fit.py @ f4b36fa

core_shell_microgelscostrafo411magnetic_modelticket-1257-vesicle-productticket_1156ticket_1265_superballticket_822_more_unit_tests

Last change on this file since f4b36fa was f4b36fa, checked in by Paul Kienzle <pkienzle@…>, 7 years ago
adjust bumps fitting example for changes in sasmodels
Property mode set to `100644`
File size: 6.3 KB

Rev	Line
[5378e40]	1	#!/usr/bin/env python
	2	# -- coding: utf-8 --
	3
[87985ca]	4	import sys
[5378e40]	5	from bumps.names import *
[346bc88]	6	from sasmodels.core import load_model
[7cf2cfd]	7	from sasmodels.bumps_model import Model, Experiment
	8	from sasmodels.data import load_data, set_beam_stop, set_top
[d772f5d]	9
	10	""" IMPORT THE DATA USED """
[7cf2cfd]	11	radial_data = load_data('DEC07267.DAT')
	12	set_beam_stop(radial_data, 0.00669, outer=0.025)
	13	set_top(radial_data, -.0185)
[87985ca]	14
[7cf2cfd]	15	tan_data = load_data('DEC07266.DAT')
	16	set_beam_stop(tan_data, 0.00669, outer=0.025)
	17	set_top(tan_data, -.0185)
[87985ca]	18	#sas.set_half(tan_data, 'right')
	19
	20	name = "ellipsoid" if len(sys.argv) < 2 else sys.argv[1]
	21	section = "radial" if len(sys.argv) < 3 else sys.argv[2]
[5d3d7b4]	22	if section not in ("radial","tangential","both"):
	23	raise ValueError("section %r should be 'radial', 'tangential' or 'both'"
	24	% section)
	25	data = radial_data if section != "tangential" else tan_data
[f4b36fa]	26	theta = 89.9 if section != "tangential" else 0
	27	phi = 90
[346bc88]	28	kernel = load_model(name, dtype="single")
[abb22f4]	29	cutoff = 1e-3
[87985ca]	30
	31	if name == "ellipsoid":
[7cf2cfd]	32	model = Model(kernel,
[f4b36fa]	33	scale=0.08, background=35,
	34	radius_polar=15, radius_equatorial=800,
[1182da5]	35	sld=.291, sld_solvent=7.105,
[f4b36fa]	36	theta=theta, phi=phi,
	37	theta_pd=0, theta_pd_n=0, theta_pd_nsigma=3,
[346bc88]	38	phi_pd=0, phi_pd_n=20, phi_pd_nsigma=3,
[f4b36fa]	39	radius_polar_pd=0.222296, radius_polar_pd_n=1, radius_polar_pd_nsigma=0,
	40	radius_equatorial_pd=.000128, radius_equatorial_pd_n=1, radius_equatorial_pd_nsigma=0,
[346bc88]	41	)
[8cdb9f1]	42
	43	# SET THE FITTING PARAMETERS
[f4b36fa]	44	model.radius_polar.range(15, 1000)
	45	model.radius_equatorial.range(15, 1000)
	46	#model.theta.range(0, 90)
	47	#model.theta_pd.range(0,10)
	48	model.phi_pd.range(0,20)
	49	model.phi.range(0, 180)
[346bc88]	50	model.background.range(0,1000)
[abb22f4]	51	model.scale.range(0, 10)
[8cdb9f1]	52
	53
[87985ca]	54	elif name == "lamellar":
[7cf2cfd]	55	model = Model(kernel,
[f4b36fa]	56	scale=0.08, background=0.003,
[346bc88]	57	thickness=19.2946,
	58	sld=5.38,sld_sol=7.105,
	59	thickness_pd= 0.37765, thickness_pd_n=10, thickness_pd_nsigma=3,
	60	)
	61
[8cdb9f1]	62	# SET THE FITTING PARAMETERS
[87985ca]	63	#model.thickness.range(0, 1000)
[8cdb9f1]	64	#model.scale.range(0, 1)
[87985ca]	65	#model.thickness_pd.range(0, 1000)
[8cdb9f1]	66	#model.background.range(0, 1000)
[87985ca]	67	model.sld.range(0, 1)
[8cdb9f1]	68
	69
[87985ca]	70	elif name == "cylinder":
[1726b21]	71	"""
	72	pars = dict(scale=0.0023, radius=92.5, length=798.3,
[87985ca]	73	sld=.29, solvent_sld=7.105, background=5,
[5d3d7b4]	74	theta=0, phi=phi,
[87985ca]	75	theta_pd=22.11, theta_pd_n=5, theta_pd_nsigma=3,
[1726b21]	76	radius_pd=.0084, radius_pd_n=10, radius_pd_nsigma=3,
	77	length_pd=0.493, length_pd_n=10, length_pd_nsigma=3,
[f4b36fa]	78	phi_pd=0, phi_pd_n=5 phi_pd_nsigma=3,)
[1726b21]	79	"""
	80	pars = dict(
[abb22f4]	81	scale=.01, background=35,
[1182da5]	82	sld=.291, sld_solvent=5.77,
[f4b36fa]	83	radius=250, length=178,
[abb22f4]	84	radius_pd=0.1, radius_pd_n=5, radius_pd_nsigma=3,
[1726b21]	85	length_pd=0.1,length_pd_n=5, length_pd_nsigma=3,
[f4b36fa]	86	theta=theta, phi=phi,
	87	theta_pd=0, theta_pd_n=0, theta_pd_nsigma=3,
	88	phi_pd=10, phi_pd_n=20, phi_pd_nsigma=3)
[7cf2cfd]	89	model = Model(kernel, **pars)
[a42fec0]	90
	91	# SET THE FITTING PARAMETERS
[1726b21]	92	model.radius.range(1, 500)
[4001d6e]	93	model.length.range(1, 5000)
[f4b36fa]	94	#model.theta.range(0, 90)
	95	model.phi.range(0, 180)
	96	model.phi_pd.range(0, 30)
[abb22f4]	97	model.radius_pd.range(0, 1)
[f4b36fa]	98	model.length_pd.range(0, 1)
[abb22f4]	99	model.scale.range(0, 10)
	100	model.background.range(0, 100)
[a42fec0]	101
	102
[87985ca]	103	elif name == "core_shell_cylinder":
[7cf2cfd]	104	model = Model(kernel,
[f4b36fa]	105	scale= .031, background=0,
	106	radius=19.5, thickness=30, length=22,
	107	sld_core=7.105, sld_shell=.291, sld_solvent=7.105,
[346bc88]	108	radius_pd=0.26, radius_pd_n=10, radius_pd_nsigma=3,
	109	length_pd=0.26, length_pd_n=10, length_pd_nsigma=3,
	110	thickness_pd=1, thickness_pd_n=1, thickness_pd_nsigma=1,
[f4b36fa]	111	theta=theta, phi=phi,
	112	theta_pd=1, theta_pd_n=1, theta_pd_nsigma=3,
	113	phi_pd=0, phi_pd_n=20, phi_pd_nsigma=3,
[346bc88]	114	)
[a42fec0]	115
	116	# SET THE FITTING PARAMETERS
[f4b36fa]	117	model.radius.range(115, 1000)
	118	model.length.range(0, 2500)
[a42fec0]	119	#model.thickness.range(18, 38)
	120	#model.thickness_pd.range(0, 1)
[87985ca]	121	#model.phi.range(0, 90)
[f4b36fa]	122	model.phi_pd.range(0,20)
[a42fec0]	123	#model.radius_pd.range(0, 1)
	124	#model.length_pd.range(0, 1)
[87985ca]	125	#model.theta_pd.range(0, 360)
[a42fec0]	126	#model.background.range(0,5)
	127	model.scale.range(0, 1)
[09e15be]	128
[8faffcd]	129
[ca6c007]	130
[87985ca]	131	elif name == "capped_cylinder":
[7cf2cfd]	132	model = Model(kernel,
[f4b36fa]	133	scale=.08, background=35,
	134	radius=20, cap_radius=40, length=400,
[1182da5]	135	sld=1, sld_solvent=6.3,
[346bc88]	136	radius_pd=.1, radius_pd_n=5, radius_pd_nsigma=3,
	137	cap_radius_pd=.1, cap_radius_pd_n=5, cap_radius_pd_nsigma=3,
	138	length_pd=.1, length_pd_n=1, length_pd_nsigma=0,
[f4b36fa]	139	theta=theta, phi=phi,
	140	theta_pd=0, theta_pd_n=1, theta_pd_nsigma=0,
	141	phi_pd=10, phi_pd_n=20, phi_pd_nsigma=0,
[346bc88]	142	)
[8cdb9f1]	143
[f4b36fa]	144	model.radius.range(115, 1000)
	145	model.length.range(0, 2500)
	146	#model.thickness.range(18, 38)
	147	#model.thickness_pd.range(0, 1)
	148	#model.phi.range(0, 90)
	149	model.phi_pd.range(0,20)
	150	#model.radius_pd.range(0, 1)
	151	#model.length_pd.range(0, 1)
	152	#model.theta_pd.range(0, 360)
	153	#model.background.range(0,5)
[8cdb9f1]	154	model.scale.range(0, 1)
	155
	156
[87985ca]	157	elif name == "triaxial_ellipsoid":
[7cf2cfd]	158	model = Model(kernel,
[f4b36fa]	159	scale=0.08, background=35,
	160	radius_equat_minor=15, radius_equat_major=20, radius_polar=500,
[1182da5]	161	sld=7.105, solvent_sld=.291,
[f4b36fa]	162	radius_equat_minor_pd=.1, radius_equat_minor_pd_n=1, radius_equat_minor_pd_nsigma=0,
	163	radius_equat_major_pd=.1, radius_equat_major_pd_n=1, radius_equat_major_pd_nsigma=0,
	164	radius_polar_pd=.1, radius_polar_pd_n=1, radius_polar_pd_nsigma=0,
	165	theta=theta, phi=phi, psi=0,
[346bc88]	166	theta_pd=20, theta_pd_n=40, theta_pd_nsigma=3,
	167	phi_pd=.1, phi_pd_n=1, phi_pd_nsigma=0,
	168	psi_pd=30, psi_pd_n=1, psi_pd_nsigma=0,
	169	)
[8cdb9f1]	170
	171	# SET THE FITTING PARAMETERS
[f4b36fa]	172	model.radius_equat_minor.range(15, 1000)
	173	model.radius_equat_major.range(15, 1000)
	174	#model.radius_polar.range(15, 1000)
[8cdb9f1]	175	#model.background.range(0,1000)
	176	#model.theta_pd.range(0, 360)
	177	#model.phi_pd.range(0, 360)
	178	#model.psi_pd.range(0, 360)
	179
[87985ca]	180	else:
	181	print "No parameters for %s"%name
	182	sys.exit(1)
[8cdb9f1]	183
[abb22f4]	184	model.cutoff = cutoff
[7cf2cfd]	185	M = Experiment(data=data, model=model)
[5d3d7b4]	186	if section == "both":
[f4b36fa]	187	tan_model = Model(model.sasmodel, **model.parameters())
[87985ca]	188	tan_model.phi = model.phi - 90
[5d3d7b4]	189	tan_model.cutoff = cutoff
[7cf2cfd]	190	tan_M = Experiment(data=tan_data, model=tan_model)
[346bc88]	191	problem = FitProblem([M, tan_M])
[87985ca]	192	else:
[346bc88]	193	problem = FitProblem(M)

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source: sasmodels/example/fit.py @ f4b36fa

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