[ca6d914] | 1 | """ |
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| 2 | Unit tests for fitting module |
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[2eaaf1a] | 3 | @author Gervaise Alina |
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[ca6d914] | 4 | """ |
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| 5 | import unittest |
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[2eaaf1a] | 6 | |
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[1e3169c] | 7 | from sans.fit.AbstractFitEngine import Model |
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[ca6d914] | 8 | import math |
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| 9 | class testFitModule(unittest.TestCase): |
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| 10 | """ test fitting """ |
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[2eaaf1a] | 11 | |
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[ca6d914] | 12 | def test1(self): |
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[8bbab51] | 13 | """ Fit 1 data (testdata_line.txt)and 1 model(lineModel) """ |
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[ca6d914] | 14 | #load data |
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[1374174f] | 15 | from DataLoader.loader import Loader |
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[1e3169c] | 16 | data = Loader().load("testdata_line.txt") |
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[ca6d914] | 17 | #Importing the Fit module |
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| 18 | from sans.fit.Fitting import Fit |
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| 19 | fitter = Fit('scipy') |
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| 20 | # Receives the type of model for the fitting |
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[52ac10b] | 21 | from sans.models.LineModel import LineModel |
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[ca6d914] | 22 | model1 = LineModel() |
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| 23 | model1.name = "M1" |
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| 24 | model = Model(model1) |
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| 25 | #fit with scipy test |
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| 26 | |
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| 27 | pars1= ['param1','param2'] |
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| 28 | fitter.set_data(data,1) |
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| 29 | try:fitter.set_model(model,1,pars1) |
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| 30 | except ValueError,msg: |
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[fd6b789] | 31 | print "ValueError was raised: "+str(msg) |
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| 32 | #assert str(msg)=="wrong paramter %s used to set model %s. Choose\ |
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| 33 | # parameter name within %s"%('param1', model.model.name,str(model.model.getParamList())) |
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[ca6d914] | 34 | else: raise AssertError,"No error raised for scipy fitting with wrong parameters name to fit" |
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| 35 | pars1= ['A','B'] |
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| 36 | fitter.set_model(model,1,pars1) |
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[8bbab51] | 37 | fitter.select_problem_for_fit(Uid=1,value=1) |
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[ca6d914] | 38 | result1 = fitter.fit() |
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| 39 | self.assert_(result1) |
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| 40 | |
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[2eaaf1a] | 41 | self.assertTrue( math.fabs(result1.pvec[0]-4)/3 <= result1.stderr[0] ) |
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| 42 | self.assertTrue( math.fabs(result1.pvec[1]-2.5)/3 <= result1.stderr[1]) |
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| 43 | self.assertTrue( result1.fitness/len(data.x) < 2 ) |
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[ca6d914] | 44 | |
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| 45 | #fit with park test |
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| 46 | fitter = Fit('park') |
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| 47 | fitter.set_data(data,1) |
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| 48 | fitter.set_model(model,1,pars1) |
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[8bbab51] | 49 | fitter.select_problem_for_fit(Uid=1,value=1) |
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[ca6d914] | 50 | result2 = fitter.fit() |
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| 51 | |
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| 52 | self.assert_(result2) |
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[2eaaf1a] | 53 | self.assertTrue( math.fabs(result2.pvec[0]-4)/3 <= result2.stderr[0] ) |
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| 54 | self.assertTrue( math.fabs(result2.pvec[1]-2.5)/3 <= result2.stderr[1] ) |
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| 55 | self.assertTrue( result2.fitness/len(data.x) < 2) |
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[ca6d914] | 56 | # compare fit result result for scipy and park |
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| 57 | self.assertAlmostEquals( result1.pvec[0], result2.pvec[0] ) |
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| 58 | self.assertAlmostEquals( result1.pvec[1],result2.pvec[1] ) |
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| 59 | self.assertAlmostEquals( result1.stderr[0],result2.stderr[0] ) |
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| 60 | self.assertAlmostEquals( result1.stderr[1],result2.stderr[1] ) |
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[2eaaf1a] | 61 | self.assertAlmostEquals( result1.fitness, |
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| 62 | result2.fitness/len(data.x),1 ) |
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| 63 | |
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[ca6d914] | 64 | |
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| 65 | def test2(self): |
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| 66 | """ fit 2 data and 2 model with no constrainst""" |
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| 67 | #load data |
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| 68 | from DataLoader.loader import Loader |
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| 69 | l = Loader() |
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[1e3169c] | 70 | data1=l.load("testdata_line.txt") |
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| 71 | |
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| 72 | data2=l.load("testdata_line1.txt") |
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| 73 | |
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[ca6d914] | 74 | #Importing the Fit module |
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| 75 | from sans.fit.Fitting import Fit |
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| 76 | fitter = Fit('scipy') |
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| 77 | # Receives the type of model for the fitting |
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[52ac10b] | 78 | from sans.models.LineModel import LineModel |
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[ca6d914] | 79 | model11 = LineModel() |
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| 80 | model11.name= "M1" |
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| 81 | model22 = LineModel() |
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| 82 | model11.name= "M2" |
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[1e3169c] | 83 | |
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[ca6d914] | 84 | model1 = Model(model11) |
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| 85 | model2 = Model(model22) |
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| 86 | #fit with scipy test |
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| 87 | pars1= ['A','B'] |
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| 88 | fitter.set_data(data1,1) |
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| 89 | fitter.set_model(model1,1,pars1) |
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[8bbab51] | 90 | fitter.select_problem_for_fit(Uid=1,value=0) |
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[ca6d914] | 91 | fitter.set_data(data2,2) |
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| 92 | fitter.set_model(model2,2,pars1) |
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[8bbab51] | 93 | fitter.select_problem_for_fit(Uid=2,value=0) |
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| 94 | |
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| 95 | try: result1 = fitter.fit() |
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| 96 | except RuntimeError,msg: |
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| 97 | assert str(msg)=="No Assembly scheduled for Scipy fitting." |
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| 98 | else: raise AssertError,"No error raised for scipy fitting with no model" |
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| 99 | fitter.select_problem_for_fit(Uid=1,value=1) |
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| 100 | fitter.select_problem_for_fit(Uid=2,value=1) |
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[ca6d914] | 101 | try: result1 = fitter.fit() |
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| 102 | except RuntimeError,msg: |
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| 103 | assert str(msg)=="Scipy can't fit more than a single fit problem at a time." |
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| 104 | else: raise AssertError,"No error raised for scipy fitting with more than 2 models" |
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| 105 | |
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| 106 | #fit with park test |
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| 107 | fitter = Fit('park') |
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| 108 | fitter.set_data(data1,1) |
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| 109 | fitter.set_model(model1,1,pars1) |
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| 110 | fitter.set_data(data2,2) |
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| 111 | fitter.set_model(model2,2,pars1) |
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[8bbab51] | 112 | fitter.select_problem_for_fit(Uid=1,value=1) |
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| 113 | fitter.select_problem_for_fit(Uid=2,value=1) |
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[ca6d914] | 114 | result2 = fitter.fit() |
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| 115 | |
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| 116 | self.assert_(result2) |
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[2eaaf1a] | 117 | self.assertTrue( math.fabs(result2.pvec[0]-4)/3 <= result2.stderr[0] ) |
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| 118 | self.assertTrue( math.fabs(result2.pvec[1]-2.5)/3 <= result2.stderr[1] ) |
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[1e3169c] | 119 | self.assertTrue( result2.fitness/(len(data1.x)+len(data2.x)) < 2) |
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[ca6d914] | 120 | |
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| 121 | |
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| 122 | def test3(self): |
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| 123 | """ fit 2 data and 2 model with 1 constrainst""" |
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| 124 | #load data |
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| 125 | from DataLoader.loader import Loader |
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| 126 | l = Loader() |
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[1e3169c] | 127 | data1= l.load("testdata_line.txt") |
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| 128 | data2= l.load("testdata_cst.txt") |
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| 129 | |
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[ca6d914] | 130 | # Receives the type of model for the fitting |
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[52ac10b] | 131 | from sans.models.LineModel import LineModel |
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[ca6d914] | 132 | model11 = LineModel() |
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| 133 | model11.name= "line" |
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[2eaaf1a] | 134 | model11.setParam("A", 1.0) |
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| 135 | model11.setParam("B",1.0) |
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| 136 | |
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[1e3169c] | 137 | from sans.models.Constant import Constant |
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[ca6d914] | 138 | model22 = Constant() |
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| 139 | model22.name= "cst" |
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[2eaaf1a] | 140 | model22.setParam("value", 1.0) |
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[8bbab51] | 141 | |
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[ca6d914] | 142 | model1 = Model(model11) |
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| 143 | model2 = Model(model22) |
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[8bbab51] | 144 | model1.set(A=4) |
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| 145 | model1.set(B=3) |
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[1e3169c] | 146 | # Constraint the constant value to be equal to parameter B (the real value is 2.5) |
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[8bbab51] | 147 | model2.set(value='line.B') |
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[ca6d914] | 148 | #fit with scipy test |
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| 149 | pars1= ['A','B'] |
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| 150 | pars2= ['value'] |
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| 151 | |
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[1e3169c] | 152 | #Importing the Fit module |
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| 153 | from sans.fit.Fitting import Fit |
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| 154 | fitter = Fit('park') |
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[ca6d914] | 155 | fitter.set_data(data1,1) |
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| 156 | fitter.set_model(model1,1,pars1) |
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[8296ff5] | 157 | fitter.set_data(data2,2,smearer=None) |
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[ca6d914] | 158 | fitter.set_model(model2,2,pars2) |
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[8bbab51] | 159 | fitter.select_problem_for_fit(Uid=1,value=1) |
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| 160 | fitter.select_problem_for_fit(Uid=2,value=1) |
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[ca6d914] | 161 | |
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| 162 | result2 = fitter.fit() |
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| 163 | self.assert_(result2) |
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[2eaaf1a] | 164 | self.assertTrue( math.fabs(result2.pvec[0]-4.0)/3. <= result2.stderr[0]) |
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| 165 | self.assertTrue( math.fabs(result2.pvec[1]-2.5)/3. <= result2.stderr[1]) |
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[1e3169c] | 166 | self.assertTrue( result2.fitness/(len(data1.x)+len(data2.x)) < 2) |
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[ca6d914] | 167 | |
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| 168 | |
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| 169 | def test4(self): |
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| 170 | """ fit 2 data concatenates with limited range of x and one model """ |
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| 171 | #load data |
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| 172 | from DataLoader.loader import Loader |
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| 173 | l = Loader() |
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[1e3169c] | 174 | data1 = l.load("testdata_line.txt") |
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| 175 | data2 = l.load("testdata_line1.txt") |
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| 176 | |
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| 177 | |
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[ca6d914] | 178 | # Receives the type of model for the fitting |
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[52ac10b] | 179 | from sans.models.LineModel import LineModel |
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[ca6d914] | 180 | model1 = LineModel() |
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| 181 | model1.name= "M1" |
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[2eaaf1a] | 182 | model1.setParam("A", 1.0) |
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| 183 | model1.setParam("B",1.0) |
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| 184 | model = Model(model1) |
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[1e3169c] | 185 | |
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[ca6d914] | 186 | #fit with scipy test |
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| 187 | pars1= ['A','B'] |
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[1e3169c] | 188 | #Importing the Fit module |
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| 189 | from sans.fit.Fitting import Fit |
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| 190 | fitter = Fit('scipy') |
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[ca6d914] | 191 | fitter.set_data(data1,1,qmin=0, qmax=7) |
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| 192 | fitter.set_model(model,1,pars1) |
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| 193 | fitter.set_data(data2,1,qmin=1,qmax=10) |
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[8bbab51] | 194 | fitter.select_problem_for_fit(Uid=1,value=1) |
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[ca6d914] | 195 | |
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| 196 | result1 = fitter.fit() |
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| 197 | self.assert_(result1) |
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[916a15f] | 198 | |
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[2eaaf1a] | 199 | self.assertTrue( math.fabs(result1.pvec[0]-4)/3 <= result1.stderr[0] ) |
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| 200 | self.assertTrue( math.fabs(result1.pvec[1]-2.5)/3 <= result1.stderr[1]) |
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| 201 | self.assertTrue( result1.fitness/len(data1.x) < 2 ) |
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[ca6d914] | 202 | |
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| 203 | #fit with park test |
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| 204 | fitter = Fit('park') |
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| 205 | fitter.set_data(data1,1,qmin=0, qmax=7) |
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| 206 | fitter.set_model(model,1,pars1) |
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| 207 | fitter.set_data(data2,1,qmin=1,qmax=10) |
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[8bbab51] | 208 | fitter.select_problem_for_fit(Uid=1,value=1) |
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[ca6d914] | 209 | result2 = fitter.fit() |
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| 210 | |
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| 211 | self.assert_(result2) |
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[2eaaf1a] | 212 | self.assertTrue( math.fabs(result2.pvec[0]-4)/3 <= result2.stderr[0] ) |
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| 213 | self.assertTrue( math.fabs(result2.pvec[1]-2.5)/3 <= result2.stderr[1] ) |
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| 214 | self.assertTrue( result2.fitness/len(data1.x) < 2) |
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[ca6d914] | 215 | # compare fit result result for scipy and park |
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| 216 | self.assertAlmostEquals( result1.pvec[0], result2.pvec[0] ) |
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| 217 | self.assertAlmostEquals( result1.pvec[1],result2.pvec[1] ) |
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| 218 | self.assertAlmostEquals( result1.stderr[0],result2.stderr[0] ) |
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| 219 | self.assertAlmostEquals( result1.stderr[1],result2.stderr[1] ) |
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[1e3169c] | 220 | self.assertTrue( result2.fitness/(len(data2.x)+len(data1.x)) < 2 ) |
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[2eaaf1a] | 221 | |
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| 222 | |
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| 223 | |
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[ca6d914] | 224 | |
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