utest_nonshape.py @ 277aab4e

ESS_GUIESS_GUI_DocsESS_GUI_batch_fittingESS_GUI_bumps_abstractionESS_GUI_iss1116ESS_GUI_iss879ESS_GUI_iss959ESS_GUI_openclESS_GUI_orderingESS_GUI_sync_sascalccostrafo411magnetic_scattrelease-4.1.1release-4.1.2release-4.2.2release_4.0.1ticket-1009ticket-1094-headlessticket-1242-2d-resolutionticket-1243ticket-1249ticket885unittest-saveload

Last change on this file since 277aab4e was 8809e48, checked in by Mathieu Doucet <doucetm@…>, 16 years ago
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[914caf52]	1	"""
	2	Unit tests for non shape based model (Task 8.2.1)
	3	These tests are part of the requirements
	4	"""
	5
	6	import unittest, time, math
[f629e346]	7	from scipy.special import erf,gammaln
[914caf52]	8
	9	# Disable "missing docstring" complaint
	10	# pylint: disable-msg=C0111
	11	# Disable "too many methods" complaint
	12	# pylint: disable-msg=R0904
	13	# Disable "could be a function" complaint
	14	# pylint: disable-msg=R0201
	15
[829eee9]	16	import scipy
[914caf52]	17	class TestGuinier(unittest.TestCase):
	18	"""
	19	Unit tests for Guinier function
	20
	21	F(x) = exp[ [A] + [B]Q*2 ]
	22
	23	The model has two parameters: A and B
	24	"""
	25	def _func(self, a, b, x):
[f629e346]	26	return amath.exp(-(bx)**2/3.0)
[914caf52]	27
	28	def setUp(self):
[f629e346]	29	from sans.models.GuinierModel import GuinierModel
[914caf52]	30	self.model= GuinierModel()
	31
	32	def test1D(self):
[f629e346]	33	self.model.setParam('scale', 2.0)
	34	self.model.setParam('rg', 1.0)
[914caf52]	35
[f629e346]	36	self.assertEqual(self.model.run(0.0), 2.0)
	37	self.assertEqual(self.model.run(2.0), 2.0math.exp(-(1.02.0)**2/3.0))
[6b8399b]	38	self.assertEqual(self.model.runXY(2.0), 2.0math.exp(-(1.02.0)**2/3.0))
[914caf52]	39
	40	def test2D(self):
[f629e346]	41	self.model.setParam('scale', 2.0)
	42	self.model.setParam('rg', 1.0)
[914caf52]	43
[a55fac1]	44	#value = self._func(2.0, 1.0, 1.0)*self._func(2.0, 1.0, 2.0)
	45	value = self._func(2.0, 1.0, math.sqrt(5.0))
	46	#self.assertEqual(self.model.runXY([0.0,0.0]), 2.0*2.0)
	47	self.assertEqual(self.model.runXY([0.0,0.0]), 2.0)
[914caf52]	48	self.assertEqual(self.model.runXY([1.0,2.0]), value)
	49
	50	def test2Dphi(self):
[f629e346]	51	self.model.setParam('scale', 2.0)
	52	self.model.setParam('rg', 1.0)
[914caf52]	53
	54	x = 1.0
	55	y = 2.0
	56	r = math.sqrt(x2 + y2)
	57	phi = math.atan2(y, x)
	58
[a55fac1]	59	#value = self._func(2.0, 1.0, x)*self._func(2.0, 1.0, y)
	60	value = self._func(2.0, 1.0, r)
[914caf52]	61
[f03b027]	62	#self.assertEqual(self.model.run([r, phi]), value)
	63	self.assertAlmostEquals(self.model.run([r, phi]), value,1)
[829eee9]	64
	65
[914caf52]	66	class TestPorod(unittest.TestCase):
	67	"""
	68	Unit tests for Porod function
	69
[f629e346]	70	F(x) = C/Q**4
[914caf52]	71
	72	The model has one parameter: C
	73	"""
	74	def _func(self, c, x):
[f629e346]	75	return c/(x**4)
[914caf52]	76
	77	def setUp(self):
[f629e346]	78	from sans.models.PorodModel import PorodModel
[914caf52]	79	self.model= PorodModel()
[f629e346]	80	self.model.setParam('scale', 2.0)
[914caf52]	81
	82	def test1D(self):
	83	value = self._func(2.0, 3.0)
	84	self.assertEqual(self.model.run(3.0), value)
[6b8399b]	85	self.assertEqual(self.model.runXY(3.0), value)
[914caf52]	86
	87	def test2D(self):
[a55fac1]	88	#value = self._func(2.0, 1.0)*self._func(2.0, 2.0)
	89	value = self._func(2.0, math.sqrt(5.0))
[914caf52]	90	self.assertEqual(self.model.runXY([1.0,2.0]), value)
	91
	92	def test2Dphi(self):
	93	x = 1.0
	94	y = 2.0
	95	r = math.sqrt(x2 + y2)
	96	phi = math.atan2(y, x)
	97
[a55fac1]	98	#value = self._func(2.0, 1.0)*self._func(2.0, 2.0)
	99	value = self._func(2.0, r)
[829eee9]	100	self.assertAlmostEquals(self.model.run([r, phi]), value,1)
[914caf52]	101
[829eee9]	102	class TestDebye(unittest.TestCase):
	103	"""
	104	Unit tests for Debye function
	105
	106	F(x) = 2( exp(-x)+x -1 )/x**2
	107
	108	The model has three parameters:
	109	Rg = radius of gyration
	110	scale = scale factor
	111	bkd = Constant background
	112	"""
	113	def _func(self, Rg, scale, bkg, x):
	114	y = (Rg * x)**2
	115	return scale * (2(math.exp(-y) + y -1)/y*2) + bkg
	116
	117	def setUp(self):
[f629e346]	118	from sans.models.DebyeModel import DebyeModel
[829eee9]	119	self.model= DebyeModel()
	120	self.model.setParam('Rg', 50.0)
	121	self.model.setParam('scale',1.0)
[f629e346]	122	self.model.setParam('background',0.001)
[829eee9]	123
	124	def test1D(self):
	125	value = self._func(50.0, 1.0, 0.001, 2.0)
	126	self.assertEqual(self.model.run(2.0), value)
[6b8399b]	127	self.assertEqual(self.model.runXY(2.0), value)
[829eee9]	128
[f629e346]	129	# User enter zero as a value of x
	130	# An exceptio is raised
	131	self.assertRaises(ZeroDivisionError, self.model.run, 0.0)
[829eee9]	132
[8809e48]	133	def test1D_clone(self):
	134	value = self._func(50.0, 1.0, 10.0, 2.0)
	135	self.model.setParam('background', 10.0)
	136	clone = self.model.clone()
	137	self.assertEqual(clone.run(2.0), value)
	138	self.assertEqual(clone.runXY(2.0), value)
	139
	140	# User enter zero as a value of x
	141	# An exceptio is raised
	142	self.assertRaises(ZeroDivisionError, clone.run, 0.0)
	143
[829eee9]	144	def test2D(self):
[a55fac1]	145	#value = self._func(50.0, 1.0, 0.001, 1.0)*self._func(50.0, 1.0, 0.001, 2.0)
	146	value = self._func(50.0, 1.0, 0.001, math.sqrt(5.0))
[829eee9]	147	self.assertEqual(self.model.runXY([1.0,2.0]), value)
	148
	149	def test2Dphi(self):
	150	x = 1.0
	151	y = 2.0
	152	r = math.sqrt(x2 + y2)
	153	phi = math.atan2(y, x)
	154
	155	value = self._func(50.0, 1.0, 0.001, 1.0)*self._func(50.0, 1.0, 0.001, 2.0)
	156	self.assertAlmostEquals(self.model.run([r, phi]), value,1)
	157
	158
	159	class TestLorentz(unittest.TestCase):
	160	"""
	161	Unit tests for Lorentz function
	162
	163	F(x) = scale/( 1 + (x*L)^2 ) + bkd
	164
	165	The model has three parameters:
	166	L = screen Length
	167	scale = scale factor
	168	bkd = incoherent background
	169	"""
[f629e346]	170	def _func(self, I0 , L, bgd, qval):
	171	return I0/(1.0 + (qvalL)(qval*L)) + bgd
	172
[829eee9]	173	def setUp(self):
[f629e346]	174	from sans.models.LorentzModel import LorentzModel
[829eee9]	175	self.model= LorentzModel()
	176
	177	def test1D(self):
	178	self.model.setParam('scale', 100.0)
[f629e346]	179	self.model.setParam('Length', 50.0)
	180	self.model.setParam('background', 1.0)
[829eee9]	181
	182	self.assertEqual(self.model.run(0.0), 101.0)
	183	self.assertEqual(self.model.run(2.0), self._func(100.0, 50.0, 1.0, 2.0))
[6b8399b]	184	self.assertEqual(self.model.runXY(2.0), self._func(100.0, 50.0, 1.0, 2.0))
[829eee9]	185
	186	def test2D(self):
	187	self.model.setParam('scale', 100.0)
[f629e346]	188	self.model.setParam('Length', 50.0)
	189	self.model.setParam('background', 1.0)
[829eee9]	190
[a55fac1]	191	#value = self._func(100.0, 50.0, 1.0, 1.0)*self._func(100.0, 50.0, 1.0, 2.0)
	192	value = self._func(100.0, 50.0, 1.0, math.sqrt(5.0))
[829eee9]	193	self.assertEqual(self.model.runXY([1.0,2.0]), value)
	194
	195	def test2Dphi(self):
	196	self.model.setParam('scale', 100.0)
[f629e346]	197	self.model.setParam('Length', 50.0)
	198	self.model.setParam('background', 1.0)
[829eee9]	199
	200	x = 1.0
	201	y = 2.0
	202	r = math.sqrt(x2 + y2)
	203	phi = math.atan2(y, x)
	204
	205	value = self._func(100.0, 50.0, 1.0, x)*self._func(100.0, 50.0, 1.0, y)
	206	self.assertAlmostEquals(self.model.run([r, phi]), value,1)
	207
	208	class TestDAB(unittest.TestCase):
	209	"""
	210	Unit tests for DAB function
	211
	212	F(x) = scale/( 1 + (x*L)^2 )^(2) + bkd
	213
	214	The model has three parameters:
	215	L = Correlation Length
	216	scale = scale factor
	217	bkd = incoherent background
	218	"""
[f629e346]	219	def _func(self, Izero, range, incoh, qval):
	220	return Izero/pow((1.0 + (qvalrange)(qval*range)),2) + incoh
[829eee9]	221
	222	def setUp(self):
[f629e346]	223	from sans.models.DABModel import DABModel
[829eee9]	224	self.model= DABModel()
[6b8399b]	225	self.scale = 10.0
	226	self.length = 40.0
	227	self.back = 1.0
	228
	229	self.model.setParam('scale', self.scale)
	230	self.model.setParam('Length', self.length)
	231	self.model.setParam('background', self.back)
[829eee9]	232
	233	def test1D(self):
	234
[6b8399b]	235	self.assertEqual(self.model.run(0.0), self.scale+self.back)
	236	self.assertEqual(self.model.run(2.0), self._func(self.scale, self.length, self.back, 2.0))
	237	self.assertEqual(self.model.runXY(2.0), self._func(self.scale, self.length, self.back, 2.0))
[829eee9]	238
	239	def test2D(self):
[a55fac1]	240	#value = self._func(self.scale, self.length, self.back, 1.0)*self._func(self.scale, self.length, self.back, 2.0)
	241	value = self._func(self.scale, self.length, self.back, math.sqrt(5.0))
[829eee9]	242	self.assertEqual(self.model.runXY([1.0,2.0]), value)
	243
	244	def test2Dphi(self):
	245	x = 1.0
	246	y = 2.0
	247	r = math.sqrt(x2 + y2)
	248	phi = math.atan2(y, x)
	249
[6b8399b]	250	value = self._func(self.scale, self.length, self.back, x)*self._func(self.scale, self.length, self.back, y)
[f03b027]	251	self.assertAlmostEquals(self.model.run([r, phi]), value,1)
[914caf52]	252
[829eee9]	253	class TestPowerLaw(unittest.TestCase):
	254	"""
	255	Unit tests for PowerLaw function
	256
	257	F(x) = scale* (x)^(m) + bkd
	258
	259	The model has three parameters:
	260	m = power
	261	scale = scale factor
	262	bkd = incoherent background
	263	"""
[f629e346]	264	def _func(self, a, m, bgd, qval):
	265	return a*math.pow(qval,-m) + bgd
	266
[829eee9]	267
	268	def setUp(self):
[f629e346]	269	from sans.models.PowerLawModel import PowerLawModel
[829eee9]	270	self.model= PowerLawModel()
	271
	272	def test1D(self):
	273	self.model.setParam('scale', math.exp(-6))
	274	self.model.setParam('m', 4.0)
[f629e346]	275	self.model.setParam('background', 1.0)
[829eee9]	276
[f629e346]	277	#self.assertEqual(self.model.run(0.0), 1.0)
[829eee9]	278	self.assertEqual(self.model.run(2.0), self._func(math.exp(-6), 4.0, 1.0, 2.0))
[6b8399b]	279	self.assertEqual(self.model.runXY(2.0), self._func(math.exp(-6), 4.0, 1.0, 2.0))
[f629e346]	280
	281	def testlimit(self):
	282	self.model.setParam('scale', math.exp(-6))
	283	self.model.setParam('m', -4.0)
	284	self.model.setParam('background', 1.0)
	285
	286	self.assertEqual(self.model.run(0.0), 1.0)
[829eee9]	287
	288	def test2D(self):
	289	self.model.setParam('scale', math.exp(-6))
	290	self.model.setParam('m', 4.0)
[f629e346]	291	self.model.setParam('background', 1.0)
[829eee9]	292
[a55fac1]	293	#value = self._func(math.exp(-6), 4.0, 1.0, 1.0)\
	294	#*self._func(math.exp(-6), 4.0, 1.0, 2.0)
	295	value = self._func(math.exp(-6), 4.0, 1.0, math.sqrt(5.0))
[829eee9]	296
	297	self.assertEqual(self.model.runXY([1.0,2.0]), value)
	298
	299	def test2Dphi(self):
	300	self.model.setParam('scale', math.exp(-6))
	301	self.model.setParam('m', 4.0)
[f629e346]	302	self.model.setParam('background', 1.0)
[829eee9]	303
	304	x = 1.0
	305	y = 2.0
	306	r = math.sqrt(x2 + y2)
	307	phi = math.atan2(y, x)
	308
	309	value = self._func(math.exp(-6), 4.0, 1.0, x)\
	310	*self._func(math.exp(-6), 4.0, 1.0, y)
	311	self.assertAlmostEquals(self.model.run([r, phi]), value,1)
	312
	313	class TestTeubnerStrey(unittest.TestCase):
	314	"""
	315	Unit tests for PowerLaw function
	316
	317	F(x) = 1/( scale + c1(x)^(2)+ c2(x)^(4)) + bkd
	318
	319	The model has Four parameters:
	320	scale = scale factor
	321	c1 = constant
	322	c2 = constant
	323	bkd = incoherent background
	324	"""
[f629e346]	325	def _func(self, scale, c1, c2, bck, q):
	326
	327	q2 = q*q;
	328	q4 = q2*q2;
	329
	330	return 1.0/(scale + c1q2+c2q4) + bck
[829eee9]	331
	332	def setUp(self):
[f629e346]	333	from sans.models.TeubnerStreyModel import TeubnerStreyModel
[829eee9]	334	self.model= TeubnerStreyModel()
	335
	336	def test1D(self):
	337
	338	self.model.setParam('c1', -30.0)
	339	self.model.setParam('c2', 5000.0)
	340	self.model.setParam('scale', 0.1)
[f629e346]	341	self.model.setParam('background', 0.1)
[829eee9]	342	#self.assertEqual(1/(math.sqrt(4)), math.pow(4,-1/2))
[f629e346]	343	#self.assertEqual(self.model.TeubnerStreyLengths(),False )
[829eee9]	344
	345	self.assertEqual(self.model.run(0.0), 10.1)
	346	self.assertEqual(self.model.run(2.0), self._func(0.1,-30.0,5000.0,0.1,2.0))
[6b8399b]	347	self.assertEqual(self.model.runXY(2.0), self._func(0.1,-30.0,5000.0,0.1,2.0))
[829eee9]	348
	349	def test2D(self):
	350	self.model.setParam('c1', -30.0)
	351	self.model.setParam('c2', 5000.0)
	352	self.model.setParam('scale', 0.1)
[f629e346]	353	self.model.setParam('background', 0.1)
[a55fac1]	354	#value = self._func(0.1,-30.0,5000.0,0.1, 1.0)\
	355	#*self._func(0.1,-30.0,5000.0,0.1, 2.0)
	356	value = self._func(0.1,-30.0,5000.0,0.1, math.sqrt(5.0))
[829eee9]	357
	358	self.assertEqual(self.model.runXY([1.0,2.0]), value)
	359
	360	def test2Dphi(self):
	361	self.model.setParam('c1', -30.0)
	362	self.model.setParam('c2', 5000.0)
	363	self.model.setParam('scale', 0.1)
[f629e346]	364	self.model.setParam('background', 0.1)
[829eee9]	365
	366	x = 1.0
	367	y = 2.0
	368	r = math.sqrt(x2 + y2)
	369	phi = math.atan2(y, x)
	370
[a55fac1]	371	#value = self._func(0.1,-30.0,5000.0,0.1, x)\
	372	#*self._func(0.1,-30.0,5000.0,0.1, y)
	373	value = self._func(0.1,-30.0,5000.0,0.1, r)
[829eee9]	374	self.assertAlmostEquals(self.model.run([r, phi]), value,1)
	375
	376	class TestBEPolyelectrolyte(unittest.TestCase):
	377	"""
	378	Unit tests for BEPolyelectrolyte function
	379
	380	F(x) = K1/(4pi()Lb(alpha)^(2)(q^(2)+k2)/(1+(r02)^(2))(q^(2)+k2)\
	381	(q^(2)-(12h*C/b^(2)))
	382
	383	The model has Eight parameters:
	384	K = Constrast factor of the polymer
	385	Lb = Bjerrum length
	386	H = virial parameter
	387	B = monomer length
	388	Cs = Concentration of monovalent salt
	389	alpha = ionazation degree
	390	C = polymer molar concentration
	391	bkd = background
	392	"""
	393	def _func(self, K, Lb, H, B, Cs, alpha, C, bkd, r02, k2, x):
	394	return (K /( (4math.pi Lb(alpha2)(x*2 +k2)) ( (1 +(r02**2)) \
	395	((x2) + k2)((x*2) -(12 H * C/(B**2))) )))+ bkd
	396
	397	def setUp(self):
[f629e346]	398	from sans.models.BEPolyelectrolyte import BEPolyelectrolyte
[829eee9]	399	self.model= BEPolyelectrolyte()
	400
[f629e346]	401	self.K = 10.0
	402	self.Lb = 6.5
	403	self.h = 11
	404	self.b = 13
	405	self.Cs = 0.1
	406	self.alpha = 0.05
	407	self.C = .7
	408	self.Bkd =0.01
	409
	410	self.model.setParam('K', self.K)
	411	self.model.setParam('Lb', self.Lb)
	412	self.model.setParam('H', self.h)
	413	self.model.setParam('B', self.b)
	414	self.model.setParam('Cs',self.Cs)
	415	self.model.setParam('alpha', self.alpha)
	416	self.model.setParam('C', self.C)
	417	self.model.setParam('background', self.Bkd)
	418
	419	def _func(self, q):
	420
	421	Ca = self.C *6.022136e-4
	422	Csa = self.Cs * 6.022136e-4
	423	k2= 4math.piself.Lb(2self.Cs+self.alpha*Ca)
	424
	425	r02 = 1./self.alpha / Ca*0.5( self.b / (48math.piself.Lb)**0.5 )
	426	q2 = q**2
	427	Sq = self.K1./(4math.piself.Lbself.alpha*2) (q2 + k2) / (1+(r02*2) (q2+k2) * (q2- (12self.hCa/self.b**2)) ) + self.Bkd
	428	return Sq
	429
[829eee9]	430	def test1D(self):
	431
[f629e346]	432
	433	q = 0.001
	434
	435	self.assertEqual(self.model.run(q), self._func(q))
[6b8399b]	436	self.assertEqual(self.model.runXY(q), self._func(q))
[f629e346]	437
[829eee9]	438	def test2D(self):
[a55fac1]	439	#self.assertAlmostEquals(self.model.runXY([1.0,2.0]), self._func(1.0)*self._func(2.0), 8)
	440	self.assertAlmostEquals(self.model.runXY([1.0,2.0]), self._func(math.sqrt(1.0+2.0**2)), 8)
[829eee9]	441
	442	def test2Dphi(self):
[f629e346]	443
[829eee9]	444	x = 1.0
	445	y = 2.0
	446	r = math.sqrt(x2 + y2)
	447	phi = math.atan2(y, x)
	448
[a55fac1]	449	self.assertAlmostEquals(self.model.run([r, phi]), self._func(r), 8)
[829eee9]	450
	451	class TestFractalModel(unittest.TestCase):
	452	"""
	453	Unit tests for Number Density Fractal function
	454	F(x)= P(x)*S(x) + bkd
	455	The model has Seven parameters:
	456	scale = Volume fraction
	457	Radius = Block radius
	458	Fdim = Fractal dimension
	459	L = correlation Length
	460	SDLB = SDL block
	461	SDLS = SDL solvent
	462	bkd = background
	463	"""
	464	def setUp(self):
[f629e346]	465	from sans.models.FractalModel import FractalModel
[829eee9]	466	self.model= FractalModel()
[6b8399b]	467	self.r0 = 5.0
	468	self.sldp = 2.0e-6
	469	self.sldm = 6.35e-6
	470	self.phi = 0.05
	471	self.Df = 2
	472	self.corr = 100.0
	473	self.bck = 1.0
	474
	475	self.model.setParam('scale', self.phi)
	476	self.model.setParam('Radius', self.r0)
	477	self.model.setParam('fractal_dim',self.Df)
	478	self.model.setParam('corr_length', self.corr)
	479	self.model.setParam('block_sld', self.sldp)
	480	self.model.setParam('solvent_sld', self.sldm)
	481	self.model.setParam('background', self.bck)
	482
	483	def _func(self, x):
	484	r0 = self.r0
	485	sldp = self.sldp
	486	sldm = self.sldm
	487	phi = self.phi
	488	Df = self.Df
	489	corr = self.corr
	490	bck = self.bck
[f629e346]	491
	492	pq = 1.0e8phi4.0/3.0math.pir0r0r0(sldp-sldm)(sldp-sldm)math.pow((3(math.sin(xr0) - xr0math.cos(xr0))/math.pow((x*r0),3)),2);
	493
	494	sq = Dfmath.exp(gammaln(Df-1.0))math.sin((Df-1.0)math.atan(xcorr));
	495	sq /= math.pow((xr0),Df) math.pow((1.0 + 1.0/(xcorr)/(xcorr)),((Df-1.0)/2.0));
	496	sq += 1.0;
[829eee9]	497
[6b8399b]	498	self.assertAlmostEqual(self.model._scatterRanDom(x), pq, 8 )
[f629e346]	499	self.assertEqual(self.model._Block(x),sq )
[829eee9]	500
[6b8399b]	501	return sq*pq+bck
	502
	503	def test1D(self):
	504	x = 0.001
	505
	506	iq = self._func(x)
	507	self.assertEqual(self.model.run(x), iq)
	508	self.assertEqual(self.model.runXY(x), iq)
	509
	510	def test2D(self):
	511	x = 1.0
	512	y = 2.0
	513	r = math.sqrt(x2 + y2)
	514	phi = math.atan2(y, x)
	515	iq_x = self._func(x)
	516	iq_y = self._func(y)
	517
[a55fac1]	518	#self.assertEqual(self.model.run([r, phi]), iq_x*iq_y)
	519	self.assertEqual(self.model.run([r, phi]), self.model.run(r))
	520	#self.assertEqual(self.model.runXY([x,y]), iq_x*iq_y)
	521	self.assertEqual(self.model.runXY([x,y]), self.model.run(r))
[829eee9]	522
[914caf52]	523	if __name__ == '__main__':
	524	unittest.main()

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SasView

source: sasview/sansmodels/src/sans/models/test/utest_nonshape.py @ 277aab4e

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