elliptical_cylinder.c @ 19e8a2b

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Last change on this file since 19e8a2b was ee60aa7, checked in by Paul Kienzle <pkienzle@…>, 6 years ago
clean up effective radius functions; improve mono_gauss_coil accuracy; start moving VR into C
Property mode set to `100644`
File size: 4.6 KB

Rev	Line
[2a0b2b1]	1	static double
[251f54b]	2	form_volume(double radius_minor, double r_ratio, double length)
[a8b3cdb]	3	{
[a807206]	4	return M_PI * radius_minor * radius_minor * r_ratio * length;
[a8b3cdb]	5	}
	6
[d277229]	7	static double
	8	radius_from_volume(double radius_minor, double r_ratio, double length)
	9	{
	10	const double volume_ellcyl = form_volume(radius_minor,r_ratio,length);
	11	return cbrt(0.75*volume_ellcyl/M_PI);
	12	}
	13
	14	static double
[a94046f]	15	radius_from_min_dimension(double radius_minor, double r_ratio, double hlength)
[d277229]	16	{
	17	const double rad_min = (r_ratio > 1.0 ? radius_minor : r_ratio*radius_minor);
[fbaef04]	18	return (rad_min < hlength ? rad_min : hlength);
[d277229]	19	}
	20
	21	static double
[a94046f]	22	radius_from_max_dimension(double radius_minor, double r_ratio, double hlength)
[d277229]	23	{
	24	const double rad_max = (r_ratio < 1.0 ? radius_minor : r_ratio*radius_minor);
[fbaef04]	25	return (rad_max > hlength ? rad_max : hlength);
[d277229]	26	}
	27
	28	static double
	29	radius_from_diagonal(double radius_minor, double r_ratio, double length)
	30	{
	31	const double radius_max = (r_ratio > 1.0 ? radius_minor*r_ratio : radius_minor);
	32	return sqrt(radius_maxradius_max + 0.25length*length);
	33	}
	34
	35	static double
	36	effective_radius(int mode, double radius_minor, double r_ratio, double length)
	37	{
[ee60aa7]	38	switch (mode) {
	39	case 1: // equivalent sphere
[d277229]	40	return radius_from_volume(radius_minor, r_ratio, length);
[ee60aa7]	41	case 2: // average radius
[d277229]	42	return 0.5radius_minor(1.0 + r_ratio);
[ee60aa7]	43	case 3: // min radius
[d277229]	44	return (r_ratio > 1.0 ? radius_minor : r_ratio*radius_minor);
[ee60aa7]	45	case 4: // max radius
[d277229]	46	return (r_ratio < 1.0 ? radius_minor : r_ratio*radius_minor);
[ee60aa7]	47	case 5: // equivalent circular cross-section
[d277229]	48	return sqrt(radius_minorradius_minorr_ratio);
[ee60aa7]	49	case 6: // half length
[d277229]	50	return 0.5*length;
[ee60aa7]	51	case 7: // half min dimension
[a94046f]	52	return radius_from_min_dimension(radius_minor,r_ratio,0.5*length);
[ee60aa7]	53	case 8: // half max dimension
[a94046f]	54	return radius_from_max_dimension(radius_minor,r_ratio,0.5*length);
[ee60aa7]	55	case 9: // half diagonal
[d277229]	56	return radius_from_diagonal(radius_minor,r_ratio,length);
	57	}
	58	}
	59
[71b751d]	60	static void
	61	Fq(double q, double F1, double F2, double radius_minor, double r_ratio, double length,
[68425bf]	62	double sld, double solvent_sld)
	63	{
[a8b3cdb]	64	// orientational average limits
[68425bf]	65	const double va = 0.0;
	66	const double vb = 1.0;
[a8b3cdb]	67	// inner integral limits
[68425bf]	68	const double vaj=0.0;
	69	const double vbj=M_PI;
[a8b3cdb]	70
[68425bf]	71	const double radius_major = r_ratio * radius_minor;
	72	const double rA = 0.5*(square(radius_major) + square(radius_minor));
	73	const double rB = 0.5*(square(radius_major) - square(radius_minor));
[a8b3cdb]	74
[68425bf]	75	//initialize integral
[71b751d]	76	double outer_sum_F1 = 0.0;
	77	double outer_sum_F2 = 0.0;
[74768cb]	78	for(int i=0;i<GAUSS_N;i++) {
[a8b3cdb]	79	//setup inner integral over the ellipsoidal cross-section
[74768cb]	80	const double cos_val = ( GAUSS_Z[i]*(vb-va) + va + vb )/2.0;
[68425bf]	81	const double sin_val = sqrt(1.0 - cos_val*cos_val);
	82	//const double arg = radius_minor*sin_val;
[71b751d]	83	double inner_sum_F1 = 0.0;
	84	double inner_sum_F2 = 0.0;
[74768cb]	85	for(int j=0;j<GAUSS_N;j++) {
	86	const double theta = ( GAUSS_Z[j]*(vbj-vaj) + vaj + vbj )/2.0;
[68425bf]	87	const double r = sin_valsqrt(rA - rBcos(theta));
[592343f]	88	const double be = sas_2J1x_x(q*r);
[71b751d]	89	inner_sum_F1 += GAUSS_W[j] * be;
	90	inner_sum_F2 += GAUSS_W[j] * be * be;
[a8b3cdb]	91	}
	92	//now calculate the value of the inner integral
[71b751d]	93	inner_sum_F1 = 0.5(vbj-vaj);
	94	inner_sum_F2 = 0.5(vbj-vaj);
[a8b3cdb]	95
	96	//now calculate outer integral
[1e7b0db0]	97	const double si = sas_sinx_x(q0.5length*cos_val);
[71b751d]	98	outer_sum_F1 += GAUSS_W[i] * inner_sum_F1 * si;
	99	outer_sum_F2 += GAUSS_W[i] * inner_sum_F2 * si * si;
[a8b3cdb]	100	}
[71b751d]	101	// correct limits and divide integral by pi
	102	outer_sum_F1 = 0.5(vb-va)/M_PI;
	103	outer_sum_F2 = 0.5(vb-va)/M_PI;
[a8b3cdb]	104
[68425bf]	105	// scale by contrast and volume, and convert to to 1/cm units
[71b751d]	106	const double volume = form_volume(radius_minor, r_ratio, length);
	107	const double contrast = sld - solvent_sld;
	108	const double s = contrast*volume;
	109	F1 = 1.0e-2s*outer_sum_F1;
	110	F2 = 1.0e-4ssouter_sum_F2;
[a8b3cdb]	111	}
	112
	113
[2a0b2b1]	114	static double
[108e70e]	115	Iqabc(double qa, double qb, double qc,
[68425bf]	116	double radius_minor, double r_ratio, double length,
[becded3]	117	double sld, double solvent_sld)
[68425bf]	118	{
	119	// Compute: r = sqrt((radius_majorcos_nu)^2 + (radius_minorcos_mu)^2)
	120	// Given: radius_major = r_ratio * radius_minor
[82592da]	121	const double qr = radius_minorsqrt(square(r_ratioqb) + square(qa));
[2a0b2b1]	122	const double be = sas_2J1x_x(qr);
	123	const double si = sas_sinx_x(qc0.5length);
[71b751d]	124	const double fq = be * si;
	125	const double contrast = sld - solvent_sld;
	126	const double volume = form_volume(radius_minor, r_ratio, length);
	127	return 1.0e-4 * square(contrast * volume * fq);
[a8b3cdb]	128	}

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source: sasmodels/sasmodels/models/elliptical_cylinder.c @ 19e8a2b

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