#if !defined(cylinder_h)
#define cylinder_h
/** Structure definition for cylinder parameters
* [PYTHONCLASS] = CylinderModel
* [DISP_PARAMS] = radius, length, cyl_theta, cyl_phi
[DESCRIPTION] = f(q)= 2*(sldCyl - sldSolv)*V*sin(qLcos(alpha/2))
/[qLcos(alpha/2)]*J1(qRsin(alpha/2))/[qRsin(alpha)]
P(q,alpha)= scale/V*f(q)^(2)+bkg
V: Volume of the cylinder
R: Radius of the cylinder
L: Length of the cylinder
J1: The bessel function
alpha: angle betweenthe axis of the
cylinder and the q-vector for 1D
:the ouput is P(q)=scale/V*integral
from pi/2 to zero of...
f(q)^(2)*sin(alpha)*dalpha+ bkg
[FIXED]= cyl_phi.width; cyl_theta.width; length.width;radius.width
[ORIENTATION_PARAMS]= cyl_phi; cyl_theta; cyl_phi.width; cyl_theta.width
**/
typedef struct {
/// Scale factor
// [DEFAULT]=scale=1.0
double scale;
/// Radius of the cylinder [A]
// [DEFAULT]=radius=20.0 [A]
double radius;
/// Length of the cylinder [A]
// [DEFAULT]=length=400.0 [A]
double length;
/// Contrast [1/A^(2)]
// [DEFAULT]=sldCyl=4.0e-6 [1/A^(2)]
double sldCyl;
/// sldCyl [1/A^(2)]
// [DEFAULT]=sldSolv=1.0e-6 [1/A^(2)]
double sldSolv;
/// Incoherent Background [1/cm] 0.00
// [DEFAULT]=background=0.0 [1/cm]
double background;
/// Orientation of the cylinder axis w/respect incoming beam [rad]
// [DEFAULT]=cyl_theta=1.0 [rad]
double cyl_theta;
/// Orientation of the cylinder in the plane of the detector [rad]
// [DEFAULT]=cyl_phi=1.0 [rad]
double cyl_phi;
} CylinderParameters;
/// 1D scattering function
double cylinder_analytical_1D(CylinderParameters *pars, double q);
/// 2D scattering function
double cylinder_analytical_2D(CylinderParameters *pars, double q, double phi);
double cylinder_analytical_2DXY(CylinderParameters *pars, double qx, double qy);
double cylinder_analytical_2D_scaled(CylinderParameters *pars, double q, double q_x, double q_y);
#endif