/// Constructor
FunctionGenerator::FunctionGenerator(API::IFunction_sptr source)
    : m_source(source), m_nOwnParams(source->nParams()), m_dirty(true) {
    if (!m_source) {
        throw std::logic_error(
            "FunctionGenerator initialised with null source function.");
    }
    declareAttribute("NumDeriv", Attribute(false));
}
示例#2
0
/** Fit background function
  */
void ProcessBackground::fitBackgroundFunction(std::string bkgdfunctiontype) {
  // Get background type and create bakground function
  BackgroundFunction_sptr bkgdfunction =
      createBackgroundFunction(bkgdfunctiontype);

  int bkgdorder = getProperty("OutputBackgroundOrder");
  bkgdfunction->setAttributeValue("n", bkgdorder);

  if (bkgdfunctiontype == "Chebyshev") {
    double xmin = m_outputWS->readX(0).front();
    double xmax = m_outputWS->readX(0).back();
    g_log.information() << "Chebyshev Fit range: " << xmin << ", " << xmax
                        << "\n";
    bkgdfunction->setAttributeValue("StartX", xmin);
    bkgdfunction->setAttributeValue("EndX", xmax);
  }

  g_log.information() << "Fit selected background " << bkgdfunctiontype
                      << " to data workspace with "
                      << m_outputWS->getNumberHistograms() << " spectra."
                      << "\n";

  // Fit input (a few) background pionts to get initial guess
  API::IAlgorithm_sptr fit;
  try {
    fit = this->createChildAlgorithm("Fit", 0.9, 1.0, true);
  } catch (Exception::NotFoundError &) {
    g_log.error() << "Requires CurveFitting library." << std::endl;
    throw;
  }

  g_log.information() << "Fitting background function: "
                      << bkgdfunction->asString() << "\n";

  double startx = m_lowerBound;
  double endx = m_upperBound;
  fit->setProperty("Function",
                   boost::dynamic_pointer_cast<API::IFunction>(bkgdfunction));
  fit->setProperty("InputWorkspace", m_outputWS);
  fit->setProperty("WorkspaceIndex", 0);
  fit->setProperty("MaxIterations", 500);
  fit->setProperty("StartX", startx);
  fit->setProperty("EndX", endx);
  fit->setProperty("Minimizer", "Levenberg-MarquardtMD");
  fit->setProperty("CostFunction", "Least squares");

  fit->executeAsChildAlg();

  // Get fit status and chi^2
  std::string fitStatus = fit->getProperty("OutputStatus");
  bool allowedfailure = (fitStatus.find("cannot") < fitStatus.size()) &&
                        (fitStatus.find("tolerance") < fitStatus.size());
  if (fitStatus.compare("success") != 0 && !allowedfailure) {
    g_log.error() << "ProcessBackground: Fit Status = " << fitStatus
                  << ".  Not to update fit result" << std::endl;
    throw std::runtime_error("Bad Fit");
  }

  const double chi2 = fit->getProperty("OutputChi2overDoF");
  g_log.information() << "Fit background: Fit Status = " << fitStatus
                      << ", chi2 = " << chi2 << "\n";

  // Get out the parameter names
  API::IFunction_sptr funcout = fit->getProperty("Function");
  TableWorkspace_sptr outbkgdparws = boost::make_shared<TableWorkspace>();
  outbkgdparws->addColumn("str", "Name");
  outbkgdparws->addColumn("double", "Value");

  TableRow typerow = outbkgdparws->appendRow();
  typerow << bkgdfunctiontype << 0.;

  vector<string> parnames = funcout->getParameterNames();
  size_t nparam = funcout->nParams();
  for (size_t i = 0; i < nparam; ++i) {
    TableRow newrow = outbkgdparws->appendRow();
    newrow << parnames[i] << funcout->getParameter(i);
  }

  TableRow chi2row = outbkgdparws->appendRow();
  chi2row << "Chi-square" << chi2;

  g_log.information() << "Set table workspace (#row = "
                      << outbkgdparws->rowCount()
                      << ") to OutputBackgroundParameterTable. "
                      << "\n";
  setProperty("OutputBackgroundParameterWorkspace", outbkgdparws);

  // Set output workspace
  const MantidVec &vecX = m_outputWS->readX(0);
  const MantidVec &vecY = m_outputWS->readY(0);
  FunctionDomain1DVector domain(vecX);
  FunctionValues values(domain);

  funcout->function(domain, values);

  MantidVec &dataModel = m_outputWS->dataY(1);
  MantidVec &dataDiff = m_outputWS->dataY(2);
  for (size_t i = 0; i < dataModel.size(); ++i) {
    dataModel[i] = values[i];
    dataDiff[i] = vecY[i] - dataModel[i];
  }

  return;
}
示例#3
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/**
 * Execute smoothing of a single spectrum.
 * @param inputWS :: A workspace to pick a spectrum from.
 * @param wsIndex :: An index of a spectrum to smooth.
 * @return :: A single-spectrum workspace with the smoothed data.
 */
API::MatrixWorkspace_sptr
WienerSmooth::smoothSingleSpectrum(API::MatrixWorkspace_sptr inputWS,
                                   size_t wsIndex) {
  size_t dataSize = inputWS->blocksize();

  // it won't work for very small workspaces
  if (dataSize < 4) {
    g_log.debug() << "No smoothing, spectrum copied." << std::endl;
    return copyInput(inputWS, wsIndex);
  }

  // Due to the way RealFFT works the input should be even-sized
  const bool isOddSize = dataSize % 2 != 0;
  if (isOddSize) {
    // add a fake value to the end to make size even
    inputWS = copyInput(inputWS, wsIndex);
    wsIndex = 0;
    auto &X = inputWS->dataX(wsIndex);
    auto &Y = inputWS->dataY(wsIndex);
    auto &E = inputWS->dataE(wsIndex);
    double dx = X[dataSize - 1] - X[dataSize - 2];
    X.push_back(X.back() + dx);
    Y.push_back(Y.back());
    E.push_back(E.back());
  }

  // the input vectors
  auto &X = inputWS->readX(wsIndex);
  auto &Y = inputWS->readY(wsIndex);
  auto &E = inputWS->readE(wsIndex);

  // Digital fourier transform works best for data oscillating around 0.
  // Fit a spline with a small number of break points to the data.
  // Make sure that the spline passes through the first and the last points
  // of the data.
  // The fitted spline will be subtracted from the data and the difference
  // will be smoothed with the Wiener filter. After that the spline will be
  // added to the smoothed data to produce the output.

  // number of spline break points, must be smaller than the data size but
  // between 2 and 10
  size_t nbreak = 10;
  if (nbreak * 3 > dataSize)
    nbreak = dataSize / 3;

  // NB. The spline mustn't fit too well to the data. If it does smoothing
  // doesn't happen.
  // TODO: it's possible that the spline is unnecessary and a simple linear
  // function will
  //       do a better job.

  g_log.debug() << "Spline break points " << nbreak << std::endl;

  // define the spline
  API::IFunction_sptr spline =
      API::FunctionFactory::Instance().createFunction("BSpline");
  auto xInterval = getStartEnd(X, inputWS->isHistogramData());
  spline->setAttributeValue("StartX", xInterval.first);
  spline->setAttributeValue("EndX", xInterval.second);
  spline->setAttributeValue("NBreak", static_cast<int>(nbreak));
  // fix the first and last parameters to the first and last data values
  spline->setParameter(0, Y.front());
  spline->fix(0);
  size_t lastParamIndex = spline->nParams() - 1;
  spline->setParameter(lastParamIndex, Y.back());
  spline->fix(lastParamIndex);

  // fit the spline to the data
  auto fit = createChildAlgorithm("Fit");
  fit->initialize();
  fit->setProperty("Function", spline);
  fit->setProperty("InputWorkspace", inputWS);
  fit->setProperty("WorkspaceIndex", static_cast<int>(wsIndex));
  fit->setProperty("CreateOutput", true);
  fit->execute();

  // get the fit output workspace; spectrum 2 contains the difference that is to
  // be smoothed
  API::MatrixWorkspace_sptr fitOut = fit->getProperty("OutputWorkspace");

  // Fourier transform the difference spectrum
  auto fourier = createChildAlgorithm("RealFFT");
  fourier->initialize();
  fourier->setProperty("InputWorkspace", fitOut);
  fourier->setProperty("WorkspaceIndex", 2);
  // we don't require bin linearity as we don't need the exact transform
  fourier->setProperty("IgnoreXBins", true);
  fourier->execute();

  API::MatrixWorkspace_sptr fourierOut =
      fourier->getProperty("OutputWorkspace");

  // spectrum 2 of the transformed workspace has the transform modulus which is
  // a square
  // root of the power spectrum
  auto &powerSpec = fourierOut->dataY(2);
  // convert the modulus to power spectrum wich is the base of the Wiener filter
  std::transform(powerSpec.begin(), powerSpec.end(), powerSpec.begin(),
                 PowerSpectrum());

  // estimate power spectrum's noise as the average of its high frequency half
  size_t n2 = powerSpec.size();
  double noise =
      std::accumulate(powerSpec.begin() + n2 / 2, powerSpec.end(), 0.0);
  noise /= static_cast<double>(n2);

  // index of the maximum element in powerSpec
  const size_t imax = static_cast<size_t>(std::distance(
      powerSpec.begin(), std::max_element(powerSpec.begin(), powerSpec.end())));

  if (noise == 0.0) {
    noise = powerSpec[imax] / guessSignalToNoiseRatio;
  }

  g_log.debug() << "Maximum signal " << powerSpec[imax] << std::endl;
  g_log.debug() << "Noise          " << noise << std::endl;

  // storage for the Wiener filter, initialized with 0.0's
  std::vector<double> wf(n2);

  // The filter consists of two parts:
  //   1) low frequency region, from 0 until the power spectrum falls to the
  //   noise level, filter is calculated
  //      from the power spectrum
  //   2) high frequency noisy region, filter is a smooth function of frequency
  //   decreasing to 0

  // the following code is an adaptation of a fortran routine
  // noise starting index
  size_t i0 = 0;
  // intermediate variables
  double xx = 0.0;
  double xy = 0.0;
  double ym = 0.0;
  // low frequency filter values: the higher the power spectrum the closer the
  // filter to 1.0
  for (size_t i = 0; i < n2; ++i) {
    double cd1 = powerSpec[i] / noise;
    if (cd1 < 1.0 && i > imax) {
      i0 = i;
      break;
    }
    double cd2 = log(cd1);
    wf[i] = cd1 / (1.0 + cd1);
    double j = static_cast<double>(i + 1);
    xx += j * j;
    xy += j * cd2;
    ym += cd2;
  }

  // i0 should always be > 0 but in case something goes wrong make a check
  if (i0 > 0) {
    g_log.debug() << "Noise start index " << i0 << std::endl;

    // high frequency filter values: smooth decreasing function
    double ri0f = static_cast<double>(i0 + 1);
    double xm = (1.0 + ri0f) / 2;
    ym /= ri0f;
    double a1 = (xy - ri0f * xm * ym) / (xx - ri0f * xm * xm);
    double b1 = ym - a1 * xm;

    g_log.debug() << "(a1,b1) = (" << a1 << ',' << b1 << ')' << std::endl;

    const double dblev = -20.0;
    // cut-off index
    double ri1 = floor((dblev / 4 - b1) / a1);
    if (ri1 < static_cast<double>(i0)) {
      g_log.warning() << "Failed to build Wiener filter: no smoothing."
                      << std::endl;
      ri1 = static_cast<double>(i0);
    }
    size_t i1 = static_cast<size_t>(ri1);
    if (i1 > n2)
      i1 = n2;
    for (size_t i = i0; i < i1; ++i) {
      double s = exp(a1 * static_cast<double>(i + 1) + b1);
      wf[i] = s / (1.0 + s);
    }
    // wf[i] for i1 <= i < n2 are 0.0

    g_log.debug() << "Cut-off index " << i1 << std::endl;
  } else {
    g_log.warning() << "Power spectrum has an unexpected shape: no smoothing"
                    << std::endl;
    return copyInput(inputWS, wsIndex);
  }

  // multiply the fourier transform by the filter
  auto &re = fourierOut->dataY(0);
  auto &im = fourierOut->dataY(1);

  std::transform(re.begin(), re.end(), wf.begin(), re.begin(),
                 std::multiplies<double>());
  std::transform(im.begin(), im.end(), wf.begin(), im.begin(),
                 std::multiplies<double>());

  // inverse fourier transform
  fourier = createChildAlgorithm("RealFFT");
  fourier->initialize();
  fourier->setProperty("InputWorkspace", fourierOut);
  fourier->setProperty("IgnoreXBins", true);
  fourier->setPropertyValue("Transform", "Backward");
  fourier->execute();

  API::MatrixWorkspace_sptr out = fourier->getProperty("OutputWorkspace");
  auto &background = fitOut->readY(1);
  auto &y = out->dataY(0);

  if (y.size() != background.size()) {
    throw std::logic_error("Logic error: inconsistent arrays");
  }

  // add the spline "background" to the smoothed data
  std::transform(y.begin(), y.end(), background.begin(), y.begin(),
                 std::plus<double>());

  // copy the x-values and errors from the original spectrum
  // remove the last values for odd-sized inputs
  if (isOddSize) {
    out->dataX(0).assign(X.begin(), X.end() - 1);
    out->dataE(0).assign(E.begin(), E.end() - 1);
    out->dataY(0).resize(Y.size() - 1);
  } else {
    out->setX(0, X);
    out->dataE(0).assign(E.begin(), E.end());
  }

  return out;
}
示例#4
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/**
 * Update the cost function, derivatives and hessian by adding values calculated
 * on a domain.
 * @param function :: Function to use to calculate the value and the derivatives
 * @param domain :: The domain.
 * @param values :: The fit function values
 * @param evalFunction :: Flag to evaluate the function
 * @param evalDeriv :: Flag to evaluate the derivatives
 * @param evalHessian :: Flag to evaluate the Hessian
 */
void CostFuncLeastSquares::addValDerivHessian(
  API::IFunction_sptr function,
  API::FunctionDomain_sptr domain,
  API::FunctionValues_sptr values,
  bool evalFunction , bool evalDeriv, bool evalHessian) const
{
  UNUSED_ARG(evalDeriv);
  size_t np = function->nParams();  // number of parameters 
  size_t ny = domain->size(); // number of data points
  Jacobian jacobian(ny,np);
  if (evalFunction)
  {
    function->function(*domain,*values);
  }
  function->functionDeriv(*domain,jacobian);

  size_t iActiveP = 0;
  double fVal = 0.0;
  if (debug)
  {
    std::cerr << "Jacobian:\n";
    for(size_t i = 0; i < ny; ++i)
    {
      for(size_t ip = 0; ip < np; ++ip)
      {
        if ( !m_function->isActive(ip) ) continue;
        std::cerr << jacobian.get(i,ip) << ' ';
      }
      std::cerr << std::endl;
    }
  }
  for(size_t ip = 0; ip < np; ++ip)
  {
    if ( !function->isActive(ip) ) continue;
    double d = 0.0;
    for(size_t i = 0; i < ny; ++i)
    {
      double calc = values->getCalculated(i);
      double obs = values->getFitData(i);
      double w = values->getFitWeight(i);
      double y = ( calc - obs ) * w;
      d += y * jacobian.get(i,ip) * w;
      if (iActiveP == 0 && evalFunction)
      {
        fVal += y * y;
      }
    }
    PARALLEL_CRITICAL(der_set)
    {
      double der = m_der.get(iActiveP);
      m_der.set(iActiveP, der + d);
    }
    //std::cerr << "der " << ip << ' ' << der[iActiveP] << std::endl;
    ++iActiveP;
  }

  if (evalFunction)
  {
    PARALLEL_ATOMIC
    m_value += 0.5 * fVal;
  }

  if (!evalHessian) return;

  //size_t na = m_der.size(); // number of active parameters

  size_t i1 = 0; // active parameter index
  for(size_t i = 0; i < np; ++i) // over parameters
  {
    if ( !function->isActive(i) ) continue;
    size_t i2 = 0; // active parameter index
    for(size_t j = 0; j <= i; ++j) // over ~ half of parameters
    {
      if ( !function->isActive(j) ) continue;
      double d = 0.0;
      for(size_t k = 0; k < ny; ++k) // over fitting data
      {
        double w = values->getFitWeight(k);
        d += jacobian.get(k,i) * jacobian.get(k,j) * w * w;
      }
      PARALLEL_CRITICAL(hessian_set)
      {
        double h = m_hessian.get(i1,i2);
        m_hessian.set(i1,i2, h + d);
        //std::cerr << "hess " << i1 << ' ' << i2 << std::endl;
        if (i1 != i2)
        {
          m_hessian.set(i2,i1,h + d);
        }
      }
      ++i2;
    }
    ++i1;
  }
}
示例#5
0
/**
 * Update the cost function, derivatives and hessian by adding values calculated
 * on a domain.
 * @param function :: Function to use to calculate the value and the derivatives
 * @param domain :: The domain.
 * @param values :: The fit function values
 * @param evalDeriv :: Flag to evaluate the derivatives
 * @param evalHessian :: Flag to evaluate the Hessian
 */
void CostFuncLeastSquares::addValDerivHessian(API::IFunction_sptr function,
                                              API::FunctionDomain_sptr domain,
                                              API::FunctionValues_sptr values,
                                              bool evalDeriv,
                                              bool evalHessian) const {
  UNUSED_ARG(evalDeriv);
  function->function(*domain, *values);
  size_t np = function->nParams(); // number of parameters
  size_t ny = values->size();      // number of data points
  Jacobian jacobian(ny, np);
  function->functionDeriv(*domain, jacobian);

  size_t iActiveP = 0;
  double fVal = 0.0;
  std::vector<double> weights = getFitWeights(values);

  for (size_t ip = 0; ip < np; ++ip) {
    if (!function->isActive(ip))
      continue;
    double d = 0.0;
    for (size_t i = 0; i < ny; ++i) {
      double calc = values->getCalculated(i);
      double obs = values->getFitData(i);
      double w = weights[i];
      double y = (calc - obs) * w;
      d += y * jacobian.get(i, ip) * w;
      if (iActiveP == 0) {
        fVal += y * y;
      }
    }
    PARALLEL_CRITICAL(der_set) {
      double der = m_der.get(iActiveP);
      m_der.set(iActiveP, der + d);
    }
    ++iActiveP;
  }

  PARALLEL_ATOMIC
  m_value += 0.5 * fVal;

  if (!evalHessian)
    return;

  size_t i1 = 0;                  // active parameter index
  for (size_t i = 0; i < np; ++i) // over parameters
  {
    if (!function->isActive(i))
      continue;
    size_t i2 = 0;                  // active parameter index
    for (size_t j = 0; j <= i; ++j) // over ~ half of parameters
    {
      if (!function->isActive(j))
        continue;
      double d = 0.0;
      for (size_t k = 0; k < ny; ++k) // over fitting data
      {
        double w = weights[k];
        d += jacobian.get(k, i) * jacobian.get(k, j) * w * w;
      }
      PARALLEL_CRITICAL(hessian_set) {
        double h = m_hessian.get(i1, i2);
        m_hessian.set(i1, i2, h + d);
        if (i1 != i2) {
          m_hessian.set(i2, i1, h + d);
        }
      }
      ++i2;
    }
    ++i1;
  }
}