コード例 #1
0
void TOFSANSResolutionByPixel::exec() {
  MatrixWorkspace_sptr inOutWS = getProperty("Workspace");
  double deltaR = getProperty("DeltaR");
  double R1 = getProperty("SourceApertureRadius");
  double R2 = getProperty("SampleApertureRadius");
  // Convert to meters
  deltaR /= 1000.0;
  R1 /= 1000.0;
  R2 /= 1000.0;

  const MatrixWorkspace_sptr sigmaModeratorVSwavelength =
      getProperty("SigmaModerator");

  // create interpolation table from sigmaModeratorVSwavelength
  Kernel::Interpolation lookUpTable;

  const MantidVec xInterpolate = sigmaModeratorVSwavelength->readX(0);
  const MantidVec yInterpolate = sigmaModeratorVSwavelength->readY(0);

  // prefer the input to be a pointworkspace and create interpolation function
  if (sigmaModeratorVSwavelength->isHistogramData()) {
    g_log.notice() << "mid-points of SigmaModerator histogram bins will be "
                      "used for interpolation.";

    for (size_t i = 0; i < xInterpolate.size() - 1; ++i) {
      const double midpoint = xInterpolate[i + 1] - xInterpolate[i];
      lookUpTable.addPoint(midpoint, yInterpolate[i]);
    }
  } else {
    for (size_t i = 0; i < xInterpolate.size(); ++i) {
      lookUpTable.addPoint(xInterpolate[i], yInterpolate[i]);
    }
  }

  const V3D samplePos = inOutWS->getInstrument()->getSample()->getPos();
  const V3D sourcePos = inOutWS->getInstrument()->getSource()->getPos();
  const V3D SSD = samplePos - sourcePos;
  const double L1 = SSD.norm();

  const int numberOfSpectra = static_cast<int>(inOutWS->getNumberHistograms());
  Progress progress(this, 0.0, 1.0, numberOfSpectra);

  for (int i = 0; i < numberOfSpectra; i++) {
    IDetector_const_sptr det;
    try {
      det = inOutWS->getDetector(i);
    } catch (Exception::NotFoundError &) {
      g_log.information() << "Spectrum index " << i
                          << " has no detector assigned to it - discarding"
                          << std::endl;
    }
    // If no detector found or if it's masked or a monitor, skip onto the next
    // spectrum
    if (!det || det->isMonitor() || det->isMasked())
      continue;

    // Get the flight path from the sample to the detector pixel
    const V3D scatteredFlightPathV3D = det->getPos() - samplePos;

    const double L2 = scatteredFlightPathV3D.norm();
    const double Lsum = L1 + L2;

    // calculate part that is wavelenght independent
    const double dTheta2 = (4.0 * M_PI * M_PI / 12.0) *
                           (3.0 * R1 * R1 / (L1 * L1) +
                            3.0 * R2 * R2 * Lsum * Lsum / (L1 * L1 * L2 * L2) +
                            (deltaR * deltaR) / (L2 * L2));

    // Multiplicative factor to go from lambda to Q
    // Don't get fooled by the function name...
    const double theta = inOutWS->detectorTwoTheta(det);
    const double factor = 4.0 * M_PI * sin(theta / 2.0);

    const MantidVec &xIn = inOutWS->readX(i);
    MantidVec &yIn = inOutWS->dataY(i);
    const size_t xLength = xIn.size();

    // for each wavelenght bin of each pixel calculate a q-resolution
    for (size_t j = 0; j < xLength - 1; j++) {
      // use the midpoint of each bin
      const double wl = (xIn[j + 1] + xIn[j]) / 2.0;
      // Calculate q. Alternatively q could be calculated using ConvertUnit
      const double q = factor / wl;

      // wavelenght spread from bin assumed to be
      const double sigmaSpreadFromBin = xIn[j + 1] - xIn[j];

      // wavelenght spread from moderatorm, converted from microseconds to
      // wavelengths
      const double sigmaModerator =
          lookUpTable.value(wl) * 3.9560 / (1000.0 * Lsum);

      // calculate wavelenght resolution from moderator and histogram time bin
      const double sigmaLambda =
          std::sqrt(sigmaSpreadFromBin * sigmaSpreadFromBin / 12.0 +
                    sigmaModerator * sigmaModerator);

      // calculate sigmaQ for a given lambda and pixel
      const double sigmaOverLambdaTimesQ = q * sigmaLambda / wl;
      const double sigmaQ = std::sqrt(
          dTheta2 / (wl * wl) + sigmaOverLambdaTimesQ * sigmaOverLambdaTimesQ);

      // update inout workspace with this sigmaQ
      yIn[j] = sigmaQ;
    }

    progress.report("Computing Q resolution");
  }
}
コード例 #2
0
void TOFSANSResolutionByPixel::exec() {
  MatrixWorkspace_sptr inWS = getProperty("InputWorkspace");
  double deltaR = getProperty("DeltaR");
  double R1 = getProperty("SourceApertureRadius");
  double R2 = getProperty("SampleApertureRadius");
  const bool doGravity = getProperty("AccountForGravity");

  // Check the input
  checkInput(inWS);

  // Setup outputworkspace
  auto outWS = setupOutputWorkspace(inWS);

  // Convert to meters
  deltaR /= 1000.0;
  R1 /= 1000.0;
  R2 /= 1000.0;

  // The moderator workspace needs to match the data workspace
  // in terms of wavelength binning
  const MatrixWorkspace_sptr sigmaModeratorVSwavelength =
      getModeratorWorkspace(inWS);

  // create interpolation table from sigmaModeratorVSwavelength
  Kernel::Interpolation lookUpTable;

  const auto &xInterpolate = sigmaModeratorVSwavelength->points(0);
  const auto &yInterpolate = sigmaModeratorVSwavelength->y(0);

  // prefer the input to be a pointworkspace and create interpolation function
  if (sigmaModeratorVSwavelength->isHistogramData()) {
    g_log.notice() << "mid-points of SigmaModerator histogram bins will be "
                      "used for interpolation.";
  }

  for (size_t i = 0; i < xInterpolate.size(); ++i) {
    lookUpTable.addPoint(xInterpolate[i], yInterpolate[i]);
  }

  // Calculate the L1 distance
  const V3D samplePos = inWS->getInstrument()->getSample()->getPos();
  const V3D sourcePos = inWS->getInstrument()->getSource()->getPos();
  const V3D SSD = samplePos - sourcePos;
  const double L1 = SSD.norm();

  // Get the collimation length
  double LCollim = getProperty("CollimationLength");

  if (LCollim == 0.0) {
    auto collimationLengthEstimator = SANSCollimationLengthEstimator();
    LCollim = collimationLengthEstimator.provideCollimationLength(inWS);
    g_log.information() << "No collimation length was specified. A default "
                           "collimation length was estimated to be " << LCollim
                        << '\n';
  } else {
    g_log.information() << "The collimation length is  " << LCollim << '\n';
  }

  const int numberOfSpectra = static_cast<int>(inWS->getNumberHistograms());
  Progress progress(this, 0.0, 1.0, numberOfSpectra);

  const auto &spectrumInfo = inWS->spectrumInfo();
  for (int i = 0; i < numberOfSpectra; i++) {
    IDetector_const_sptr det;
    if (!spectrumInfo.hasDetectors(i)) {
      g_log.information() << "Workspace index " << i
                          << " has no detector assigned to it - discarding\n";
      continue;
    }
    // If no detector found or if it's masked or a monitor, skip onto the next
    // spectrum
    if (spectrumInfo.isMonitor(i) || spectrumInfo.isMasked(i))
      continue;

    const double L2 = spectrumInfo.l2(i);
    TOFSANSResolutionByPixelCalculator calculator;
    const double waveLengthIndependentFactor =
        calculator.getWavelengthIndependentFactor(R1, R2, deltaR, LCollim, L2);

    // Multiplicative factor to go from lambda to Q
    // Don't get fooled by the function name...
    const double theta = spectrumInfo.twoTheta(i);
    double sinTheta = sin(0.5 * theta);
    double factor = 4.0 * M_PI * sinTheta;

    const auto &xIn = inWS->x(i);
    const size_t xLength = xIn.size();

    // Gravity correction
    std::unique_ptr<GravitySANSHelper> grav;
    if (doGravity) {
      grav = Kernel::make_unique<GravitySANSHelper>(spectrumInfo, i,
                                                    getProperty("ExtraLength"));
    }

    // Get handles on the outputWorkspace
    auto &yOut = outWS->mutableY(i);
    // for each wavelenght bin of each pixel calculate a q-resolution
    for (size_t j = 0; j < xLength - 1; j++) {
      // use the midpoint of each bin
      const double wl = (xIn[j + 1] + xIn[j]) / 2.0;
      // Calculate q. Alternatively q could be calculated using ConvertUnit
      // If we include a gravity correction we need to adjust sinTheta
      // for each wavelength (in Angstrom)
      if (doGravity) {
        double sinThetaGrav = grav->calcSinTheta(wl);
        factor = 4.0 * M_PI * sinThetaGrav;
      }
      const double q = factor / wl;

      // wavelenght spread from bin assumed to be
      const double sigmaSpreadFromBin = xIn[j + 1] - xIn[j];

      // Get the uncertainty in Q
      auto sigmaQ = calculator.getSigmaQValue(lookUpTable.value(wl),
                                              waveLengthIndependentFactor, q,
                                              wl, sigmaSpreadFromBin, L1, L2);

      // Insert the Q value and the Q resolution into the outputworkspace
      yOut[j] = sigmaQ;
    }
    progress.report("Computing Q resolution");
  }

  // Set the y axis label
  outWS->setYUnitLabel("QResolution");

  setProperty("OutputWorkspace", outWS);
}