm,
                                               samplePos, det, offset);
    offset = dspace[detectorID] / factor - 1.0;
    // Save in the map
    try {
      offsetsWS->setValue(detectorID, offset);
    } catch (std::invalid_argument &) {
    }
  }
}
Exemplo n.º 3
0
/**
 * Make a map of the conversion factors between tof and D-spacing
 * for all pixel IDs in a workspace.
 * map vulcan should contain the module/module and stack/stack offset
 *
 * @param vulcan :: map between detector ID and vulcan correction factor.
 * @param offsetsWS :: OffsetsWorkspace to be filled.
 */
void LoadDspacemap::CalculateOffsetsFromVulcanFactors(
    std::map<detid_t, double> &vulcan,
    Mantid::DataObjects::OffsetsWorkspace_sptr offsetsWS) {
  // Get a pointer to the instrument contained in the workspace
  // At this point, instrument VULCAN has been created?
  Instrument_const_sptr instrument = offsetsWS->getInstrument();

  g_log.notice() << "Name of instrument = " << instrument->getName()
                 << std::endl;
  g_log.notice() << "Input map (dict):  size = " << vulcan.size() << std::endl;

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

  detid2det_map::const_iterator it;
  int numfinds = 0;
  g_log.notice() << "Input number of detectors = " << allDetectors.size()
                 << std::endl;

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

  /*** A survey of parent detector
  std::map<detid_t, bool> parents;
  for (it = allDetectors.begin(); it != allDetectors.end(); it++){
    int32_t detid = it->first;

    // def boost::shared_ptr<const Mantid::Geometry::IDetector>
  IDetector_const_sptr;

    std::string parentname =
  it->second->getParent()->getComponentID()->getName();
    g_log.notice() << "Name = " << parentname << std::endl;
    // parents.insert(parentid, true);
  }
  ***/

  /*** Here some special configuration for VULCAN is hard-coded here!
   *   Including (1) Super-Parent Information
   ***/
  Kernel::V3D referencePos;
  detid_t anydetinrefmodule = 21 * 1250 + 5;

  std::map<detid_t, Geometry::IDetector_const_sptr>::iterator det_iter =
      allDetectors.find(anydetinrefmodule);

  if (det_iter == allDetectors.end()) {
    throw std::invalid_argument("Any Detector ID is Instrument's detector");
  }
  referencePos = det_iter->second->getParent()->getPos();
  double refl2 = referencePos.norm();
  double halfcosTwoThetaRef =
      referencePos.scalar_prod(beamline) / (refl2 * beamline_norm);
  double sinThetaRef = sqrt(0.5 - halfcosTwoThetaRef);
  double difcRef = sinThetaRef * (l1 + refl2) / CONSTANT;

  // Loop over all detectors in instrument to find the offset
  for (it = allDetectors.begin(); it != allDetectors.end(); ++it) {
    int detectorID = it->first;
    Geometry::IDetector_const_sptr det = it->second;
    double offset = 0.0;

    // Find the vulcan factor;
    double vulcan_factor = 0.0;
    std::map<detid_t, double>::const_iterator vulcan_iter =
        vulcan.find(detectorID);
    if (vulcan_iter != vulcan.end()) {
      vulcan_factor = vulcan_iter->second;
      numfinds++;
    }

    // g_log.notice() << "Selected Detector with ID = " << detectorID << "  ID2
    // = " << id2 << std::endl; proved to be same

    double intermoduleoffset = 0;
    double interstackoffset = 0;

    detid_t intermoduleid = detid_t(detectorID / 1250) * 1250 + 1250 - 2;
    vulcan_iter = vulcan.find(intermoduleid);
    if (vulcan_iter == vulcan.end()) {
      g_log.error() << "Cannot find inter-module offset ID = " << intermoduleid
                    << std::endl;
    } else {
      intermoduleoffset = vulcan_iter->second;
    }

    detid_t interstackid = detid_t(detectorID / 1250) * 1250 + 1250 - 1;
    vulcan_iter = vulcan.find(interstackid);
    if (vulcan_iter == vulcan.end()) {
      g_log.error() << "Cannot find inter-module offset ID = " << intermoduleid
                    << std::endl;
    } else {
      interstackoffset = vulcan_iter->second;
    }

    /***  This is the previous way to correct upon DIFC[module center pixel]
    // The actual factor is 10^(-value_in_the_file)
    vulcan_factor = pow(10.0,-vulcan_factor);
    // At this point, tof_corrected = vulcan_factor * tof_input
    // So this is the offset
    offset = vulcan_factor - 1.0;
    ***/

    /*** New approach to correct based on DIFC of each pixel
     *   Equation:  offset = DIFC^(pixel)/DIFC^(parent)*(1+vulcan_offset)-1
     *   offset should be close to 0
     ***/
    // 1. calculate DIFC
    Kernel::V3D detPos;
    detPos = det->getPos();

    // Now detPos will be set with respect to samplePos
    detPos -= samplePos;
    double l2 = detPos.norm();
    double halfcosTwoTheta =
        detPos.scalar_prod(beamline) / (l2 * beamline_norm);
    double sinTheta = sqrt(0.5 - halfcosTwoTheta);
    double difc_pixel = sinTheta * (l1 + l2) / CONSTANT;

    // Kernel::V3D parentPos = det->getParent()->getPos();
    // parentPos -= samplePos;
    // double l2parent = parentPos.norm();
    // double halfcosTwoThetaParent = parentPos.scalar_prod(beamline)/(l2 *
    // beamline_norm);
    // double sinThetaParent = sqrt(0.5 - halfcosTwoThetaParent);
    // double difc_parent = sinThetaParent*(l1+l2parent)/CONSTANT;

    /*** Offset Replicate Previous Result
    offset = difc_pixel/difc_parent*(pow(10.0, -vulcan_factor))-1.0;
    ***/

    offset =
        difc_pixel / difcRef * (pow(10.0, -(vulcan_factor + intermoduleoffset +
                                            interstackoffset))) -
        1.0;

    // Save in the map
    try {
      offsetsWS->setValue(detectorID, offset);

      if (intermoduleid != 27498 && intermoduleid != 28748 &&
          intermoduleid != 29998 && intermoduleid != 33748 &&
          intermoduleid != 34998 && intermoduleid != 36248) {
        g_log.error() << "Detector ID = " << detectorID
                      << "  Inter-Module ID = " << intermoduleid << std::endl;
        throw std::invalid_argument("Indexing error!");
      }

    } catch (std::invalid_argument &) {
      g_log.notice() << "Misses Detector ID = " << detectorID << std::endl;
    }
  } // for

  g_log.notice() << "Number of matched detectors =" << numfinds << std::endl;
}