#if !defined(capcyl_h)
#define capcyl_h
#include "parameters.hh"
/**
* Structure definition for CappedCylinder parameters
*/
//[PYTHONCLASS] = CappedCylinderModel
//[DISP_PARAMS] = rad_cyl,len_cyl,rad_cap,phi, theta
//[DESCRIPTION] =Calculates the scattering from a cylinder with spherical section end-caps.
// That is, a sphereocylinder
// with end caps that have a radius larger than
// that of the cylinder and the center of the
// end cap radius lies within the cylinder.
// Note: As the length of cylinder -->0,
// it becomes a ConvexLens.
// It must be that rad_cyl <(=) rad_cap.
// [Parameters];
// scale: volume fraction of spheres,
// background:incoherent background,
// rad_cyl: radius of the cylinder,
// len_cyl: length of the cylinder,
// rad_cap: radius of the semi-spherical cap,
// sld_capcyl: SLD of the capped cylinder,
// sld_solv: SLD of the solvent.
//
//[FIXED]= rad_cyl.width;len_cyl;rad_cap;phi.width; theta.width
//[ORIENTATION_PARAMS]= phi; theta; phi.width; theta.width
class CappedCylinderModel{
public:
// Model parameters
/// Scale factor
// [DEFAULT]=scale= 1.0
Parameter scale;
/// rad_cyl [A]
// [DEFAULT]=rad_cyl=20.0 [A]
Parameter rad_cyl;
/// length of the cylinder
// [DEFAULT]=len_cyl=400.0 [A]
Parameter len_cyl;
/// Radius of sphere [A]
// [DEFAULT]=rad_cap=40.0 [A]
Parameter rad_cap;
/// sld_capcyl [1/A^(2)]
// [DEFAULT]=sld_capcyl= 1.0e-6 [1/A^(2)]
Parameter sld_capcyl;
/// sld_solv [1/A^(2)]
// [DEFAULT]=sld_solv= 6.3e-6 [1/A^(2)]
Parameter sld_solv;
/// Incoherent Background [1/cm]
// [DEFAULT]=background=0.0 [1/cm]
Parameter background;
/// Angle of the main axis against z-axis in detector plane [deg]
// [DEFAULT]=theta=0.0 [deg]
Parameter theta;
/// Azimuthal angle around z-axis in detector plane [deg]
// [DEFAULT]=phi=0.0 [deg]
Parameter phi;
// Constructor
CappedCylinderModel();
// Operators to get I(Q)
double operator()(double q);
double operator()(double qx, double qy);
double calculate_ER();
double evaluate_rphi(double q, double phi);
};
#endif