#mono_gauss_coil model #conversion of DebyeModel.py #converted by Steve King, Mar 2016 r""" This Debye Gaussian coil model strictly describes the scattering from *monodisperse* polymer chains in theta solvents or polymer melts, conditions under which the distances between segments follow a Gaussian distribution. Provided the number of segments is large (ie, high molecular weight polymers) the single-chain form factor P(Q) is that described by Debye (1947). To describe the scattering from *polydisperse* polymer chains see the :ref:`poly-gauss-coil` model. Definition ---------- .. math:: I(q) = \text{scale} \cdot I_0 \cdot P(q) + \text{background} where .. math:: I_0 &= \phi_\text{poly} \cdot V \cdot (\rho_\text{poly} - \rho_\text{solv})^2 \\ P(q) &= 2 [\exp(-Z) + Z - 1] / Z^2 \\ Z &= (q R_g)^2 \\ V &= M / (N_A \delta) Here, $\phi_\text{poly}$ is the volume fraction of polymer, $V$ is the volume of a polymer coil, *M* is the molecular weight of the polymer, $N_A$ is Avogadro's Number, $\delta$ is the bulk density of the polymer, $\rho_\text{poly}$ is the sld of the polymer, $\rho\text{solv}$ is the sld of the solvent, and $R_g$ is the radius of gyration of the polymer coil. The 2D scattering intensity is calculated in the same way as the 1D, but where the *q* vector is redefined as .. math:: q = \sqrt{q_x^2 + q_y^2} References ---------- P Debye, *J. Phys. Colloid. Chem.*, 51 (1947) 18. R J Roe, *Methods of X-Ray and Neutron Scattering in Polymer Science*, Oxford University Press, New York (2000). http://www.ncnr.nist.gov/staff/hammouda/distance_learning/chapter_28.pdf """ import numpy as np from numpy import inf name = "mono_gauss_coil" title = "Scattering from monodisperse polymer coils" description = """ Evaluates the scattering from monodisperse polymer chains. """ category = "shape-independent" # pylint: disable=bad-whitespace, line-too-long # ["name", "units", default, [lower, upper], "type", "description"], parameters = [ ["i_zero", "1/cm", 70.0, [0.0, inf], "", "Intensity at q=0"], ["rg", "Ang", 75.0, [0.0, inf], "volume", "Radius of gyration"], ] # pylint: enable=bad-whitespace, line-too-long source = ["mono_gauss_coil.c"] have_Fq = False effective_radius_type = ["R_g", "2R_g", "3R_g", "sqrt(5/3)*R_g"] def random(): """Return a random parameter set for the model.""" rg = 10**np.random.uniform(0, 4) #rg = 1e3 pars = dict( #scale=1, background=0, i_zero=1e7, # i_zero is a simple scale rg=rg, ) return pars demo = dict(scale=1.0, i_zero=70.0, rg=75.0, background=0.0) # these unit test values taken from SasView 3.1.2 tests = [ [{'scale': 1.0, 'i_zero': 70.0, 'rg': 75.0, 'background': 0.0}, [0.0106939, 0.469418], [57.1241, 0.112859]], ]