dft_tools/pytriqs/gf/local/_gf_imfreq.py

from scipy.optimize import leastsq
from tools import get_indices_in_dict
import _gf_plot 
import numpy

def init( mesh= None, shape =None, name = 'g', **d):
    """
    """
    if mesh is None :
        from gf import MeshImFreq
        if 'beta' not in d : raise ValueError, "beta not provided"
        beta = float(d.pop('beta'))
        n_points = d.pop('n_points',1025)
        stat = d.pop('statistic','Fermion')
        positive_only = d.pop('positive_only',True)
        mesh = MeshImFreq(beta,stat,n_points, positive_only)
    
    indices_pack = get_indices_in_dict(d)
    if not shape : 
      assert indices_pack, "No shape, no indices !"
      indicesL, indicesR = indices_pack
      shape = len(indicesL),len(indicesR)
    
    #data = d.pop('data') if 'data' in d else numpy.zeros((len(mesh),N1,N2), self.dtype )
    #tail = d.pop('tail') if 'tail' in d else TailGf(shape = (N1,N2))
    #symmetry = d.pop('symmetry', Nothing())

    return (mesh, shape, indices_pack, name), {}
    #return mesh, data, tail, symmetry, indices_pack, name

#--------------   PLOT   ---------------------------------------

def plot(self, opt_dict):
    """ Plot protocol. opt_dict can contain :
         * :param RIS: 'R', 'I', 'S', 'RI' [ default]
         * :param x_window: (xmin,xmax) or None [default]
         * :param name: a string [default ='']. If not '', it remplaces the name of the function just for this plot.
    """
    return _gf_plot.plot_base( self, opt_dict,  r'$\omega_n$',
            lambda name : r'%s$(i\omega_n)$'%name, True, [x.imag for x in self.mesh] )

#--------------   OTHER OPERATIONS -----------------------------------------------------

def replace_by_tail(self,start) :
    d = self.data
    t = self.tail
    for n, om in enumerate(self.mesh) :
        if n >= start : d[n,:,:] = t(om)

def fit_tail(self, fixed_coef, order_max, fit_start, fit_stop, replace_tail = True):
   """
   Fit the tail of the Green's function
   Input:
     - fixed_coef: a 3-dim array of known coefficients for the fit starting from the order -1
     - order_max: highest order in the fit
     - fit_start, fit_stop: fit the data between fit_start and fit_stop
   Output:
     On output all the data above fit_start is replaced by the fitted tail
     and the new moments are included in the Green's function
   """

   # Turn known_coefs into a numpy array if ever it is not already the case
   known_coef = fixed_coef

   # Change the order_max
   # It is assumed that any known_coef will start at order -1
   self.tail.zero()
   self.tail.mask.fill(order_max)

   # Fill up two arrays with the frequencies and values over the range of interest
   ninit, nstop = 0, -1
   x = []
   for om in self.mesh:
     if (om.imag < fit_start): ninit = ninit+1
     if (om.imag <= fit_stop): nstop = nstop+1
     if (om.imag <= fit_stop and om.imag >= fit_start): x += [om]
   omegas = numpy.array(x)
   values = self.data[ninit:nstop+1,:,:]

   # Loop over the indices of the Green's function
   for n1,indR in enumerate(self.indicesR):
     for n2,indL in enumerate(self.indicesL):

       # Construct the part of the fitting functions which is known
       f_known = numpy.zeros((len(omegas)),numpy.complex)
       for order in range(len(known_coef[n1][n2])):
         f_known += known_coef[n1][n2][order]*omegas**(1-order)

       # Compute how many free parameters we have and give an initial guess
       len_param = order_max-len(known_coef[n1][n2])+2
       p0 = len_param*[1.0]

       # This is the function to be minimized, the diff between the original
       # data in values and the fitting function
       def fct(p):
         y_fct = 1.0*f_known
         for order in range(len_param):
           y_fct += p[order]*omegas**(1-len(known_coef[n1][n2])-order)
         y_fct -= values[:,n1,n2]
         return abs(y_fct)

       # Now call the minimizing function
       sol = leastsq(fct, p0, maxfev=1000*len_param)

       # Put the known and the new found moments in the tail
       for order in range(len(known_coef[n1][n2])):
         self.tail[order-1][n1,n2] = numpy.array([[ known_coef[n1][n2][order] ]])
       for order, moment in enumerate(sol[0]):
         self.tail[len(known_coef[n1][n2])+order-1][n1,n2] = numpy.array([[ moment ]])
   self.tail.mask.fill(order_max)
   # Replace then end of the Green's function by the tail
   if replace_tail: self.replace_by_tail(ninit);
gf : new wrapper 2014-05-09 10:43:55 +02:00			`from scipy.optimize import leastsq`
			`from tools import get_indices_in_dict`
			`import _gf_plot`
			`import numpy`

			`def init( mesh= None, shape =None, name = 'g', **d):`
			`"""`
			`"""`
			`if mesh is None :`
			`from gf import MeshImFreq`
			`if 'beta' not in d : raise ValueError, "beta not provided"`
			`beta = float(d.pop('beta'))`
			`n_points = d.pop('n_points',1025)`
			`stat = d.pop('statistic','Fermion')`
			`positive_only = d.pop('positive_only',True)`
			`mesh = MeshImFreq(beta,stat,n_points, positive_only)`

			`indices_pack = get_indices_in_dict(d)`
			`if not shape :`
			`assert indices_pack, "No shape, no indices !"`
			`indicesL, indicesR = indices_pack`
			`shape = len(indicesL),len(indicesR)`

			`#data = d.pop('data') if 'data' in d else numpy.zeros((len(mesh),N1,N2), self.dtype )`
			`#tail = d.pop('tail') if 'tail' in d else TailGf(shape = (N1,N2))`
			`#symmetry = d.pop('symmetry', Nothing())`

			`return (mesh, shape, indices_pack, name), {}`
			`#return mesh, data, tail, symmetry, indices_pack, name`

			`#-------------- PLOT ---------------------------------------`

			`def plot(self, opt_dict):`
			`""" Plot protocol. opt_dict can contain :`
			`* :param RIS: 'R', 'I', 'S', 'RI' [ default]`
			`* :param x_window: (xmin,xmax) or None [default]`
			`* :param name: a string [default ='']. If not '', it remplaces the name of the function just for this plot.`
			`"""`
			`return _gf_plot.plot_base( self, opt_dict, r'$\omega_n$',`
			`lambda name : r'%s$(i\omega_n)$'%name, True, [x.imag for x in self.mesh] )`

			`#-------------- OTHER OPERATIONS -----------------------------------------------------`

			`def replace_by_tail(self,start) :`
			`d = self.data`
			`t = self.tail`
			`for n, om in enumerate(self.mesh) :`
			`if n >= start : d[n,:,:] = t(om)`

			`def fit_tail(self, fixed_coef, order_max, fit_start, fit_stop, replace_tail = True):`
			`"""`
			`Fit the tail of the Green's function`
			`Input:`
			`- fixed_coef: a 3-dim array of known coefficients for the fit starting from the order -1`
			`- order_max: highest order in the fit`
			`- fit_start, fit_stop: fit the data between fit_start and fit_stop`
			`Output:`
			`On output all the data above fit_start is replaced by the fitted tail`
			`and the new moments are included in the Green's function`
			`"""`

			`# Turn known_coefs into a numpy array if ever it is not already the case`
			`known_coef = fixed_coef`

			`# Change the order_max`
			`# It is assumed that any known_coef will start at order -1`
			`self.tail.zero()`
			`self.tail.mask.fill(order_max)`

			`# Fill up two arrays with the frequencies and values over the range of interest`
			`ninit, nstop = 0, -1`
			`x = []`
			`for om in self.mesh:`
			`if (om.imag < fit_start): ninit = ninit+1`
			`if (om.imag <= fit_stop): nstop = nstop+1`
			`if (om.imag <= fit_stop and om.imag >= fit_start): x += [om]`
			`omegas = numpy.array(x)`
			`values = self.data[ninit:nstop+1,:,:]`

			`# Loop over the indices of the Green's function`
			`for n1,indR in enumerate(self.indicesR):`
			`for n2,indL in enumerate(self.indicesL):`

			`# Construct the part of the fitting functions which is known`
			`f_known = numpy.zeros((len(omegas)),numpy.complex)`
			`for order in range(len(known_coef[n1][n2])):`
			`f_known += known_coef[n1][n2][order]omegas*(1-order)`

			`# Compute how many free parameters we have and give an initial guess`
			`len_param = order_max-len(known_coef[n1][n2])+2`
			`p0 = len_param*[1.0]`

			`# This is the function to be minimized, the diff between the original`
			`# data in values and the fitting function`
			`def fct(p):`
			`y_fct = 1.0*f_known`
			`for order in range(len_param):`
			`y_fct += p[order]omegas*(1-len(known_coef[n1][n2])-order)`
			`y_fct -= values[:,n1,n2]`
			`return abs(y_fct)`

			`# Now call the minimizing function`
			`sol = leastsq(fct, p0, maxfev=1000*len_param)`

			`# Put the known and the new found moments in the tail`
			`for order in range(len(known_coef[n1][n2])):`
			`self.tail[order-1][n1,n2] = numpy.array([[ known_coef[n1][n2][order] ]])`
			`for order, moment in enumerate(sol[0]):`
			`self.tail[len(known_coef[n1][n2])+order-1][n1,n2] = numpy.array([[ moment ]])`
			`self.tail.mask.fill(order_max)`
			`# Replace then end of the Green's function by the tail`
			`if replace_tail: self.replace_by_tail(ninit);`