Ejemplo n.º 1
0
    def guess_fwhm(self, **kw):
        if 'y' in kw:
            y=kw['y']
        else:
            return self.config['FwhmPoints']
        if 'x' in kw:
            x=kw['x']
        else:
            x=numpy.arange(len(y))*1.0

        #set at least a default value for the fwhm    
        fwhm=4

        zz=SpecfitFuns.subac(y,1.000,1000)
        yfit=y-zz
        
        #now I should do some sort of peak search ...
        maximum = max(yfit)
        idx = numpy.nonzero(yfit == maximum)[0]
        pos = numpy.take(x,idx)[-1]
        posindex = idx[-1]
        height = yfit[posindex]
        imin = posindex
        while ((yfit[imin] > 0.5*height) & (imin >0)):
            imin=imin - 1
        imax=posindex
        while ((yfit[imax] > 0.5*height) & (imax <(len(yfit)-1))):
            imax=imax + 1
        fwhm=max(imax-imin-1,fwhm)
            
        return fwhm            
Ejemplo n.º 2
0
 def bkg_internal(self,pars,x):
    """
    Internal Background
    """
    #fast
    #return self.zz  
    #slow: recalculate the background as function of the parameters
    #yy=SpecfitFuns.subac(self.ydata*self.fitconfig['Yscaling'],
    #                     pars[0],pars[1])
    yy=SpecfitFuns.subac(self.ydata*1.0,
                         pars[0],pars[1])
    nrx=shape(x)[0]
    nry=shape(yy)[0]
    if nrx == nry:
         return SpecfitFuns.subac(yy,pars[0],pars[1])
    else:
         return SpecfitFuns.subac(numpy.take(yy,numpy.arange(0,nry,2)),pars[0],pars[1])
    def interpolate(self, factor=1.):
        '''
        Input
        -----
        factor : float
            factor used to oversample existing data, use
            with caution.
        
        Interpolates all existing curves to an equidistant
        x-range using the either the active or the first
        curve do determine the number of data points.
        Use this method instead of self.getAllCurves() when
        performin FFT related tasks.
        
        Returns
        -------
        interpCurves : ndarray
            Array containing the interpolated curves shown
            in the plot window. 
            Format: [(x0, y0, legend0, info0), ...]
        '''
        curves = self.getAllCurves()
        if len(curves) < 1:
            raise ValueError("At least 1 curve needed")
            if DEBUG:
                print('interpolate -- no curves present')
            return

        activeCurve = self.getActiveCurve()
        if not activeCurve:
            activeCurve = curves[0]
        else:
            activeLegend = activeCurve[2]
            idx = list.index([curve[2] for curve in curves],
                             activeLegend)
            activeCurve = curves[idx]
        activeX, activeY, activeLegend, activeInfo = activeCurve[0:4]
        
        # Determine average spaceing between Datapoints
        step = numpy.average(numpy.diff(activeX))
        xmin, xmax = self.getXLimits([x for (x,y,leg,info) in curves],
                                     overlap=False)
        num  = factor * numpy.ceil((xmax-xmin)/step)
        
        # Create equidistant x-range, exclude first and last point
        xeq = numpy.linspace(xmin, xmax, num, endpoint=False)[:-1]
        
        # Interpolate on sections of xeq
        interpCurves = []
        for (x,y,legend,info) in curves:
            idx = numpy.nonzero((x.min()<xeq) & (xeq<x.max()))[0]
            xi = numpy.take(xeq, idx)
            yi = SpecfitFuns.interpol([x], y, xi.reshape(-1,1), y.min())
            yi.shape = -1
            interpCurves += [(xi, yi, legend, info)]
        return interpCurves
Ejemplo n.º 4
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 def periodic_gauss(self, pars, x):
     """
     Fit function periodic_gauss(pars, x)
     pars = [npeaks, delta, height, position, fwhm]
     """
     newpars = numpy.zeros((pars[0], 3), numpy.float)
     for i in range(int(pars[0])):
         newpars[i, 0] = pars[2]
         newpars[i, 1] = pars[3] + i * pars[1]
         newpars[:, 2] = pars[4]
     return SpecfitFuns.gauss(newpars,x)
Ejemplo n.º 5
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def estimateXANESEdge(spectrum, energy=None, full=False):
    if energy is None:
        x = numpy.arange(len(spectrum)).astype(numpy.float)
    else:
        x = numpy.array(energy, dtype=numpy.float, copy=True)
    y = numpy.array(spectrum, dtype=numpy.float, copy=True)

    # make sure data are sorted
    idx = energy.argsort(kind='mergesort')
    x = numpy.take(energy, idx)
    y = numpy.take(spectrum, idx)

    # make sure data are strictly increasing
    delta = x[1:] - x[:-1]
    dmin = delta.min()
    dmax = delta.max()
    if delta.min() <= 1.0e-10:
        # force data are strictly increasing
        # although we do not consider last point
        idx = numpy.nonzero(delta>0)[0]
        x = numpy.take(x, idx)
        y = numpy.take(y, idx)
        delta = None

    sortedX = x
    sortedY = y

    # use a regularly spaced spectrum
    if dmax != dmin:
        # choose the number of points or deduce it from
        # the input data length?
        nchannels = 5 * len(spectrum)
        xi = numpy.linspace(x[1], x[-2], nchannels).reshape(-1, 1)
        x.shape = -1
        y.shape = -1
        y = SpecfitFuns.interpol([x], y, xi, y.min())
        x = xi
        x.shape = -1
        y.shape = -1

    # take the first derivative
    npoints = 7
    xPrime = x[npoints:-npoints]
    yPrime = SGModule.getSavitzkyGolay(y, npoints=npoints, degree=2, order=1)
    
    # get the index at maximum value
    iMax = numpy.argmax(yPrime)

    if full:
        # return intermediate information
        return x[iMax], sortedX, sortedY, xPrime, yPrime
    else:
        # return the corresponding x value
        return x[iMax]
Ejemplo n.º 6
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 def _getSmooth(self, x, y): 
     f=[0.25,0.5,0.25]
     try:
         if hasattr(y, "shape"):
             if len(y.shape) > 1:
                 result=SpecfitFuns.SavitskyGolay(numpy.ravel(y).astype(numpy.float), 
                                 self._fitConfiguration['fit']['stripfilterwidth'])
             else:                                
                 result=SpecfitFuns.SavitskyGolay(numpy.array(y).astype(numpy.float), 
                                 self._fitConfiguration['fit']['stripfilterwidth'])
         else:
             result=SpecfitFuns.SavitskyGolay(numpy.array(y).astype(numpy.float),
                                 self._fitConfiguration['fit']['stripfilterwidth'])
     except:
         err = sys.exc_info()[1]
         raise ValueError("Unsuccessful Savitsky-Golay smoothing: %s" % err)
         result=numpy.array(y).astype(numpy.float)
     if len(result) > 1:
         result[1:-1]=numpy.convolve(result,f,mode=0)
         result[0]=0.5*(result[0]+result[1])
         result[-1]=0.5*(result[-1]+result[-2])
     return result
Ejemplo n.º 7
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def test():
    import numpy
    from PyMca import SpecfitFuns
    x = numpy.arange(1000.)
    data = numpy.zeros((50, 1000), numpy.float)

    #the peaks to be fitted
    p0 = [100., 300., 50., 200., 500., 30., 300., 800., 65]

    #generate the data to be fitted
    for i in range(data.shape[0]):
        nPeaks = 3 - i % 3
        data[i, :] = SpecfitFuns.gauss(p0[:3 * nPeaks], x)

    oldShape = data.shape
    data.shape = 1, oldShape[0], oldShape[1]

    instance = StackSimpleFit()
    instance.setData(x, data)
    instance.setConfigurationFile("C:\StackSimpleFit.cfg")
    instance.processStack()
Ejemplo n.º 8
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def test():
    import numpy
    from PyMca import SpecfitFuns
    x = numpy.arange(1000.)
    data = numpy.zeros((50, 1000), numpy.float)

    #the peaks to be fitted
    p0 = [100., 300., 50.,
          200., 500., 30.,
          300., 800., 65]

    #generate the data to be fitted
    for i in range(data.shape[0]):
        nPeaks = 3 - i % 3
        data[i,:] = SpecfitFuns.gauss(p0[:3*nPeaks],x)

    oldShape = data.shape
    data.shape = 1,oldShape[0], oldShape[1]

    instance = StackSimpleFit()
    instance.setData(x, data)
    instance.setConfigurationFile("C:\StackSimpleFit.cfg")
    instance.processStack()
Ejemplo n.º 9
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    def seek(self,y,x=None,yscaling=None,
                           fwhm=None,
                           sensitivity=None,
                           mca=None):
        """
        SpecfitFunctions.seek(self,y,
                                x=None,
                                yscaling=None,fwhm=None,sensitivity=None,
                                mca=None)
        It searches for peaks in the y array. If x it is given, it gives back
        the closest x(s) to the position of the peak(s). Otherways it gives back
        the index of the closest point to the peak.
        """
        if yscaling is None:
            yscaling=self.config['Yscaling']
        
        if fwhm is None:
            if self.config['AutoFwhm']:
                fwhm=self.guess_fwhm(x=x,y=y)            
            else:
                fwhm=self.config['FwhmPoints']
        if sensitivity is None:
            sensitivity=self.config['Sensitivity']
        if mca is None:
            mca=self.config['McaMode']

        search_fwhm=int(max(fwhm,3))
        search_sensitivity=max(1.0,sensitivity)
        mca=1.0        
        if mca:
            ysearch = numpy.array(y) * yscaling
        else:
            ysearch = numpy.ones([len(y) + 2 * search_fwhm,], numpy.float)
            if y[0]:
                ysearch[0:(search_fwhm+1)]=ysearch[0:(search_fwhm+1)]*y[0]*yscaling
            else:
                ysearch[0:(search_fwhm+1)]=ysearch[0:(search_fwhm+1)]*yscaling*sum(y[0:3])/3.0
            ysearch[-1:-(search_fwhm+1):-1]=ysearch[-1:-(search_fwhm+1):-1]*y[len(y)-1]*yscaling
            ysearch[search_fwhm:(search_fwhm+len(y))]=y*yscaling
        npoints=len(ysearch)
        if npoints > (1.5)*search_fwhm:
            peaks=SpecfitFuns.seek(ysearch,0,npoints,
                                    search_fwhm,
                                    search_sensitivity)
        else:
            peaks=[]
        
        if len(peaks) > 0:
            if mca == 0:
                for i in range(len(peaks)):
                    peaks[i]=int(peaks[i]-search_fwhm)
            for i in peaks:
                if (i < 1) | (i > (npoints-1)):
                    peaks.remove(i) 
            if x is not None:
                if len(x) == len(y):
                    for i in range(len(peaks)):
                        peaks[i]=x[int(max(peaks[i],0))]
        #print "peaks found = ",peaks,"mca =",mca,"fwhm=",search_fwhm,\
        #        "sensi=",search_sensitivity,"scaling=",yscaling
        return peaks
        self.connect(self.dismissButton, qt.SIGNAL("clicked()"), self.reject)
        self.connect(self.okButton, qt.SIGNAL("clicked()"), self.accept)

    def getParameters(self):
        parametersDict = self.parametersWidget.getParameters()
        return parametersDict

    def setParameters(self, ddict):
        return self.parametersWidget.setParameters(ddict)


if __name__ == "__main__":
    app = qt.QApplication([])
    if len(sys.argv) > 1:
        from PyMca import specfilewrapper as specfile
        sf = specfile.Specfile(sys.argv[1])
        scan = sf[0]
        data = scan.data()
        energy = data[0, :]
        spectrum = data[1, :]
        w = XASNormalizationDialog(None, spectrum, energy=energy)
    else:
        from PyMca import SpecfitFuns
        noise = numpy.random.randn(1500.)
        x = 8000. + numpy.arange(1500.)
        y = SpecfitFuns.upstep([100, 8500., 50], x)
        w = XASNormalizationDialog(None, y + numpy.sqrt(y) * noise, energy=x)
    ret = w.exec_()
    if ret:
        print(w.getParameters())
Ejemplo n.º 11
0
    def update(self):
        if self._y is None:
            return

        pars = self.getParameters()

        #smoothed data
        y = numpy.ravel(numpy.array(self._y)).astype(numpy.float)
        ysmooth = SpecfitFuns.SavitskyGolay(y, pars['stripfilterwidth'])
        f = [0.25, 0.5, 0.25]
        ysmooth[1:-1] = numpy.convolve(ysmooth, f, mode=0)
        ysmooth[0] = 0.5 * (ysmooth[0] + ysmooth[1])
        ysmooth[-1] = 0.5 * (ysmooth[-1] + ysmooth[-2])

        #loop for anchors
        x = self._x
        niter = pars['stripiterations']
        anchorslist = []
        if pars['stripanchorsflag']:
            if pars['stripanchorslist'] is not None:
                ravelled = x
                for channel in pars['stripanchorslist']:
                    if channel <= ravelled[0]: continue
                    index = numpy.nonzero(ravelled >= channel)[0]
                    if len(index):
                        index = min(index)
                        if index > 0:
                            anchorslist.append(index)
        if niter > 1000:
            stripBackground = SpecfitFuns.subac(ysmooth, pars['stripconstant'],
                                                niter, pars['stripwidth'],
                                                anchorslist)
            #final smoothing
            stripBackground = SpecfitFuns.subac(stripBackground,
                                                pars['stripconstant'], 500, 1,
                                                anchorslist)
        elif niter > 0:
            stripBackground = SpecfitFuns.subac(ysmooth, pars['stripconstant'],
                                                niter, pars['stripwidth'],
                                                anchorslist)
        else:
            stripBackground = 0.0 * ysmooth + ysmooth.min()

        if len(anchorslist) == 0:
            anchorslist = [0, len(ysmooth) - 1]
        anchorslist.sort()
        snipBackground = 0.0 * ysmooth
        lastAnchor = 0
        width = pars['snipwidth']
        for anchor in anchorslist:
            if (anchor > lastAnchor) and (anchor < len(ysmooth)):
                snipBackground[lastAnchor:anchor] =\
                            SpecfitFuns.snip1d(ysmooth[lastAnchor:anchor], width, 0)
                lastAnchor = anchor
        if lastAnchor < len(ysmooth):
            snipBackground[lastAnchor:] =\
                            SpecfitFuns.snip1d(ysmooth[lastAnchor:], width, 0)

        self.graphWidget.addCurve(x, y, \
                                  legend='Input Data',\
                                  replace=True,
                                  replot=False)
        self.graphWidget.addCurve(x, stripBackground,\
                                  legend='Strip Background',\
                                  replot=False)
        self.graphWidget.addCurve(x, snipBackground,\
                                  legend='SNIP Background',
                                  replot=True)
    def XASNormalize(self):
        #all curves
        curves = self.getAllCurves()
        nCurves = len(curves)
        if nCurves < 1:
            raise ValueError("At least one curve needed")
            return

        #get active curve
        activeCurve = self.getActiveCurve()
        if activeCurve is None:
            raise ValueError("Please select an active curve")
            return

        x, y, legend0, info = activeCurve

        #sort the values
        idx = numpy.argsort(x, kind='mergesort')
        x0 = numpy.take(x, idx)
        y0 = numpy.take(y, idx)
        xmin, xmax = self.getGraphXLimits()

        # get calculation parameters
        if self.widget is None:
            self._createWidget(y0, x0)

        parameters = self.parameters
        if parameters['auto_edge']:
            edge = None
        else:
            edge = parameters['edge_energy']
        energy = x
        pre_edge_regions = parameters['pre_edge']['regions']
        post_edge_regions = parameters['post_edge']['regions']
        algorithm = 'polynomial'
        algorithm_parameters = {}
        algorithm_parameters['pre_edge_order'] = parameters['pre_edge']\
                                                         ['polynomial']
        algorithm_parameters['post_edge_order'] = parameters['post_edge']\
                                                         ['polynomial']
        i = 0
        lastCurve = None
        for curve in curves:
            x, y, legend, info = curve[0:4]
            #take the portion ox x between limits
            idx = numpy.nonzero((x >= xmin) & (x <= xmax))[0]
            if not len(idx):
                #no overlap
                continue
            x = numpy.take(x, idx)
            y = numpy.take(y, idx)

            idx = numpy.nonzero((x0 >= x.min()) & (x0 <= x.max()))[0]
            if not len(idx):
                #no overlap
                continue
            xi = numpy.take(x0, idx)
            yi = numpy.take(y0, idx)

            #perform interpolation
            xi.shape = -1, 1
            yw = SpecfitFuns.interpol([x], y, xi, yi.min())

            # try: ... except: here?
            yw.shape = -1
            xi.shape = -1
            x, y = XASNormalization.XASNormalization(
                yw,
                energy=xi,
                edge=edge,
                pre_edge_regions=pre_edge_regions,
                post_edge_regions=post_edge_regions,
                algorithm=algorithm,
                algorithm_parameters=algorithm_parameters)[0:2]
            #
            if i == 0:
                replace = True
                replot = True
                i = 1
            else:
                replot = False
                replace = False
            newLegend = " ".join(legend.split(" ")[:-1])
            if not newLegend.startswith('Norm.'):
                newLegend = "Norm. " + newLegend
            self.addCurve(x,
                          y,
                          legend=newLegend,
                          info=info,
                          replot=replot,
                          replace=replace)
            lastCurve = [x, y, newLegend]
        self.addCurve(lastCurve[0],
                      lastCurve[1],
                      legend=lastCurve[2],
                      info=info,
                      replot=True,
                      replace=False)
Ejemplo n.º 13
0
 def stepup(self,pars,x):
     """
     A fit function.
     """
     return 0.5*SpecfitFuns.upstep(pars,x)
Ejemplo n.º 14
0
 def slit(self,pars,x):
     """
     A fit function.
     """
     return 0.5*SpecfitFuns.slit(pars,x)
Ejemplo n.º 15
0
    def fftAlignment(self):
        curves = self.getAllCurves()
        nCurves = len(curves)
        if nCurves < 2:
            raise ValueError("At least 2 curves needed")
            return

        # get active curve
        activeCurve = self.getActiveCurve()
        if activeCurve is None:
            activeCurve = curves[0]

        # apply between graph limits
        x0 = activeCurve[0][:]
        y0 = activeCurve[1][:]
        xmin, xmax = self.getGraphXLimits()
        idx = numpy.nonzero((x0 >= xmin) & (x0 <= xmax))[0]
        x0 = numpy.take(x0, idx)
        y0 = numpy.take(y0, idx)

        #sort the values
        idx = numpy.argsort(x0, kind='mergesort')
        x0 = numpy.take(x0, idx)
        y0 = numpy.take(y0, idx)

        #remove duplicates
        x0 = x0.ravel()
        idx = numpy.nonzero((x0[1:] > x0[:-1]))[0]
        x0 = numpy.take(x0, idx)
        y0 = numpy.take(y0, idx)

        #make sure values are regularly spaced
        xi = numpy.linspace(x0[0], x0[-1], len(idx)).reshape(-1, 1)
        yi = SpecfitFuns.interpol([x0], y0, xi, y0.min())
        x0 = xi
        y0 = yi

        y0.shape = -1
        fft0 = numpy.fft.fft(y0)
        y0.shape = -1, 1
        x0.shape = -1, 1
        nChannels = x0.shape[0]

        # built a couple of temporary array of spectra for handy access
        tmpArray = numpy.zeros((nChannels, nCurves), numpy.float)
        fftList = []
        shiftList = []
        curveList = []
        i = 0
        for idx in range(nCurves):
            x, y, legend, info = curves[idx][0:4]
            #sort the values
            x = x[:]
            idx = numpy.argsort(x, kind='mergesort')
            x = numpy.take(x, idx)
            y = numpy.take(y, idx)

            #take the portion of x between limits
            idx = numpy.nonzero((x >= xmin) & (x <= xmax))[0]
            if not len(idx):
                # no overlap
                continue
            x = numpy.take(x, idx)
            y = numpy.take(y, idx)

            #remove duplicates
            x = x.ravel()
            idx = numpy.nonzero((x[1:] > x[:-1]))[0]
            x = numpy.take(x, idx)
            y = numpy.take(y, idx)
            x.shape = -1, 1
            if numpy.allclose(x, x0):
                # no need for interpolation
                pass
            else:
                # we have to interpolate
                x.shape = -1
                y.shape = -1
                xi = x0[:]
                y = SpecfitFuns.interpol([x], y, xi, y0.min())
            y.shape = -1
            tmpArray[:, i] = y
            i += 1

            # now calculate the shift
            ffty = numpy.fft.fft(y)
            fftList.append(ffty)
            if 0:
                self.addCurve(x,
                              y,
                              legend="NEW Y%d" % i,
                              info=None,
                              replot=True,
                              replace=False)
            elif numpy.allclose(fft0, ffty):
                shiftList.append(0.0)
            else:
                shift = numpy.fft.ifft(fft0 * ffty.conjugate()).real
                shift2 = numpy.zeros(shift.shape, dtype=shift.dtype)
                m = shift2.size // 2
                shift2[m:] = shift[:-m]
                shift2[:m] = shift[-m:]
                if 0:
                    self.addCurve(numpy.arange(len(shift2)),
                                  shift2,
                                  legend="SHIFT",
                                  info=None,
                                  replot=True,
                                  replace=False)
                threshold = 0.50 * shift2.max()
                #threshold = shift2.mean()
                idx = numpy.nonzero(shift2 > threshold)[0]
                #print("max indices = %d" % (m - idx))
                shift = (shift2[idx] * idx / shift2[idx].sum()).sum()
                #print("shift = ", shift - m, "in x units = ", (shift - m) * (x[1]-x[0]))

                # shift the curve
                shift = (shift - m) * (x[1] - x[0])
                x.shape = -1
                y = numpy.fft.ifft(numpy.exp(-2.0*numpy.pi*numpy.sqrt(numpy.complex(-1))*\
                                numpy.fft.fftfreq(len(x), d=x[1]-x[0])*shift)*numpy.fft.fft(y))
                y = y.real
                y.shape = -1
            curveList.append([x, y, legend + "SHIFT", False, False])
        tmpArray = None
        curveList[-1][-2] = True
        curveList[-1][-1] = False
        x, y, legend, replot, replace = curveList[0]
        self.addCurve(x, y, legend=legend, replot=True, replace=True)
        for i in range(1, len(curveList)):
            x, y, legend, replot, replace = curveList[i]
            self.addCurve(x,
                          y,
                          legend=legend,
                          info=None,
                          replot=replot,
                          replace=False)
        return

        # now get the final spectrum
        y = medianSpectra.sum(axis=1) / nCurves
        x0.shape = -1
        y.shape = x0.shape
        legend = "%d Median from %s to %s" % (width, curves[0][2],
                                              curves[-1][2])
        self.addCurve(x0,
                      y,
                      legend=legend,
                      info=None,
                      replot=True,
                      replace=True)
Ejemplo n.º 16
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 def hypermet(self,pars,x):
    """
    A fit function.
    """
    return SpecfitFuns.ahypermet(pars,x,self.config['HypermetTails'],0)
 def stepDown(self, pars, x):
     """
     Complementary error function like.
     """
     return 0.5 * SpecfitFuns.downstep(pars, x)
 def slit(self, pars, x):
     """
     Function to calulate slit width and knife edge cut
     """
     return 0.5 * SpecfitFuns.slit(pars, x)
Ejemplo n.º 19
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    def estimate_periodic_gauss(self,xx,yy,zzz,xscaling=1.0,yscaling=None):
        if yscaling == None:
            try:
                yscaling=self.config['Yscaling']
            except:
                yscaling=1.0
        if yscaling == 0:
            yscaling=1.0
        fittedpar=[]
        zz=SpecfitFuns.subac(yy,1.000,10000)
       
        npoints = len(zz)
        if self.config['AutoFwhm']:
            search_fwhm=self.guess_fwhm(x=xx,y=yy)
        else: 
            search_fwhm=int(float(self.config['FwhmPoints']))
        search_sens=float(self.config['Sensitivity'])
        search_mca=int(float(self.config['McaMode']))
       
        if search_fwhm < 3:
            search_fwhm = 3
            self.config['FwhmPoints']=3
       
        if search_sens < 1:
            search_sens = 1
            self.config['Sensitivity']=1
            
        if npoints > 1.5*search_fwhm:
            peaks=self.seek(yy,fwhm=search_fwhm,
                               sensitivity=search_sens,
                               yscaling=yscaling,
                               mca=search_mca)
        else:
             peaks = []
        npeaks = len(peaks)
        if not npeaks:
            fittedpar = []
            cons = numpy.zeros((3,len(fittedpar)), numpy.float)
            return fittedpar, cons

        fittedpar = [0.0, 0.0, 0.0, 0.0, 0.0]

        #The number of peaks
        fittedpar[0] = npeaks

        #The separation between peaks in x units
        delta  = 0.0
        height = 0.0
        for i in range(npeaks):
            height += yy[int(peaks[i])] - zz [int(peaks[i])]
            if i != ((npeaks)-1):
                delta += (xx[int(peaks[i+1])] - xx[int(peaks[i])])

        #delta between peaks
        if npeaks > 1:
            fittedpar[1] = delta/(npeaks-1)

        #starting height
        fittedpar[2] = height/npeaks

        #position of the first peak
        fittedpar[3] = xx[int(peaks[0])]

        #Estimate the fwhm
        fittedpar[4] = search_fwhm

        #setup constraints
        cons = numpy.zeros((3, 5), numpy.float)
        cons [0] [0] = CFIXED     #the number of gaussians
        if npeaks == 1:
            cons[0][1] = CFIXED  #the delta between peaks
        else: 
            cons[0][1] = CFREE   #the delta between peaks
        j = 2
        #Setup height area constrains
        if self.config['NoConstrainsFlag'] == 0:
            if self.config['HeightAreaFlag']:
                #POSITIVE = 1
                cons[0] [j] = 1
                cons[1] [j] = 0
                cons[2] [j] = 0
        j=j+1
                
        #Setup position constrains
        if self.config['NoConstrainsFlag'] == 0:
            if self.config['PositionFlag']:
                        #QUOTED = 2
                        cons[0][j]=2
                        cons[1][j]=min(xx)
                        cons[2][j]=max(xx) 
        j=j+1
        
        #Setup positive FWHM constrains
        if self.config['NoConstrainsFlag'] == 0:
            if self.config['PosFwhmFlag']:
                        #POSITIVE=1
                        cons[0][j]=1
                        cons[1][j]=0
                        cons[2][j]=0
        j=j+1
        return fittedpar,cons 
Ejemplo n.º 20
0
 def alorentz(self,pars,x):
    """
    Fit function.
    """
    return SpecfitFuns.alorentz(pars,x)
Ejemplo n.º 21
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 def lorentz(self,pars,x):
    """
    Fit function.
    """
    #return pars[0] + pars [1] * x + SpecfitFuns.lorentz(pars[2:len(pars)],x)
    return SpecfitFuns.lorentz(pars,x)
Ejemplo n.º 22
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    def estimate_gauss(self,xx,yy,zzz,xscaling=1.0,yscaling=None):
       if yscaling == None:
            try:
                yscaling=self.config['Yscaling']
            except:
                yscaling=1.0
       if yscaling == 0:
            yscaling=1.0
       fittedpar=[]
       zz=SpecfitFuns.subac(yy,1.000,10000)
       
       npoints = len(zz)
       if self.config['AutoFwhm']:
            search_fwhm=self.guess_fwhm(x=xx,y=yy)
       else: 
            search_fwhm=int(float(self.config['FwhmPoints']))
       search_sens=float(self.config['Sensitivity'])
       search_mca=int(float(self.config['McaMode']))
       
       if search_fwhm < 3:
            search_fwhm = 3
            self.config['FwhmPoints']=3
       
       if search_sens < 1:
            search_sens = 1
            self.config['Sensitivity']=1
            
       if npoints > 1.5*search_fwhm:
            peaks=self.seek(yy,fwhm=search_fwhm,
                               sensitivity=search_sens,
                               yscaling=yscaling,
                               mca=search_mca)
            #print "estimate peaks = ",peaks
            #peaks=self.seek(yy-zz,fwhm=search_fwhm,
            #                   sensitivity=search_sens,
            #                   yscaling=yscaling,
            #                   mca=search_mca)
       else:
            peaks = []
       if not len(peaks):
            mca = int(float(self.config.get('McaMode', 0)))
            forcePeak =  int(float(self.config.get('ForcePeakPresence', 0)))
            if (not mca) and forcePeak:
                delta = yy - zz
                peaks  = [int(numpy.nonzero(delta == delta.max())[0])]
                
       #print "peaks = ",peaks
       #print "peaks subac = ",self.seek(yy-zz,fwhm=search_fwhm,
       #                        sensitivity=search_sens,
       #                        yscaling=yscaling,
       #                        mca=search_mca)
       largest_index = 0
       if len(peaks) > 0:
            j = 0
            for i in peaks:
                if j == 0:
                    sig=5*abs(xx[npoints-1]-xx[0])/npoints
                    peakpos = xx[int(i)]
                    if abs(peakpos) < 1.0e-16:
                        peakpos = 0.0
                    param = numpy.array([yy[int(i)] - zz[int(i)], peakpos ,sig])
                    largest = param
                else:
                    param2 = numpy.array([yy[int(i)] - zz [int(i)], xx[int(i)] ,sig])
                    param = numpy.concatenate((param,param2),1)
                    if (param2[0] > largest[0]):
                        largest = param2
                        largest_index = j
                j = j + 1
            xw = numpy.resize(xx,(npoints,1))
            if (0):
                sy = numpy.sqrt(abs(yy))
                yw = numpy.resize(yy-zz,(npoints,1))
                sy = numpy.resize(sy,(npoints,1))
                datawork = numpy.concatenate((xw,yw,sy),1)
            else:
                yw = numpy.resize(yy-zz,(npoints,1))
                datawork = numpy.concatenate((xw,yw),1)            
            cons = numpy.zeros((3,len(param)),numpy.float)
            cons [0] [0:len(param):3] = CPOSITIVE
            #force peaks to stay around their position
            if (1):
                cons [0] [1:len(param):3] = CQUOTED
                #This does not work!!!!
                #FWHM should be given in terms of X not of points!
                #cons [1] [1:len(param):3] = param[1:len(param):3]-0.5*search_fwhm
                #cons [2] [1:len(param):3] = param[1:len(param):3]+0.5*search_fwhm                
                if len(xw) > search_fwhm:
                    fwhmx = numpy.fabs(xw[int(search_fwhm)]-xw[0])
                    cons [1] [1:len(param):3] = param[1:len(param):3]-0.5*fwhmx
                    cons [2] [1:len(param):3] = param[1:len(param):3]+0.5*fwhmx                
                else:
                    cons [1] [1:len(param):3] = numpy.ones(shape(param[1:len(param):3]),numpy.float)*min(xw)
                    cons [2] [1:len(param):3] = numpy.ones(shape(param[1:len(param):3]),numpy.float)*max(xw)            

            if 0:
                cons [0] [2:len(param):3] = CFACTOR
                cons [1] [2:len(param):3] = 2
                cons [2] [2:len(param):3] = 1.0
                cons [0] [2] = CPOSITIVE
                cons [1] [2] = 0
                cons [2] [2] = 0
            else:
                cons [0] [2:len(param):3] = CPOSITIVE
            fittedpar, chisq, sigmapar = LeastSquaresFit(SpecfitFuns.gauss,param,
                                            datawork,
                                            weightflag=self.config['WeightFlag'],
                                            maxiter=4,constrains=cons.tolist())
            #I already have the estimation
            #yw=yy-zz-SpecfitFuns.gauss(fittedpar,xx)
            #if DEBUG:
            #    SimplePlot.plot([xx,yw])
            #print self.seek(yw,\
            #                   fwhm=search_fwhm,\
            #                   sensitivity=search_sens,\
            #                   yscaling=yscaling)
       #else:
       #     #Use SPEC estimate ...
       #     peakpos,height,myidx = SpecArithmetic.search_peak(xx,yy-zz)
       #     fwhm,cfwhm         = SpecArithmetic.search_fwhm(xx,yy-zz,
       #                                    peak=peakpos,index=myidx) 
       #     xx = numpy.array(xx)
       #     if npoints > 2:
       #         #forget SPEC estimation of fwhm
       #         fwhm=5*abs(xx[npoints-1]-xx[0])/npoints
       #     fittedpar=[height,peakpos,fwhm]
       #     largest=numpy.array([height,peakpos,fwhm])
       #     peaks=[peakpos]
       cons = numpy.zeros((3,len(fittedpar)),numpy.float)
       j=0
       for i in range(len(peaks)):
                #Setup height area constrains
                if self.config['NoConstrainsFlag'] == 0:
                    if self.config['HeightAreaFlag']:
                        #POSITIVE = 1
                        cons[0] [j] = 1
                        cons[1] [j] = 0
                        cons[2] [j] = 0
                j=j+1
                
                
                #Setup position constrains
                if self.config['NoConstrainsFlag'] == 0:
                    if self.config['PositionFlag']:
                                #QUOTED = 2
                                cons[0][j]=2
                                cons[1][j]=min(xx)
                                cons[2][j]=max(xx) 
                j=j+1
                
                #Setup positive FWHM constrains
                if self.config['NoConstrainsFlag'] == 0:
                    if self.config['PosFwhmFlag']:
                                #POSITIVE=1
                                cons[0][j]=1
                                cons[1][j]=0
                                cons[2][j]=0
                    if self.config['SameFwhmFlag']:
                        if (i != largest_index):
                                #FACTOR=4
                                cons[0][j]=4
                                cons[1][j]=3*largest_index+2
                                cons[2][j]=1.0
                j=j+1
       return fittedpar,cons 
Ejemplo n.º 23
0
 def stepdown(self,pars,x):
     """
     A fit function.
     """
     return 0.5*SpecfitFuns.downstep(pars,x)
Ejemplo n.º 24
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 def apvoigt(self,pars,x):
    """
    Fit function.
    """
    return SpecfitFuns.apvoigt(pars,x)
Ejemplo n.º 25
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 def agauss(self,pars,x):
    """
    A fit function.
    """
    return SpecfitFuns.agauss(pars,x)
 def hypermet(self, pars, x):
     """
     Default hypermet function
     """
     return SpecfitFuns.ahypermet(pars, x, 15, 0)
Ejemplo n.º 27
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 def splitgauss(self,pars,x):
    """
    Asymmetric gaussian.
    """
    return SpecfitFuns.splitgauss(pars,x)
 def stepUp(self, pars, x):
     """
     Error function like.
     """
     return 0.5 * SpecfitFuns.upstep(pars, x)
Ejemplo n.º 29
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 def splitlorentz(self,pars,x):
    """
    Asymmetric lorentz.
    """
    return SpecfitFuns.splitlorentz(pars,x)
Ejemplo n.º 30
0
    def divideByActiveCurve(self):
        #all curves
        curves = self.getAllCurves()
        nCurves = len(curves)
        if nCurves < 2:
            raise ValueError("At least two curves needed")
            return
        
        #get active curve
        activeCurve = self.getActiveCurve()
        if activeCurve is None:
            raise ValueError("Please select an active curve")
            return
        
        x, y, legend0, info = activeCurve
        xmin, xmax = self.getGraphXLimits()
        y = y.astype(numpy.float)

        #get the nonzero values
        idx = numpy.nonzero(abs(y) != 0.0)[0]
        if not len(idx):
            raise ValueError("All divisor values are zero!")
        x0 = numpy.take(x, idx)
        y0 = numpy.take(y, idx)        

        #sort the values
        idx = numpy.argsort(x0, kind='mergesort')
        x0 = numpy.take(x0, idx)
        y0 = numpy.take(y0, idx)

        i = 0
        for curve in curves:            
            x, y, legend, info = curve[0:4]
            if legend == legend0:
                continue
            #take the portion ox x between limits
            idx = numpy.nonzero((x>=xmin) & (x<=xmax))[0]
            if not len(idx):
                #no overlap
                continue
            x = numpy.take(x, idx)
            y = numpy.take(y, idx)

            idx = numpy.nonzero((x0>=x.min()) & (x0<=x.max()))[0]
            if not len(idx):
                #no overlap
                continue
            xi = numpy.take(x0, idx)
            yi = numpy.take(y0, idx)
            
            #perform interpolation
            xi.shape = -1, 1
            yw = SpecfitFuns.interpol([x], y, xi, yi.min())
            y = yw / yi
            if i == 0:
                replace = True
                replot = True
                i = 1
            else:
                replot = False
                replace = False
            self.addCurve(x, y,
                          legend=legend,
                          info=info,
                          replot=replot,
                          replace=replace)
            lastCurve = [x, y, legend]
        self.addCurve(lastCurve[0],
                      lastCurve[1],
                      legend=lastCurve[2],                      
                      info=info,
                      replot=True,
                      replace=False)
Ejemplo n.º 31
0
 def splitpvoigt(self,pars,x):
    """
    Asymmetric pseudovoigt.
    """
    return SpecfitFuns.splitpvoigt(pars,x)