source: sasmodels/doc/ref/intro.rst @ a217f7d

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2.. _models-intro:
3
4************
5Introduction
6************
7
8Many of our models use the form factor calculations implemented in a c-library provided by the NIST Center for Neutron
9Research and thus some content and figures in this document are originated from or shared with the NIST SANS Igor-based
10analysis package.
11
12This software provides form factors for various particle shapes. After giving a mathematical definition of each model,
13we show the list of parameters available to the user. Validation plots for each model are also presented.
14
15Instructions on how to use SasView itself are available separately.
16
17To easily compare to the scattering intensity measured in experiments, we normalize the form factors by the volume of
18the particle
19
20.. math::
21
22    P(\vec q) = \frac{P_o(\vec q)}{V} = \frac{1}{V} F(\vec q) F^*(\vec q)
23
24with
25
26    F(\vec q) = \int\int\int dV\rho(\vec r) e^{-i\vec q \cdot \vec r}
27
28where $P_0(\vec q)$ is the un-normalized form factor, $\rho(\vec r)$ is the scattering length density at a given
29point in space and the integration is done over the volume $V$ of the scatterer.
30
31For systems without inter-particle interference, the form factors we provide can be related to the scattering intensity
32by the particle volume fraction
33
34.. math::
35
36    I(\vec q) = \Phi P(\vec q)
37
38Our so-called 1D scattering intensity functions provide $P(Q)$ for the case where the scatterer is randomly oriented. In
39that case, the scattering intensity only depends on the length of $Q$ . The intensity measured on the plane of the SAS
40detector will have an azimuthal symmetry around $Q=0$.
41
42Our so-called 2D scattering intensity functions provide $P(Q,\phi)$ for an oriented system as a function of a
43$q$ vector in the plane of the detector. We define the angle $\phi$ as the angle between the $q$ vector and the horizontal
44($x$) axis of the plane of the detector.
45
46For information about polarised and magnetic scattering, see here_.
47
48
49.. _here: polar_mag_help.html
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