Example #1
0
    def addcellpeaks(self, limit=None):
        """
        Adds unit cell predicted peaks for fitting against
        Optional arg limit gives highest angle to use

        Depends on parameters:
            'cell__a','cell__b','cell__c', 'wavelength' # in angstrom
            'cell_alpha','cell_beta','cell_gamma' # in degrees
            'cell_lattice_[P,A,B,C,I,F,R]'
        """
        #
        # Given unit cell, wavelength and distance, compute the radial positions
        # in microns of the unit cell peaks
        #
        pars = self.parameterobj.get_parameters()
        cell = [
            pars[name] for name in [
                'cell__a', 'cell__b', 'cell__c', 'cell_alpha', 'cell_beta',
                'cell_gamma'
            ]
        ]
        lattice = pars['cell_lattice_[P,A,B,C,I,F,R]']
        if "tth" not in self.colfile.titles:
            self.compute_tth_eta()
        # Find last peak in radius
        if limit is None:
            highest = numpy.maximum.reduce(self.getcolumn("tth"))
        else:
            highest = limit
        w = pars['wavelength']
        ds = 2 * numpy.sin(transform.radians(highest) / 2.) / w
        self.dslimit = ds
        self.unitcell = unitcell.unitcell(cell, lattice)
        # If the space group is provided use xfab for generate unique hkls
        if 'cell_sg' in pars:
            self.theorypeaks = self.unitcell.gethkls_xfab(ds, pars['cell_sg'])
            tths = []
            self.theoryds = []
            for i in range(len(self.theorypeaks)):
                tths.append(2 * numpy.arcsin(w * self.theorypeaks[i][0] / 2.))
                self.theoryds.append(self.theorypeaks[i][0])
        else:
            # HO:  I have removed this part as it seems redundant ringds also calls gethkls
            # JPW: It was not redundant. theorypeaks is not defined anywhere else and you
            #      can't write a g-vector file without it.
            self.theorypeaks = self.unitcell.gethkls(ds)
            self.unitcell.makerings(ds)
            self.theoryds = self.unitcell.ringds
            tths = [
                numpy.arcsin(w * dstar / 2) * 2
                for dstar in self.unitcell.ringds
            ]
        self.theorytth = transform.degrees(numpy.array(tths))
Example #2
0
    def gof(self, args):
        """ Compute how good is the fit of obs/calc peak positions in tth """
        self.applyargs(args)
        # Here, pars is a dictionary of name/value pairs to pass to compute_tth_eta
        tth, eta = self.compute_tth_eta()
        w = self.parameterobj.get("wavelength")
        gof = 0.
        npeaks = 0
        for i in range(len(self.tthc)):# (twotheta_rad_cell.shape[0]):
            self.tthc[i] = transform.degrees(math.asin(self.fitds[i] * w / 2) * 2)
            diff = numpy.take(tth, self.indices[i]) - self.tthc[i]
#         print "peak",i,"diff",maximum.reduce(diff),minimum.reduce(diff)
            gof = gof + numpy.sum(diff * diff)
            npeaks = npeaks + len(diff)
        gof = gof / npeaks
        return gof * 1e6