Exemplo n.º 1
0
def fix_spe(spe_file):

    entry = NXentry()
    entry.title = spe_file.nxname
    entry.incident_energy = spe_file['data/NXSPE_info/fixed_energy']
    entry.data = spe_file.data.data
    entry.data.error.rename('errors')

    s = raw_input("Emin Emax Phimin Phimax dPhi: ")
    xmin, xmax, ymin, ymax, dy = [float(i) for i in s.split(' ')]
    mfit(entry.data, xmin, xmax, ymin, ymax, dy)

    return entry
Exemplo n.º 2
0
def fix_spe(spe_file):

    entry = NXentry()
    entry.title = spe_file.nxname
    entry.incident_energy = spe_file['data/NXSPE_info/fixed_energy']
    entry.data = spe_file.data.data
    entry.data.error.rename('errors')

    s = raw_input("Emin Emax Phimin Phimax dPhi: ")
    xmin, xmax, ymin, ymax, dy = [float(i) for i in s.split(' ')]    
    mfit(entry.data, xmin, xmax, ymin, ymax, dy)
    
    return entry
Exemplo n.º 3
0
Arquivo: cflib.py Projeto: N1l0c/cflib
    def NXspectrum(self, eps=None, sigma=None, T=None, Hx=None, Hz=None):
        """Returns the neutron scattering cross section as a NXentry group"""

        from nexusformat.nexus import NXfield, NXentry, NXsample, NXdata

        if T is None:
            T = self.T
        S = self.spectrum(eps, sigma, T, Hx, Hz)
        entry = NXentry()
        entry.title = "Crystal Field Spectra for %s at %s K" % (self.title, T)
        entry.sample = NXsample()
        entry.sample.temperature = T
        entry.sample.temperature.units = "K"
        entry.data = NXdata(NXfield(S, name="intensity", units="mb/sr/meV"),
                            NXfield(eps, name="energy_transfer", units="meV"))
        return entry
Exemplo n.º 4
0
 def get_nxspe(self):
     spe_file = nxload(self.import_file)
     entry = NXentry()
     entry.title = self.get_title()
     Ei = self.get_energy()
     if Ei and Ei > 0.0:
         entry.instrument = NXinstrument()
         entry.instrument.monochromator = NXmonochromator(
             NXfield(Ei, name="incident_energy", units="meV"))
     entry.data = spe_file.NXentry[0].data
     entry.data.nxsignal = entry.data.data
     if 'energy' in entry.data.entries:
         entry.data.energy.rename('energy_transfer')
     entry.data.nxaxes = [entry.data.polar, entry.data.energy_transfer]
     if 'error' in entry.data.entries:
         entry.data.error.rename('errors')
     return entry
Exemplo n.º 5
0
 def get_spe(self, phxfile=None):
     entry = NXentry()
     phi, omega, spw, errors = readspe(self.get_filename())
     if phxfile:
         theta, phi, dtheta, dpsi = readphx(phxfile)
         phip, psi = angles(theta, phi)
         instrument = NXinstrument(NXdetector())
         instrument.detector.polar_angle = NXfield(theta, units="degrees")
         Ei = self.get_energy()
         if Ei and Ei > 0.0:
             instrument.monochromator = NXmonochromator(
                 NXfield(Ei, name="incident_energy", units="meV"))
         if phi.ptp() > 1.0:  # i.e., the azimuthal angle is specified
             instrument.detector.azimuthal_angle = NXfield(
                 phi, units="degrees")
             instrument.detector.rotation_angle = NXfield(
                 phip, units="degrees")
             instrument.detector.tilt_angle = NXfield(psi, units="degrees")
             data = NXdata(
                 NXfield(
                     spw, name="intensity",
                     long_name="Neutron Intensity"),
                 (
                     NXfield(
                         np.arange(1, len(theta) + 1),
                         name="spectrum_index",
                         long_name="Spectrum Index"),
                     NXfield(
                         omega, name="energy_transfer", units="meV",
                         long_name="Energy Transfer")),
                 errors=NXfield(
                     np.sqrt(errors),
                     name="errors", long_name="Errors"))
             if np.median(dtheta) > 0.0 and np.median(dpsi) > 0.0:
                 data2D = rebin2D(
                     spw, phip, psi, omega, np.median(dtheta),
                     np.median(dpsi))
                 return NXentry(instrument, data, data2D=data2D)
             else:
                 return NXentry(instrument, data)
         else:
             phi = np.zeros(theta.size+1)
             phi[:-1] = theta - 0.5*dtheta
             phi[-1] = theta[-1] + 0.5*dtheta[-1]
             data = NXdata(
                 NXfield(
                     spw, name="intensity",
                     long_name="Neutron Intensity"),
                 (
                     NXfield(
                         phi, name="polar_angle",
                         long_name="Polar Angle", units="degrees"),
                     NXfield(
                         omega, name="energy_transfer", units="meV",
                         long_name="Energy Transfer")),
                 errors=NXfield(
                     np.sqrt(errors),
                     name="errors", long_name="Errors"))
             return NXentry(instrument, data)
     else:
         Ei = self.get_energy()
         if Ei and Ei > 0.0:
             entry = NXentry(
                 NXinstrument(
                     NXmonochromator(
                         NXfield(
                             Ei, name="incident_energy",
                             units="meV"))))
         else:
             entry = NXentry()
         if phi.ptp() > 1.0:
             entry.data = NXdata(
                 NXfield(spw, name="intensity",
                         long_name="Neutron Intensity"),
                 (NXfield(phi, name="polar_angle", units="degrees",
                          long_name="Polar Angle"),
                     NXfield(omega, name="energy_transfer", units="meV",
                             long_name="Energy Transfer")),
                 errors=NXfield(np.sqrt(errors), name="errors",
                                long_name="Errors"))
         else:
             entry.data = NXdata(
                 NXfield(spw, name="intensity",
                         long_name="Neutron Intensity"),
                 (NXfield(np.arange(1, len(phi)+1), name="spectrum_index",
                          long_name="Spectrum Index"),
                     NXfield(omega, name="energy_transfer", units="meV",
                             long_name="Energy Transfer")),
                 errors=NXfield(np.sqrt(errors), name="errors",
                                long_name="Errors"))
         return entry