r""" For information about polarised and magnetic scattering, click here_. .. _here: polar_mag_help.html Definition ---------- The 1D scattering intensity is calculated in the following way (Guinier, 1955) .. math:: I(Q) = \frac{\text{scale}}{V} \cdot \left[ \ 3V(\Delta\rho) \cdot \frac{\sin(QR) - QR\cos(QR))}{(QR)^3} \ \right]^2 + \text{background} where *scale* is a volume fraction, $V$ is the volume of the scatterer, $R$ is the radius of the sphere, *background* is the background level and *sld* and *solvent_sld* are the scattering length densities (SLDs) of the scatterer and the solvent respectively. Note that if your data is in absolute scale, the *scale* should represent the volume fraction (which is unitless) if you have a good fit. If not, it should represent the volume fraction times a factor (by which your data might need to be rescaled). The 2D scattering intensity is the same as above, regardless of the orientation of $\vec q$. Our model uses the form factor calculations as defined in the IGOR package provided by the NIST Center for Neutron Research (Kline, 2006). Validation ---------- Validation of our code was done by comparing the output of the 1D model to the output of the software provided by the NIST (Kline, 2006). Figure :num:`figure #sphere-comparison` shows a comparison of the output of our model and the output of the NIST software. .. _sphere-comparison: .. figure:: img/sphere_comparison.jpg Comparison of the DANSE scattering intensity for a sphere with the output of the NIST SANS analysis software. The parameters were set to: *scale* = 1.0, *radius* = 60 |Ang|, *contrast* = 1e-6 |Ang^-2|, and *background* = 0.01 |cm^-1|. Reference --------- A Guinier and G. Fournet, *Small-Angle Scattering of X-Rays*, John Wiley and Sons, New York, (1955) *2013/09/09 and 2014/01/06 - Description reviewed by S King and P Parker.* """ from numpy import inf name = "sphere" title = "Spheres with uniform scattering length density" description = """\ P(q)=(scale/V)*[3V(sld-solvent_sld)*(sin(qR)-qRcos(qR)) /(qR)^3]^2 + background R: radius of sphere V: The volume of the scatter sld: the SLD of the sphere solvent_sld: the SLD of the solvent """ category = "shape:sphere" # ["name", "units", default, [lower, upper], "type","description"], parameters = [["sld", "1e-6/Ang^2", 1, [-inf, inf], "", "Layer scattering length density"], ["solvent_sld", "1e-6/Ang^2", 6, [-inf, inf], "", "Solvent scattering length density"], ["radius", "Ang", 50, [0, inf], "volume", "Sphere radius"], ] # No volume normalization despite having a volume parameter # This should perhaps be volume normalized? form_volume = """ return 1.333333333333333*M_PI*radius*radius*radius; """ Iq = """ const double qr = q*radius; double sn, cn; SINCOS(qr, sn, cn); const double bes = qr==0.0 ? 1.0 : 3.0*(sn-qr*cn)/(qr*qr*qr); const double fq = bes * (sld - solvent_sld) * form_volume(radius); return 1.0e-4*fq*fq; """ Iqxy = """ // never called since no orientation or magnetic parameters. //return -1.0; return Iq(sqrt(qx*qx + qy*qy), sld, solvent_sld, radius); """ def ER(radius): return radius # VR defaults to 1.0 demo = dict(scale=1, background=0, sld=6, solvent_sld=1, radius=120, radius_pd=.2, radius_pd_n=45) oldname = "SphereModel" oldpars = dict(sld='sldSph', solvent_sld='sldSolv', radius='radius')