Changes in / [33d7be3:b763f9d] in sasmodels
- Location:
- sasmodels/models
- Files:
-
- 3 added
- 53 edited
Legend:
- Unmodified
- Added
- Removed
-
sasmodels/models/barbell.c
r71b751d rd277229 62 62 } 63 63 64 static double 65 radius_from_volume(double radius_bell, double radius, double length) 66 { 67 const double vol_barbell = form_volume(radius_bell,radius,length); 68 return cbrt(0.75*vol_barbell/M_PI); 69 } 70 71 static double 72 radius_from_totallength(double radius_bell, double radius, double length) 73 { 74 const double hdist = sqrt(square(radius_bell) - square(radius)); 75 return 0.5*length + hdist + radius_bell; 76 } 77 78 static double 79 effective_radius(int mode, double radius_bell, double radius, double length) 80 { 81 if (mode == 1) { 82 return radius_from_volume(radius_bell, radius , length); 83 } else if (mode == 2) { 84 return radius; 85 } else if (mode == 3) { 86 return 0.5*length; 87 } else { 88 return radius_from_totallength(radius_bell,radius,length); 89 } 90 } 91 64 92 static void 65 93 Fq(double q,double *F1, double *F2, double sld, double solvent_sld, -
sasmodels/models/barbell.py
r71b751d rd277229 117 117 source = ["lib/polevl.c", "lib/sas_J1.c", "lib/gauss76.c", "barbell.c"] 118 118 have_Fq = True 119 effective_radius_type = ["equivalent sphere","radius","half length","half total length"] 119 120 120 121 def random(): -
sasmodels/models/capped_cylinder.c
r71b751d rd277229 84 84 } 85 85 86 static double 87 radius_from_volume(double radius, double radius_cap, double length) 88 { 89 const double vol_cappedcyl = form_volume(radius,radius_cap,length); 90 return cbrt(0.75*vol_cappedcyl/M_PI); 91 } 92 93 static double 94 radius_from_totallength(double radius, double radius_cap, double length) 95 { 96 const double hc = radius_cap - sqrt(radius_cap*radius_cap - radius*radius); 97 return 0.5*length + hc; 98 } 99 100 static double 101 effective_radius(int mode, double radius, double radius_cap, double length) 102 { 103 if (mode == 1) { 104 return radius_from_volume(radius, radius_cap, length); 105 } else if (mode == 2) { 106 return radius; 107 } else if (mode == 3) { 108 return 0.5*length; 109 } else { 110 return radius_from_totallength(radius, radius_cap,length); 111 } 112 } 113 86 114 static void 87 115 Fq(double q,double *F1, double *F2, double sld, double solvent_sld, -
sasmodels/models/capped_cylinder.py
r71b751d rd277229 137 137 source = ["lib/polevl.c", "lib/sas_J1.c", "lib/gauss76.c", "capped_cylinder.c"] 138 138 have_Fq = True 139 effective_radius_type = ["equivalent sphere","radius","half length","half total length"] 139 140 140 141 def random(): -
sasmodels/models/core_multi_shell.c
r71b751d rd277229 19 19 } 20 20 21 static double 22 outer_radius(double core_radius, double fp_n, double thickness[]) 23 { 24 double r = core_radius; 25 int n = (int)(fp_n+0.5); 26 for (int i=0; i < n; i++) { 27 r += thickness[i]; 28 } 29 return r; 30 } 31 32 static double 33 effective_radius(int mode, double core_radius, double fp_n, double thickness[]) 34 { 35 if (mode == 1) { 36 double r = core_radius; 37 int n = (int)(fp_n+0.5); 38 for (int i=0; i < n; i++) { 39 r += thickness[i]; 40 } 41 return r; 42 //return outer_radius(core_radius,fp_n,thickness); 43 } else { 44 return core_radius; 45 } 46 } 47 21 48 static void 22 49 Fq(double q, double *F1, double *F2, double core_sld, double core_radius, -
sasmodels/models/core_multi_shell.py
r71b751d rd277229 100 100 source = ["lib/sas_3j1x_x.c", "core_multi_shell.c"] 101 101 have_Fq = True 102 effective_radius_type = ["outer radius", "core radius"] 102 103 103 104 def random(): … … 144 145 return np.asarray(z), np.asarray(rho) 145 146 146 def ER(radius, n, thickness):147 """Effective radius"""148 n = int(n[0]+0.5) # n is a control parameter and is not polydisperse149 return np.sum(thickness[:n], axis=0) + radius147 #def ER(radius, n, thickness): 148 # """Effective radius""" 149 # n = int(n[0]+0.5) # n is a control parameter and is not polydisperse 150 # return np.sum(thickness[:n], axis=0) + radius 150 151 151 152 demo = dict(sld_core=6.4, -
sasmodels/models/core_shell_bicelle.c
r71b751d rd277229 34 34 35 35 return t; 36 } 37 38 static double 39 radius_from_volume(double radius, double thick_rim, double thick_face, double length) 40 { 41 const double volume_bicelle = form_volume(radius,thick_rim,thick_face,length); 42 return cbrt(0.75*volume_bicelle/M_PI); 43 } 44 45 static double 46 radius_from_diagonal(double radius, double thick_rim, double thick_face, double length) 47 { 48 const double radius_tot = radius + thick_rim; 49 const double length_tot = length + 2.0*thick_face; 50 return sqrt(radius_tot*radius_tot + 0.25*length_tot*length_tot); 51 } 52 53 static double 54 effective_radius(int mode, double radius, double thick_rim, double thick_face, double length) 55 { 56 if (mode == 1) { 57 return radius_from_volume(radius, thick_rim, thick_face, length); 58 } else if (mode == 2) { 59 return radius + thick_rim; 60 } else if (mode == 3) { 61 return 0.5*length + thick_face; 62 } else { 63 return radius_from_diagonal(radius,thick_rim,thick_face,length); 64 } 36 65 } 37 66 -
sasmodels/models/core_shell_bicelle.py
r71b751d rd277229 155 155 "core_shell_bicelle.c"] 156 156 have_Fq = True 157 effective_radius_type = ["equivalent sphere","outer rim radius", "half outer thickness","half diagonal"] 157 158 158 159 def random(): -
sasmodels/models/core_shell_bicelle_elliptical.c
r71b751d rd277229 8 8 { 9 9 return M_PI*(r_minor+thick_rim)*(r_minor*x_core+thick_rim)*(length+2.0*thick_face); 10 } 11 12 static double 13 radius_from_volume(double r_minor, double x_core, double thick_rim, double thick_face, double length) 14 { 15 const double volume_bicelle = form_volume(r_minor, x_core, thick_rim,thick_face,length); 16 return cbrt(0.75*volume_bicelle/M_PI); 17 } 18 19 static double 20 radius_from_diagonal(double r_minor, double x_core, double thick_rim, double thick_face, double length) 21 { 22 const double radius_max = (x_core < 1.0 ? r_minor : x_core*r_minor); 23 const double radius_max_tot = radius_max + thick_rim; 24 const double length_tot = length + 2.0*thick_face; 25 return sqrt(radius_max_tot*radius_max_tot + 0.25*length_tot*length_tot); 26 } 27 28 static double 29 effective_radius(int mode, double r_minor, double x_core, double thick_rim, double thick_face, double length) 30 { 31 if (mode == 1) { 32 return radius_from_volume(r_minor, x_core, thick_rim, thick_face, length); 33 } else if (mode == 2) { 34 return 0.5*r_minor*(1.0 + x_core) + thick_rim; 35 } else if (mode == 3) { 36 return (x_core < 1.0 ? x_core*r_minor+thick_rim : r_minor+thick_rim); 37 } else if (mode == 4) { 38 return (x_core > 1.0 ? x_core*r_minor+thick_rim : r_minor+thick_rim); 39 } else if (mode ==5) { 40 return 0.5*length + thick_face; 41 } else { 42 return radius_from_diagonal(r_minor,x_core,thick_rim,thick_face,length); 43 } 10 44 } 11 45 -
sasmodels/models/core_shell_bicelle_elliptical.py
r71b751d rd277229 147 147 "core_shell_bicelle_elliptical.c"] 148 148 have_Fq = True 149 effective_radius_type = ["equivalent sphere","outer rim average radius","outer rim min radius", 150 "outer max radius", "half outer thickness","half diagonal"] 149 151 150 152 def random(): -
sasmodels/models/core_shell_bicelle_elliptical_belt_rough.c
r71b751d rd277229 9 9 return M_PI*( (r_minor + thick_rim)*(r_minor*x_core + thick_rim)* length + 10 10 square(r_minor)*x_core*2.0*thick_face ); 11 } 12 13 static double 14 radius_from_volume(double r_minor, double x_core, double thick_rim, double thick_face, double length) 15 { 16 const double volume_bicelle = form_volume(r_minor, x_core, thick_rim,thick_face,length); 17 return cbrt(0.75*volume_bicelle/M_PI); 18 } 19 20 static double 21 radius_from_diagonal(double r_minor, double x_core, double thick_rim, double thick_face, double length) 22 { 23 const double radius_max = (x_core < 1.0 ? r_minor : x_core*r_minor); 24 const double radius_max_tot = radius_max + thick_rim; 25 const double length_tot = length + 2.0*thick_face; 26 return sqrt(radius_max_tot*radius_max_tot + 0.25*length_tot*length_tot); 27 } 28 29 static double 30 effective_radius(int mode, double r_minor, double x_core, double thick_rim, double thick_face, double length) 31 { 32 if (mode == 1) { 33 return radius_from_volume(r_minor, x_core, thick_rim, thick_face, length); 34 } else if (mode == 2) { 35 return 0.5*r_minor*(1.0 + x_core) + thick_rim; 36 } else if (mode == 3) { 37 return (x_core < 1.0 ? x_core*r_minor+thick_rim : r_minor+thick_rim); 38 } else if (mode == 4) { 39 return (x_core > 1.0 ? x_core*r_minor+thick_rim : r_minor+thick_rim); 40 } else if (mode ==5) { 41 return 0.5*length + thick_face; 42 } else { 43 return radius_from_diagonal(r_minor,x_core,thick_rim,thick_face,length); 44 } 11 45 } 12 46 -
sasmodels/models/core_shell_bicelle_elliptical_belt_rough.py
r71b751d rd277229 160 160 "core_shell_bicelle_elliptical_belt_rough.c"] 161 161 have_Fq = True 162 effective_radius_type = ["equivalent sphere","outer rim average radius","outer rim min radius", 163 "outer max radius", "half outer thickness","half diagonal"] 162 164 163 165 demo = dict(scale=1, background=0, -
sasmodels/models/core_shell_cylinder.c
r71b751d rd277229 11 11 { 12 12 return M_PI*square(radius+thickness)*(length+2.0*thickness); 13 } 14 15 static double 16 radius_from_volume(double radius, double thickness, double length) 17 { 18 const double volume_outer_cyl = form_volume(radius,thickness,length); 19 return cbrt(0.75*volume_outer_cyl/M_PI); 20 } 21 22 static double 23 radius_from_diagonal(double radius, double thickness, double length) 24 { 25 const double radius_outer = radius + thickness; 26 const double length_outer = length + thickness; 27 return sqrt(radius_outer*radius_outer + 0.25*length_outer*length_outer); 28 } 29 30 static double 31 effective_radius(int mode, double radius, double thickness, double length) 32 { 33 if (mode == 1) { 34 return radius_from_volume(radius, thickness, length); 35 } else if (mode == 2) { 36 return radius + thickness; 37 } else if (mode == 3) { 38 return 0.5*length + thickness; 39 } else if (mode == 4) { 40 return (radius < 0.5*length ? radius + thickness : 0.5*length + thickness); 41 } else if (mode == 5) { 42 return (radius > 0.5*length ? radius + thickness : 0.5*length + thickness); 43 } else { 44 return radius_from_diagonal(radius,thickness,length); 45 } 13 46 } 14 47 -
sasmodels/models/core_shell_cylinder.py
r71b751d rd277229 126 126 source = ["lib/polevl.c", "lib/sas_J1.c", "lib/gauss76.c", "core_shell_cylinder.c"] 127 127 have_Fq = True 128 effective_radius_type = ["equivalent sphere","outer radius","half outer length","half min outer dimension", 129 "half max outer dimension","half outer diagonal"] 128 130 129 def ER(radius, thickness, length):130 """131 Returns the effective radius used in the S*P calculation132 """133 radius = radius + thickness134 length = length + 2 * thickness135 ddd = 0.75 * radius * (2 * radius * length + (length + radius) * (length + pi * radius))136 return 0.5 * (ddd) ** (1. / 3.)131 #def ER(radius, thickness, length): 132 # """ 133 # Returns the effective radius used in the S*P calculation 134 # """ 135 # radius = radius + thickness 136 # length = length + 2 * thickness 137 # ddd = 0.75 * radius * (2 * radius * length + (length + radius) * (length + pi * radius)) 138 # return 0.5 * (ddd) ** (1. / 3.) 137 139 138 140 def VR(radius, thickness, length): -
sasmodels/models/core_shell_ellipsoid.c
r71b751d r3c60146 36 36 double vol = M_4PI_3*equat_shell*equat_shell*polar_shell; 37 37 return vol; 38 } 39 40 static double 41 radius_from_volume(double radius_equat_core, double x_core, double thick_shell, double x_polar_shell) 42 { 43 const double volume_ellipsoid = form_volume(radius_equat_core, x_core, thick_shell, x_polar_shell); 44 return cbrt(0.75*volume_ellipsoid/M_PI); 45 } 46 47 static double 48 radius_from_curvature(double radius_equat_core, double x_core, double thick_shell, double x_polar_shell) 49 { 50 // Trivial cases 51 if (1.0 == x_core && 1.0 == x_polar_shell) return radius_equat_core + thick_shell; 52 if ((radius_equat_core + thick_shell)*(radius_equat_core*x_core + thick_shell*x_polar_shell) == 0.) return 0.; 53 54 // see equation (26) in A.Isihara, J.Chem.Phys. 18(1950)1446-1449 55 const double radius_equat_tot = radius_equat_core + thick_shell; 56 const double radius_polar_tot = radius_equat_core*x_core + thick_shell*x_polar_shell; 57 const double ratio = (radius_polar_tot < radius_equat_tot 58 ? radius_polar_tot / radius_equat_tot 59 : radius_equat_tot / radius_polar_tot); 60 const double e1 = sqrt(1.0 - ratio*ratio); 61 const double b1 = 1.0 + asin(e1) / (e1 * ratio); 62 const double bL = (1.0 + e1) / (1.0 - e1); 63 const double b2 = 1.0 + 0.5 * ratio * ratio / e1 * log(bL); 64 const double delta = 0.75 * b1 * b2; 65 const double ddd = 2.0 * (delta + 1.0) * radius_polar_tot * radius_equat_tot * radius_equat_tot; 66 return 0.5 * cbrt(ddd); 67 } 68 69 static double 70 effective_radius(int mode, double radius_equat_core, double x_core, double thick_shell, double x_polar_shell) 71 { 72 const double radius_equat_tot = radius_equat_core + thick_shell; 73 const double radius_polar_tot = radius_equat_core*x_core + thick_shell*x_polar_shell; 74 75 if (mode == 1) { 76 return radius_from_volume(radius_equat_core, x_core, thick_shell, x_polar_shell); 77 } else if (mode == 2) { 78 return radius_from_curvature(radius_equat_core, x_core, thick_shell, x_polar_shell); 79 } else if (mode == 3) { 80 return (radius_polar_tot < radius_equat_tot ? radius_polar_tot : radius_equat_tot); 81 } else { 82 return (radius_polar_tot > radius_equat_tot ? radius_polar_tot : radius_equat_tot); 83 } 38 84 } 39 85 -
sasmodels/models/core_shell_ellipsoid.py
r71b751d rd277229 146 146 source = ["lib/sas_3j1x_x.c", "lib/gauss76.c", "core_shell_ellipsoid.c"] 147 147 have_Fq = True 148 149 def ER(radius_equat_core, x_core, thick_shell, x_polar_shell): 150 """ 151 Returns the effective radius used in the S*P calculation 152 """ 153 from .ellipsoid import ER as ellipsoid_ER 154 polar_outer = radius_equat_core*x_core + thick_shell*x_polar_shell 155 equat_outer = radius_equat_core + thick_shell 156 return ellipsoid_ER(polar_outer, equat_outer) 148 effective_radius_type = ["equivalent sphere","average outer curvature", "min outer radius", "max outer radius"] 149 150 #def ER(radius_equat_core, x_core, thick_shell, x_polar_shell): 151 # """ 152 # Returns the effective radius used in the S*P calculation 153 # """ 154 # from .ellipsoid import ER as ellipsoid_ER 155 # polar_outer = radius_equat_core*x_core + thick_shell*x_polar_shell 156 # equat_outer = radius_equat_core + thick_shell 157 # return ellipsoid_ER(polar_outer, equat_outer) 157 158 158 159 def random(): -
sasmodels/models/core_shell_parallelepiped.c
r71b751d rd277229 25 25 2.0 * length_a * length_b * thick_rim_c; 26 26 #endif 27 } 28 29 static double 30 radius_from_volume(double length_a, double length_b, double length_c, 31 double thick_rim_a, double thick_rim_b, double thick_rim_c) 32 { 33 const double volume_paral = form_volume(length_a, length_b, length_c, thick_rim_a, thick_rim_b, thick_rim_c); 34 return cbrt(0.75*volume_paral/M_PI); 35 } 36 37 static double 38 radius_from_crosssection(double length_a, double length_b, double thick_rim_a, double thick_rim_b) 39 { 40 const double area_xsec_paral = length_a*length_b + 2.0*thick_rim_a*length_b + 2.0*thick_rim_b*length_a; 41 return sqrt(area_xsec_paral/M_PI); 42 } 43 44 static double 45 effective_radius(int mode, double length_a, double length_b, double length_c, 46 double thick_rim_a, double thick_rim_b, double thick_rim_c) 47 { 48 if (mode == 1) { 49 return radius_from_volume(length_a, length_b, length_c, thick_rim_a, thick_rim_b, thick_rim_c); 50 } else if (mode == 2) { 51 return 0.5 * (length_a + thick_rim_a); 52 } else if (mode == 3) { 53 return 0.5 * (length_b + thick_rim_b); 54 } else if (mode == 4) { 55 return 0.5 * (length_c + thick_rim_c); 56 } else if (mode == 5) { 57 return radius_from_crosssection(length_a, length_b, thick_rim_a, thick_rim_b); 58 } else if (mode == 6) { 59 return 0.5*sqrt(square(length_a+thick_rim_a) + square(length_b+thick_rim_b)); 60 } else { 61 return 0.5*sqrt(square(length_a+thick_rim_a) + square(length_b+thick_rim_b) + square(length_c+thick_rim_c)); 62 } 27 63 } 28 64 -
sasmodels/models/core_shell_parallelepiped.py
r71b751d rd277229 227 227 source = ["lib/gauss76.c", "core_shell_parallelepiped.c"] 228 228 have_Fq = True 229 230 231 def ER(length_a, length_b, length_c, thick_rim_a, thick_rim_b, thick_rim_c): 232 """ 233 Return equivalent radius (ER) 234 """ 235 from .parallelepiped import ER as ER_p 236 237 a = length_a + 2*thick_rim_a 238 b = length_b + 2*thick_rim_b 239 c = length_c + 2*thick_rim_c 240 return ER_p(a, b, c) 229 effective_radius_type = ["equivalent sphere","half outer length_a", "half outer length_b", "half outer length_c", 230 "equivalent circular cross-section","half outer ab diagonal","half outer diagonal"] 231 232 #def ER(length_a, length_b, length_c, thick_rim_a, thick_rim_b, thick_rim_c): 233 # """ 234 # Return equivalent radius (ER) 235 # """ 236 # from .parallelepiped import ER as ER_p 237 # 238 # a = length_a + 2*thick_rim_a 239 # b = length_b + 2*thick_rim_b 240 # c = length_c + 2*thick_rim_c 241 # return ER_p(a, b, c) 241 242 242 243 # VR defaults to 1.0 -
sasmodels/models/core_shell_sphere.c
r71b751d rd277229 3 3 { 4 4 return M_4PI_3 * cube(radius + thickness); 5 } 6 7 static double 8 effective_radius(int mode, double radius, double thickness) 9 { 10 if (mode == 1) { 11 return radius + thickness; 12 } else { 13 return radius; 14 } 5 15 } 6 16 -
sasmodels/models/core_shell_sphere.py
r71b751d rd277229 78 78 source = ["lib/sas_3j1x_x.c", "lib/core_shell.c", "core_shell_sphere.c"] 79 79 have_Fq = True 80 effective_radius_type = ["outer radius", "core radius"] 80 81 81 82 demo = dict(scale=1, background=0, radius=60, thickness=10, 82 83 sld_core=1.0, sld_shell=2.0, sld_solvent=0.0) 83 84 84 def ER(radius, thickness):85 """86 Equivalent radius87 @param radius: core radius88 @param thickness: shell thickness89 """90 return radius + thickness85 #def ER(radius, thickness): 86 # """ 87 # Equivalent radius 88 # @param radius: core radius 89 # @param thickness: shell thickness 90 # """ 91 # return radius + thickness 91 92 92 93 def VR(radius, thickness): -
sasmodels/models/cylinder.c
r71b751d rd277229 11 11 { 12 12 return sas_2J1x_x(qab*radius) * sas_sinx_x(qc*0.5*length); 13 } 14 15 static double 16 radius_from_volume(double radius, double length) 17 { 18 return cbrt(0.75*radius*radius*length); 19 } 20 21 static double 22 radius_from_diagonal(double radius, double length) 23 { 24 return sqrt(radius*radius + 0.25*length*length); 25 } 26 27 static double 28 effective_radius(int mode, double radius, double length) 29 { 30 if (mode == 1) { 31 return radius_from_volume(radius, length); 32 } else if (mode == 2) { 33 return radius; 34 } else if (mode == 3) { 35 return 0.5*length; 36 } else if (mode == 4) { 37 return (radius < 0.5*length ? radius : 0.5*length); 38 } else if (mode == 5) { 39 return (radius > 0.5*length ? radius : 0.5*length); 40 } else { 41 return radius_from_diagonal(radius,length); 42 } 13 43 } 14 44 -
sasmodels/models/cylinder.py
r71b751d rd277229 139 139 source = ["lib/polevl.c", "lib/sas_J1.c", "lib/gauss76.c", "cylinder.c"] 140 140 have_Fq = True 141 effective_radius_type = ["equivalent sphere","radius","half length","half min dimension","half max dimension","half diagonal"] 141 142 142 def ER(radius, length):143 """144 Return equivalent radius (ER)145 """146 ddd = 0.75 * radius * (2 * radius * length + (length + radius) * (length + pi * radius))147 return 0.5 * (ddd) ** (1. / 3.)143 #def ER(radius, length): 144 # """ 145 # Return equivalent radius (ER) 146 # """ 147 # ddd = 0.75 * radius * (2 * radius * length + (length + radius) * (length + pi * radius)) 148 # return 0.5 * (ddd) ** (1. / 3.) 148 149 149 150 def random(): -
sasmodels/models/ellipsoid.c
r6e7ba14 rd277229 4 4 return M_4PI_3*radius_polar*radius_equatorial*radius_equatorial; 5 5 } 6 7 6 8 7 static double … … 20 19 21 20 // see equation (26) in A.Isihara, J.Chem.Phys. 18(1950)1446-1449 22 const double ratio = (radius_polar < radius_equatorial 21 const double ratio = (radius_polar < radius_equatorial 23 22 ? radius_polar / radius_equatorial 24 23 : radius_equatorial / radius_polar); … … 36 35 { 37 36 if (mode == 1) { 37 return radius_from_volume(radius_polar, radius_equatorial); 38 } else if (mode == 2) { 38 39 return radius_from_curvature(radius_polar, radius_equatorial); 39 } else if (mode == 2) {40 return radius_from_volume(radius_polar, radius_equatorial);41 40 } else if (mode == 3) { 42 41 return (radius_polar < radius_equatorial ? radius_polar : radius_equatorial); -
sasmodels/models/ellipsoid.py
r6e7ba14 rd277229 164 164 source = ["lib/sas_3j1x_x.c", "lib/gauss76.c", "ellipsoid.c"] 165 165 have_Fq = True 166 effective_radius_type = [" average curvature", "equivalent sphere", "min radius", "max radius"]166 effective_radius_type = ["equivalent sphere","average curvature", "min radius", "max radius"] 167 167 168 168 def random(): -
sasmodels/models/elliptical_cylinder.c
r71b751d rd277229 3 3 { 4 4 return M_PI * radius_minor * radius_minor * r_ratio * length; 5 } 6 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 15 radius_from_min_dimension(double radius_minor, double r_ratio, double length) 16 { 17 const double rad_min = (r_ratio > 1.0 ? radius_minor : r_ratio*radius_minor); 18 return (rad_min < length ? rad_min : length); 19 } 20 21 static double 22 radius_from_max_dimension(double radius_minor, double r_ratio, double length) 23 { 24 const double rad_max = (r_ratio < 1.0 ? radius_minor : r_ratio*radius_minor); 25 return (rad_max > length ? rad_max : length); 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_max*radius_max + 0.25*length*length); 33 } 34 35 static double 36 effective_radius(int mode, double radius_minor, double r_ratio, double length) 37 { 38 if (mode == 1) { 39 return radius_from_volume(radius_minor, r_ratio, length); 40 } else if (mode == 2) { 41 return 0.5*radius_minor*(1.0 + r_ratio); 42 } else if (mode == 3) { 43 return (r_ratio > 1.0 ? radius_minor : r_ratio*radius_minor); 44 } else if (mode == 4) { 45 return (r_ratio < 1.0 ? radius_minor : r_ratio*radius_minor); 46 } else if (mode == 5) { 47 return sqrt(radius_minor*radius_minor*r_ratio); 48 } else if (mode == 6) { 49 return 0.5*length; 50 } else if (mode == 7) { 51 return radius_from_min_dimension(radius_minor,r_ratio,length); 52 } else if (mode == 8) { 53 return radius_from_max_dimension(radius_minor,r_ratio,length); 54 } else { 55 return radius_from_diagonal(radius_minor,r_ratio,length); 56 } 5 57 } 6 58 -
sasmodels/models/elliptical_cylinder.py
r71b751d rd277229 123 123 source = ["lib/polevl.c", "lib/sas_J1.c", "lib/gauss76.c", "elliptical_cylinder.c"] 124 124 have_Fq = True 125 effective_radius_type = ["equivalent sphere","average radius","min radius","max radius", 126 "equivalent circular cross-section","half length","half min dimension","half max dimension","half diagonal"] 125 127 126 128 demo = dict(scale=1, background=0, radius_minor=100, axis_ratio=1.5, length=400.0, … … 128 130 theta_pd=10, phi_pd=2, psi_pd=3) 129 131 130 def ER(radius_minor, axis_ratio, length):131 """132 Equivalent radius133 @param radius_minor: Ellipse minor radius134 @param axis_ratio: Ratio of major radius over minor radius135 @param length: Length of the cylinder136 """137 radius = sqrt(radius_minor * radius_minor * axis_ratio)138 ddd = 0.75 * radius * (2 * radius * length139 + (length + radius) * (length + pi * radius))140 return 0.5 * (ddd) ** (1. / 3.)132 #def ER(radius_minor, axis_ratio, length): 133 # """ 134 # Equivalent radius 135 # @param radius_minor: Ellipse minor radius 136 # @param axis_ratio: Ratio of major radius over minor radius 137 # @param length: Length of the cylinder 138 # """ 139 # radius = sqrt(radius_minor * radius_minor * axis_ratio) 140 # ddd = 0.75 * radius * (2 * radius * length 141 # + (length + radius) * (length + pi * radius)) 142 # return 0.5 * (ddd) ** (1. / 3.) 141 143 142 144 def random(): -
sasmodels/models/fuzzy_sphere.py
r71b751d rd277229 78 78 ["sld_solvent", "1e-6/Ang^2", 3, [-inf, inf], "sld", "Solvent scattering length density"], 79 79 ["radius", "Ang", 60, [0, inf], "volume", "Sphere radius"], 80 ["fuzziness", "Ang", 10, [0, inf], " ", "std deviation of Gaussian convolution for interface (must be << radius)"],80 ["fuzziness", "Ang", 10, [0, inf], "volume", "std deviation of Gaussian convolution for interface (must be << radius)"], 81 81 ] 82 82 # pylint: enable=bad-whitespace,line-too-long 83 83 84 source = ["lib/sas_3j1x_x.c" ]84 source = ["lib/sas_3j1x_x.c","fuzzy_sphere.c"] 85 85 have_Fq = True 86 effective_radius_type = ["radius","radius + fuzziness"] 86 87 87 c_code = """ 88 static double form_volume(double radius) 89 { 90 return M_4PI_3*cube(radius); 91 } 92 93 static void Fq(double q, double *F1, double *F2, double sld, double sld_solvent, 94 double radius, double fuzziness) 95 { 96 const double qr = q*radius; 97 const double bes = sas_3j1x_x(qr); 98 const double qf = exp(-0.5*square(q*fuzziness)); 99 const double contrast = (sld - sld_solvent); 100 const double form = contrast * form_volume(radius) * bes * qf; 101 *F1 = 1.0e-2*form; 102 *F2 = 1.0e-4*form*form; 103 } 104 """ 105 106 def ER(radius): 107 """ 108 Return radius 109 """ 110 return radius 88 #def ER(radius): 89 # """ 90 # Return radius 91 # """ 92 # return radius 111 93 112 94 # VR defaults to 1.0 -
sasmodels/models/hollow_cylinder.c
r71b751d rd277229 22 22 } 23 23 24 static double 25 radius_from_volume(double radius, double thickness, double length) 26 { 27 const double volume_outer_cyl = M_PI*square(radius + thickness)*length; 28 return cbrt(0.75*volume_outer_cyl/M_PI); 29 } 30 31 static double 32 radius_from_diagonal(double radius, double thickness, double length) 33 { 34 return sqrt(square(radius + thickness) + 0.25*square(length)); 35 } 36 37 static double 38 effective_radius(int mode, double radius, double thickness, double length) 39 { 40 if (mode == 1) { 41 return radius_from_volume(radius, thickness, length); 42 } else if (mode == 2) { 43 return radius + thickness; 44 } else if (mode == 3) { 45 return 0.5*length; 46 } else if (mode == 4) { 47 return (radius + thickness < 0.5*length ? radius + thickness : 0.5*length); 48 } else if (mode == 5) { 49 return (radius + thickness > 0.5*length ? radius + thickness : 0.5*length); 50 } else { 51 return radius_from_diagonal(radius,thickness,length); 52 } 53 } 24 54 25 55 static void -
sasmodels/models/hollow_cylinder.py
r71b751d rd277229 90 90 source = ["lib/polevl.c", "lib/sas_J1.c", "lib/gauss76.c", "hollow_cylinder.c"] 91 91 have_Fq = True 92 effective_radius_type = ["equivalent sphere","outer radius","half length", 93 "half outer min dimension","half outer max dimension","half outer diagonal"] 92 94 93 95 # pylint: disable=W0613 94 def ER(radius, thickness, length):95 """96 :param radius: Cylinder core radius97 :param thickness: Cylinder wall thickness98 :param length: Cylinder length99 :return: Effective radius100 """101 router = radius + thickness102 if router == 0 or length == 0:103 return 0.0104 len1 = router105 len2 = length/2.0106 term1 = len1*len1*2.0*len2/2.0107 term2 = 1.0 + (len2/len1)*(1.0 + 1/len2/2.0)*(1.0 + pi*len1/len2/2.0)108 ddd = 3.0*term1*term2109 diam = pow(ddd, (1.0/3.0))110 return diam96 #def ER(radius, thickness, length): 97 # """ 98 # :param radius: Cylinder core radius 99 # :param thickness: Cylinder wall thickness 100 # :param length: Cylinder length 101 # :return: Effective radius 102 # """ 103 # router = radius + thickness 104 # if router == 0 or length == 0: 105 # return 0.0 106 # len1 = router 107 # len2 = length/2.0 108 # term1 = len1*len1*2.0*len2/2.0 109 # term2 = 1.0 + (len2/len1)*(1.0 + 1/len2/2.0)*(1.0 + pi*len1/len2/2.0) 110 # ddd = 3.0*term1*term2 111 # diam = pow(ddd, (1.0/3.0)) 112 # return diam 111 113 112 114 def VR(radius, thickness, length): -
sasmodels/models/hollow_rectangular_prism.c
r71b751d rd277229 11 11 double vol_shell = vol_total - vol_core; 12 12 return vol_shell; 13 } 14 15 static double 16 effective_radius(int mode, double length_a, double b2a_ratio, double c2a_ratio, double thickness) 17 { 18 if (mode == 1) { 19 return cbrt(0.75*cube(length_a)*b2a_ratio*c2a_ratio/M_PI); 20 } else if (mode == 2) { 21 return 0.5 * length_a; 22 } else if (mode == 3) { 23 return 0.5 * length_a*b2a_ratio; 24 } else if (mode == 4) { 25 return 0.5 * length_a*c2a_ratio; 26 } else if (mode == 5) { 27 return length_a*sqrt(b2a_ratio/M_PI); 28 } else if (mode == 6) { 29 return 0.5*sqrt(square(length_a) * (1.0 + square(b2a_ratio))); 30 } else { 31 return 0.5*sqrt(square(length_a) * (1.0 + square(b2a_ratio) + square(c2a_ratio))); 32 } 13 33 } 14 34 -
sasmodels/models/hollow_rectangular_prism.py
r71b751d rd277229 143 143 source = ["lib/gauss76.c", "hollow_rectangular_prism.c"] 144 144 have_Fq = True 145 146 def ER(length_a, b2a_ratio, c2a_ratio, thickness): 147 """ 148 Return equivalent radius (ER) 149 thickness parameter not used 150 """ 151 b_side = length_a * b2a_ratio 152 c_side = length_a * c2a_ratio 153 154 # surface average radius (rough approximation) 155 surf_rad = sqrt(length_a * b_side / pi) 156 157 ddd = 0.75 * surf_rad * (2 * surf_rad * c_side + (c_side + surf_rad) * (c_side + pi * surf_rad)) 158 return 0.5 * (ddd) ** (1. / 3.) 145 effective_radius_type = ["equivalent sphere","half length_a", "half length_b", "half length_c", 146 "equivalent outer circular cross-section","half ab diagonal","half diagonal"] 147 148 #def ER(length_a, b2a_ratio, c2a_ratio, thickness): 149 # """ 150 # Return equivalent radius (ER) 151 # thickness parameter not used 152 # """ 153 # b_side = length_a * b2a_ratio 154 # c_side = length_a * c2a_ratio 155 # 156 # # surface average radius (rough approximation) 157 # surf_rad = sqrt(length_a * b_side / pi) 158 # 159 # ddd = 0.75 * surf_rad * (2 * surf_rad * c_side + (c_side + surf_rad) * (c_side + pi * surf_rad)) 160 # return 0.5 * (ddd) ** (1. / 3.) 159 161 160 162 def VR(length_a, b2a_ratio, c2a_ratio, thickness): -
sasmodels/models/hollow_rectangular_prism_thin_walls.c
r71b751d rd277229 6 6 double vol_shell = 2.0 * (length_a*length_b + length_a*length_c + length_b*length_c); 7 7 return vol_shell; 8 } 9 10 static double 11 effective_radius(int mode, double length_a, double b2a_ratio, double c2a_ratio) 12 { 13 if (mode == 1) { 14 return cbrt(0.75*cube(length_a)*b2a_ratio*c2a_ratio/M_PI); 15 } else if (mode == 2) { 16 return 0.5 * length_a; 17 } else if (mode == 3) { 18 return 0.5 * length_a*b2a_ratio; 19 } else if (mode == 4) { 20 return 0.5 * length_a*c2a_ratio; 21 } else if (mode == 5) { 22 return length_a*sqrt(b2a_ratio/M_PI); 23 } else if (mode == 6) { 24 return 0.5*sqrt(square(length_a) * (1.0 + square(b2a_ratio))); 25 } else { 26 return 0.5*sqrt(square(length_a) * (1.0 + square(b2a_ratio) + square(c2a_ratio))); 27 } 8 28 } 9 29 -
sasmodels/models/hollow_rectangular_prism_thin_walls.py
r71b751d rd277229 103 103 source = ["lib/gauss76.c", "hollow_rectangular_prism_thin_walls.c"] 104 104 have_Fq = True 105 effective_radius_type = ["equivalent sphere","half length_a", "half length_b", "half length_c", 106 "equivalent outer circular cross-section","half ab diagonal","half diagonal"] 105 107 106 def ER(length_a, b2a_ratio, c2a_ratio):107 """108 Return equivalent radius (ER)109 """110 b_side = length_a * b2a_ratio111 c_side = length_a * c2a_ratio112 113 # surface average radius (rough approximation)114 surf_rad = sqrt(length_a * b_side / pi)115 116 ddd = 0.75 * surf_rad * (2 * surf_rad * c_side + (c_side + surf_rad) * (c_side + pi * surf_rad))117 return 0.5 * (ddd) ** (1. / 3.)108 #def ER(length_a, b2a_ratio, c2a_ratio): 109 # """ 110 # Return equivalent radius (ER) 111 # """ 112 # b_side = length_a * b2a_ratio 113 # c_side = length_a * c2a_ratio 114 # 115 # # surface average radius (rough approximation) 116 # surf_rad = sqrt(length_a * b_side / pi) 117 # 118 # ddd = 0.75 * surf_rad * (2 * surf_rad * c_side + (c_side + surf_rad) * (c_side + pi * surf_rad)) 119 # return 0.5 * (ddd) ** (1. / 3.) 118 120 119 121 def VR(length_a, b2a_ratio, c2a_ratio): -
sasmodels/models/mono_gauss_coil.py
r2d81cfe rd277229 54 54 55 55 import numpy as np 56 from numpy import inf , exp, errstate56 from numpy import inf 57 57 58 58 name = "mono_gauss_coil" … … 69 69 parameters = [ 70 70 ["i_zero", "1/cm", 70.0, [0.0, inf], "", "Intensity at q=0"], 71 ["rg", "Ang", 75.0, [0.0, inf], " ", "Radius of gyration"],71 ["rg", "Ang", 75.0, [0.0, inf], "volume", "Radius of gyration"], 72 72 ] 73 74 source = ["mono_gauss_coil.c"] 75 have_Fq = False 76 effective_radius_type = ["R_g","2R_g","3R_g","(5/3)^0.5*R_g"] 77 78 73 79 # pylint: enable=bad-whitespace, line-too-long 74 80 75 # NB: Scale and Background are implicit parameters on every model76 def Iq(q, i_zero, rg):77 # pylint: disable = missing-docstring78 z = (q * rg)**279 80 with errstate(invalid='ignore'):81 inten = (i_zero * 2.0) * (exp(-z) + z - 1.0)/z**282 inten[q == 0] = i_zero83 return inten84 Iq.vectorized = True # Iq accepts an array of q values81 ## NB: Scale and Background are implicit parameters on every model 82 #def Iq(q, i_zero, rg): 83 # # pylint: disable = missing-docstring 84 # z = (q * rg)**2 85 # 86 # with errstate(invalid='ignore'): 87 # inten = (i_zero * 2.0) * (exp(-z) + z - 1.0)/z**2 88 # inten[q == 0] = i_zero 89 # return inten 90 #Iq.vectorized = True # Iq accepts an array of q values 85 91 86 92 def random(): -
sasmodels/models/multilayer_vesicle.c
r71b751d rd277229 47 47 } 48 48 49 static double 50 effective_radius(int mode, double radius, double thick_shell, double thick_solvent, double fp_n_shells) 51 { 52 return radius + fp_n_shells*thick_shell + (fp_n_shells - 1.0)*thick_solvent; 53 } 54 49 55 static void 50 56 Fq(double q, -
sasmodels/models/multilayer_vesicle.py
r71b751d rd277229 146 146 source = ["lib/sas_3j1x_x.c", "multilayer_vesicle.c"] 147 147 have_Fq = True 148 effective_radius_type = ["outer radius"] 148 149 149 def ER(radius, thick_shell, thick_solvent, n_shells):150 n_shells = int(n_shells+0.5)151 return radius + n_shells * (thick_shell + thick_solvent) - thick_solvent150 #def ER(radius, thick_shell, thick_solvent, n_shells): 151 # n_shells = int(n_shells+0.5) 152 # return radius + n_shells * (thick_shell + thick_solvent) - thick_solvent 152 153 153 154 def random(): -
sasmodels/models/onion.c
r71b751d rd277229 40 40 } 41 41 42 static double 43 effective_radius(int mode, double radius_core, double n_shells, double thickness[]) 44 { 45 int n = (int)(n_shells+0.5); 46 double r = radius_core; 47 for (int i=0; i < n; i++) { 48 r += thickness[i]; 49 } 50 return r; 51 } 52 42 53 static void 43 54 Fq(double q, double *F1, double *F2, double sld_core, double radius_core, double sld_solvent, -
sasmodels/models/onion.py
r71b751d rd277229 316 316 single = False 317 317 have_Fq = True 318 effective_radius_type = ["outer radius"] 318 319 319 320 profile_axes = ['Radius (A)', 'SLD (1e-6/A^2)'] … … 366 367 return np.asarray(z), np.asarray(rho) 367 368 368 def ER(radius_core, n_shells, thickness):369 """Effective radius"""370 n = int(n_shells[0]+0.5)371 return np.sum(thickness[:n], axis=0) + radius_core369 #def ER(radius_core, n_shells, thickness): 370 # """Effective radius""" 371 # n = int(n_shells[0]+0.5) 372 # return np.sum(thickness[:n], axis=0) + radius_core 372 373 373 374 demo = { -
sasmodels/models/parallelepiped.c
r71b751d rd277229 3 3 { 4 4 return length_a * length_b * length_c; 5 } 6 7 static double 8 effective_radius(int mode, double length_a, double length_b, double length_c) 9 { 10 if (mode == 1) { 11 return cbrt(0.75*length_a*length_b*length_c/M_PI); 12 } else if (mode == 2) { 13 return 0.5 * length_a; 14 } else if (mode == 3) { 15 return 0.5 * length_b; 16 } else if (mode == 4) { 17 return 0.5 * length_c; 18 } else if (mode == 5) { 19 return sqrt(length_a*length_b/M_PI); 20 } else if (mode == 6) { 21 return 0.5*sqrt(length_a*length_a + length_b*length_b); 22 } else { 23 return 0.5*sqrt(length_a*length_a + length_b*length_b + length_c*length_c); 24 } 5 25 } 6 26 -
sasmodels/models/parallelepiped.py
r71b751d rd277229 231 231 source = ["lib/gauss76.c", "parallelepiped.c"] 232 232 have_Fq = True 233 234 def ER(length_a, length_b, length_c): 235 """ 236 Return effective radius (ER) for P(q)*S(q) 237 """ 238 # now that axes can be in any size order, need to sort a,b,c 239 # where a~b and c is either much smaller or much larger 240 abc = np.vstack((length_a, length_b, length_c)) 241 abc = np.sort(abc, axis=0) 242 selector = (abc[1] - abc[0]) > (abc[2] - abc[1]) 243 length = np.where(selector, abc[0], abc[2]) 244 # surface average radius (rough approximation) 245 radius = sqrt(np.where(~selector, abc[0]*abc[1], abc[1]*abc[2]) / pi) 246 247 ddd = 0.75 * radius * (2*radius*length + (length + radius)*(length + pi*radius)) 248 return 0.5 * (ddd) ** (1. / 3.) 233 effective_radius_type = ["equivalent sphere","half length_a", "half length_b", "half length_c", 234 "equivalent circular cross-section","half ab diagonal","half diagonal"] 235 236 #def ER(length_a, length_b, length_c): 237 # """ 238 # Return effective radius (ER) for P(q)*S(q) 239 # """ 240 # # now that axes can be in any size order, need to sort a,b,c 241 # # where a~b and c is either much smaller or much larger 242 # abc = np.vstack((length_a, length_b, length_c)) 243 # abc = np.sort(abc, axis=0) 244 # selector = (abc[1] - abc[0]) > (abc[2] - abc[1]) 245 # length = np.where(selector, abc[0], abc[2]) 246 # # surface average radius (rough approximation) 247 # radius = sqrt(np.where(~selector, abc[0]*abc[1], abc[1]*abc[2]) / pi) 248 # 249 # ddd = 0.75 * radius * (2*radius*length + (length + radius)*(length + pi*radius)) 250 # return 0.5 * (ddd) ** (1. / 3.) 249 251 250 252 # VR defaults to 1.0 -
sasmodels/models/pringle.c
r74768cb rd277229 104 104 } 105 105 106 static double 107 effective_radius(int mode, double radius, double thickness, double alpha, double beta) 108 { 109 if (mode == 1) { 110 return cbrt(0.75*radius*radius*thickness); 111 } else { 112 return radius; 113 } 114 } 115 106 116 double Iq( 107 117 double q, -
sasmodels/models/pringle.py
ref07e95 rd277229 74 74 source = ["lib/polevl.c", "lib/sas_J0.c", "lib/sas_J1.c", \ 75 75 "lib/sas_JN.c", "lib/gauss76.c", "pringle.c"] 76 effective_radius_type = ["equivalent sphere","radius"] 76 77 77 def ER(radius, thickness, alpha, beta):78 """79 Return equivalent radius (ER)80 """81 ddd = 0.75 * radius * (2 * radius * thickness + (thickness + radius) \82 * (thickness + pi * radius))83 return 0.5 * (ddd) ** (1. / 3.)78 #def ER(radius, thickness, alpha, beta): 79 # """ 80 # Return equivalent radius (ER) 81 # """ 82 # ddd = 0.75 * radius * (2 * radius * thickness + (thickness + radius) \ 83 # * (thickness + pi * radius)) 84 # return 0.5 * (ddd) ** (1. / 3.) 84 85 85 86 def random(): -
sasmodels/models/raspberry.c
r71b751d rd277229 1 double form_volume(double radius_lg );1 double form_volume(double radius_lg, double radius_sm, double penetration); 2 2 3 3 double Iq(double q, … … 6 6 double radius_lg, double radius_sm, double penetration); 7 7 8 double form_volume(double radius_lg )8 double form_volume(double radius_lg, double radius_sm, double penetration) 9 9 { 10 10 //Because of the complex structure, volume normalization must … … 12 12 double volume=1.0; 13 13 return volume; 14 } 15 16 static double 17 effective_radius(int mode, double radius_lg, double radius_sm, double penetration) 18 { 19 if (mode == 1) { 20 return radius_lg; 21 } else { 22 return radius_lg + 2.0*radius_sm - penetration; 23 } 14 24 } 15 25 -
sasmodels/models/raspberry.py
ref07e95 rd277229 145 145 ["radius_lg", "Ang", 5000, [0, inf], "volume", 146 146 "radius of large spheres"], 147 ["radius_sm", "Ang", 100, [0, inf], " ",147 ["radius_sm", "Ang", 100, [0, inf], "volume", 148 148 "radius of small spheres"], 149 ["penetration", "Ang", 0, [-1, 1], " ",149 ["penetration", "Ang", 0, [-1, 1], "volume", 150 150 "fractional penetration depth of small spheres into large sphere"], 151 151 ] 152 152 153 153 source = ["lib/sas_3j1x_x.c", "raspberry.c"] 154 effective_radius_type = ["radius_large","radius_outer"] 154 155 155 156 def random(): -
sasmodels/models/rectangular_prism.c
r71b751d rd277229 3 3 { 4 4 return length_a * (length_a*b2a_ratio) * (length_a*c2a_ratio); 5 } 6 7 static double 8 effective_radius(int mode, double length_a, double b2a_ratio, double c2a_ratio) 9 { 10 if (mode == 1) { 11 return cbrt(0.75*cube(length_a)*b2a_ratio*c2a_ratio/M_PI); 12 } else if (mode == 2) { 13 return 0.5 * length_a; 14 } else if (mode == 3) { 15 return 0.5 * length_a*b2a_ratio; 16 } else if (mode == 4) { 17 return 0.5 * length_a*c2a_ratio; 18 } else if (mode == 5) { 19 return length_a*sqrt(b2a_ratio/M_PI); 20 } else if (mode == 6) { 21 return 0.5*sqrt(square(length_a) * (1.0 + square(b2a_ratio))); 22 } else { 23 return 0.5*sqrt(square(length_a) * (1.0 + square(b2a_ratio) + square(c2a_ratio))); 24 } 5 25 } 6 26 -
sasmodels/models/rectangular_prism.py
r71b751d rd277229 136 136 source = ["lib/gauss76.c", "rectangular_prism.c"] 137 137 have_Fq = True 138 effective_radius_type = ["equivalent sphere","half length_a", "half length_b", "half length_c", 139 "equivalent circular cross-section","half ab diagonal","half diagonal"] 138 140 139 def ER(length_a, b2a_ratio, c2a_ratio):140 """141 Return equivalent radius (ER)142 """143 b_side = length_a * b2a_ratio144 c_side = length_a * c2a_ratio145 146 # surface average radius (rough approximation)147 surf_rad = sqrt(length_a * b_side / pi)148 149 ddd = 0.75 * surf_rad * (2 * surf_rad * c_side + (c_side + surf_rad) * (c_side + pi * surf_rad))150 return 0.5 * (ddd) ** (1. / 3.)141 #def ER(length_a, b2a_ratio, c2a_ratio): 142 # """ 143 # Return equivalent radius (ER) 144 # """ 145 # b_side = length_a * b2a_ratio 146 # c_side = length_a * c2a_ratio 147 # 148 # # surface average radius (rough approximation) 149 # surf_rad = sqrt(length_a * b_side / pi) 150 # 151 # ddd = 0.75 * surf_rad * (2 * surf_rad * c_side + (c_side + surf_rad) * (c_side + pi * surf_rad)) 152 # return 0.5 * (ddd) ** (1. / 3.) 151 153 152 154 def random(): -
sasmodels/models/sphere.py
r71b751d rd277229 67 67 ] 68 68 69 source = ["lib/sas_3j1x_x.c" ]69 source = ["lib/sas_3j1x_x.c","sphere.c"] 70 70 have_Fq = True 71 effective_radius_type = ["radius"] 71 72 72 c_code = """ 73 static double form_volume(double radius) 74 { 75 return M_4PI_3*cube(radius); 76 } 77 78 static void Fq(double q, double *f1, double *f2, double sld, double sld_solvent, double radius) 79 { 80 const double bes = sas_3j1x_x(q*radius); 81 const double contrast = (sld - sld_solvent); 82 const double form = contrast * form_volume(radius) * bes; 83 *f1 = 1.0e-2*form; 84 *f2 = 1.0e-4*form*form; 85 } 86 """ 87 88 def ER(radius): 89 """ 90 Return equivalent radius (ER) 91 """ 92 return radius 73 #def ER(radius): 74 # """ 75 # Return equivalent radius (ER) 76 # """ 77 # return radius 93 78 94 79 # VR defaults to 1.0 -
sasmodels/models/spherical_sld.c
r71b751d rd277229 10 10 } 11 11 return M_4PI_3*cube(r); 12 } 13 14 static double 15 effective_radius(int mode, double fp_n_shells, double thickness[], double interface[]) 16 { 17 int n_shells= (int)(fp_n_shells + 0.5); 18 double r = 0.0; 19 for (int i=0; i < n_shells; i++) { 20 r += thickness[i] + interface[i]; 21 } 22 return r; 12 23 } 13 24 -
sasmodels/models/spherical_sld.py
r71b751d rd277229 210 210 single = False # TODO: fix low q behaviour 211 211 have_Fq = True 212 effective_radius_type = ["outer radius"] 212 213 213 214 profile_axes = ['Radius (A)', 'SLD (1e-6/A^2)'] … … 255 256 256 257 257 def ER(n_shells, thickness, interface):258 """Effective radius"""259 n_shells = int(n_shells + 0.5)260 total = (np.sum(thickness[:n_shells], axis=1)261 + np.sum(interface[:n_shells], axis=1))262 return total258 #def ER(n_shells, thickness, interface): 259 # """Effective radius""" 260 # n_shells = int(n_shells + 0.5) 261 # total = (np.sum(thickness[:n_shells], axis=1) 262 # + np.sum(interface[:n_shells], axis=1)) 263 # return total 263 264 264 265 -
sasmodels/models/triaxial_ellipsoid.c
r71b751d rd277229 7 7 } 8 8 9 static double 10 radius_from_volume(double radius_equat_minor, double radius_equat_major, double radius_polar) 11 { 12 return cbrt(radius_equat_minor*radius_equat_major*radius_polar); 13 } 14 15 static double 16 radius_from_min_dimension(double radius_equat_minor, double radius_equat_major, double radius_polar) 17 { 18 const double rad_equat_min = (radius_equat_minor < radius_equat_major ? radius_equat_minor : radius_equat_major); 19 return (rad_equat_min < radius_polar ? rad_equat_min : radius_polar); 20 } 21 22 static double 23 radius_from_max_dimension(double radius_equat_minor, double radius_equat_major, double radius_polar) 24 { 25 const double rad_equat_max = (radius_equat_minor < radius_equat_major ? radius_equat_major : radius_equat_minor); 26 return (rad_equat_max > radius_polar ? rad_equat_max : radius_polar); 27 } 28 29 static double 30 effective_radius(int mode, double radius_equat_minor, double radius_equat_major, double radius_polar) 31 { 32 if (mode == 1) { 33 return radius_from_volume(radius_equat_minor,radius_equat_major, radius_polar); 34 } else if (mode == 2) { 35 return radius_from_min_dimension(radius_equat_minor,radius_equat_major, radius_polar); 36 } else { 37 return radius_from_max_dimension(radius_equat_minor,radius_equat_major, radius_polar); 38 } 39 } 9 40 10 41 static void -
sasmodels/models/triaxial_ellipsoid.py
r71b751d rd277229 158 158 source = ["lib/sas_3j1x_x.c", "lib/gauss76.c", "triaxial_ellipsoid.c"] 159 159 have_Fq = True 160 effective_radius_type = ["equivalent sphere","min radius", "max radius"] 160 161 161 162 def ER(radius_equat_minor, radius_equat_major, radius_polar): -
sasmodels/models/vesicle.c
r71b751d rd277229 6 6 } 7 7 8 static double 9 effective_radius(int mode, double radius, double thickness) 10 { 11 return radius + thickness; 12 } 8 13 9 14 static void -
sasmodels/models/vesicle.py
r71b751d rd277229 95 95 source = ["lib/sas_3j1x_x.c", "vesicle.c"] 96 96 have_Fq = True 97 effective_radius_type = ["outer radius"] 97 98 98 def ER(radius, thickness):99 '''100 returns the effective radius used in the S*P calculation101 102 :param radius: core radius103 :param thickness: shell thickness104 '''105 return radius + thickness99 #def ER(radius, thickness): 100 # ''' 101 # returns the effective radius used in the S*P calculation 102 # 103 # :param radius: core radius 104 # :param thickness: shell thickness 105 # ''' 106 # return radius + thickness 106 107 107 108 def VR(radius, thickness):
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