source: sasview/sansmodels/src/sans/models/OblateModel.py @ fe9c19b4

#!/usr/bin/env python
"""
        This software was developed by the University of Tennessee as part of the
        Distributed Data Analysis of Neutron Scattering Experiments (DANSE)
        project funded by the US National Science Foundation.

        If you use DANSE applications to do scientific research that leads to
        publication, we ask that you acknowledge the use of the software with the
        following sentence:

        "This work benefited from DANSE software developed under NSF award DMR-0520547."

        copyright 2008, University of Tennessee
"""

""" Provide functionality for a C extension model

        WARNING: THIS FILE WAS GENERATED BY WRAPPERGENERATOR.PY
                 DO NOT MODIFY THIS FILE, MODIFY ..\c_extensions\oblate.h
                 AND RE-RUN THE GENERATOR SCRIPT

"""

from sans.models.BaseComponent import BaseComponent
from sans_extension.c_models import COblateModel
import copy    
    
class OblateModel(COblateModel, BaseComponent):
    """ Class that evaluates a OblateModel model. 
        This file was auto-generated from ..\c_extensions\oblate.h.
        Refer to that file and the structure it contains
        for details of the model.
        List of default parameters:
         scale           = 1.0 
         major_core      = 200.0 [A]
         minor_core      = 20.0 [A]
         major_shell     = 250.0 [A]
         minor_shell     = 30.0 [A]
         contrast        = 1e-006 [1/A^(2)]
         sld_solvent     = 6.3e-006 [1/A^(2)]
         background      = 0.001 [1/cm]
         axis_theta      = 1.0 [rad]
         axis_phi        = 1.0 [rad]

    """
        
    def __init__(self):
        """ Initialization """
        
        # Initialize BaseComponent first, then sphere
        BaseComponent.__init__(self)
        COblateModel.__init__(self)
        
        ## Name of the model
        self.name = "OblateModel"
        ## Model description
        self.description ="""[OblateCoreShellModel] Calculates the form factor for an oblate
                ellipsoid particle with a core_shell structure.
                The form factor is averaged over all possible
                orientations of the ellipsoid such that P(q)
                = scale*<f^2>/Vol + bkg, where f is the
                single particle scattering amplitude.
                [Parameters]:
                major_core = radius of major_core,
                minor_core = radius of minor_core,
                major_shell = radius of major_shell,
                minor_shell = radius of minor_shell,
                contrast = SLD_core - SLD_shell
                sld_solvent = SLD_solvent
                background = Incoherent bkg
                scale =scale
                Note:It is the users' responsibility to ensure
                that shell radii are larger than core radii."""
       
        ## Parameter details [units, min, max]
        self.details = {}
        self.details['scale'] = ['', None, None]
        self.details['major_core'] = ['[A]', None, None]
        self.details['minor_core'] = ['[A]', None, None]
        self.details['major_shell'] = ['[A]', None, None]
        self.details['minor_shell'] = ['[A]', None, None]
        self.details['contrast'] = ['[1/A^(2)]', None, None]
        self.details['sld_solvent'] = ['[1/A^(2)]', None, None]
        self.details['background'] = ['[1/cm]', None, None]
        self.details['axis_theta'] = ['[rad]', None, None]
        self.details['axis_phi'] = ['[rad]', None, None]

        ## fittable parameters
        self.fixed=['major_core.width', 'minor_core.width', 'major_shell.width', 'minor_shell.width']
        
        ## parameters with orientation
        self.orientation_params =['axis_phi', 'axis_theta', 'axis_phi.width', 'axis_theta.width']
   
    def clone(self):
        """ Return a identical copy of self """
        return self._clone(OblateModel())   
        
    def __getstate__(self):
        """ return object state for pickling and copying """
        print "__dict__",self.__dict__
        #self.__dict__['params'] = self.params
        #self.__dict__['dispersion'] = self.dispersion
        #self.__dict__['log'] = self.log
        model_state = {'params': self.params, 'dispersion': self.dispersion, 'log': self.log}
        
        return self.__dict__, model_state
        
    def __setstate__(self, state):
        """ create object from pickled state """
        
        self.__dict__, model_state = state
        self.params = model_state['params']
        self.dispersion = model_state['dispersion']
        self.log = model_state['log']
        
   
    def run(self, x = 0.0):
        """ Evaluate the model
            @param x: input q, or [q,phi]
            @return: scattering function P(q)
        """
        
        return COblateModel.run(self, x)
   
    def runXY(self, x = 0.0):
        """ Evaluate the model in cartesian coordinates
            @param x: input q, or [qx, qy]
            @return: scattering function P(q)
        """
        
        return COblateModel.runXY(self, x)
        
    def evalDistribition(self, x = []):
        """ Evaluate the model in cartesian coordinates
            @param x: input q[], or [qx[], qy[]]
            @return: scattering function P(q[])
        """
        return COblateModel.evalDistribition(self, x)
        
    def calculate_ER(self):
        """ Calculate the effective radius for P(q)*S(q)
            @return: the value of the effective radius
        """       
        return COblateModel.calculate_ER(self)
        
    def set_dispersion(self, parameter, dispersion):
        """
            Set the dispersion object for a model parameter
            @param parameter: name of the parameter [string]
            @dispersion: dispersion object of type DispersionModel
        """
        return COblateModel.set_dispersion(self, parameter, dispersion.cdisp)
        
   
# End of file