示例#1
0
    def setup_class(cls):
        #> example from above
        # results copied not directly from R
        res2 = Holder()
        res2.n = 80
        res2.d = 0.3
        res2.sig_level = 0.05
        res2.power = 0.475100870572638
        res2.alternative = 'two.sided'
        res2.note = 'NULL'
        res2.method = 'two sample power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs1': res2.n,
                     'alpha': res2.sig_level, 'power':res2.power, 'ratio': 1}
        cls.kwds_extra = {}
        cls.cls = smp.NormalIndPower
示例#2
0
    def setup_class(cls):
        #> example from above
        # results copied not directly from R
        res2 = Holder()
        res2.n = 80
        res2.d = 0.3
        res2.sig_level = 0.05
        res2.power = 0.475100870572638
        res2.alternative = 'two.sided'
        res2.note = 'NULL'
        res2.method = 'two sample power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs1': res2.n,
                     'alpha': res2.sig_level, 'power':res2.power, 'ratio': 1}
        cls.kwds_extra = {}
        cls.cls = smp.NormalIndPower
    def __init__(self):

        res2 = Holder()
        #> p = pwr.t2n.test(d=0.1,n1=20, n2=30,sig.level=0.05,alternative="greater")
        #> cat_items(p, "res2.")
        res2.n1 = 20
        res2.n2 = 30
        res2.d = 0.1
        res2.sig_level = 0.05
        res2.power = 0.09623589080917805
        res2.alternative = 'greater'
        res2.method = 't test power calculation'

        self.res2 = res2
        self.kwds = {'effect_size': res2.d, 'nobs1': res2.n1,
                     'alpha': res2.sig_level, 'power':res2.power, 'ratio': 1.5}
        self.kwds_extra = {'alternative': 'larger'}
        self.cls = smp.TTestIndPower
    def __init__(self):

        res2 = Holder()
        #> p = pwr.t.test(d=0.01,n=30,sig.level=0.05,type="two.sample",alternative="greater")
        #> cat_items(p, "res2.")
        res2.n = 30
        res2.d = 0.01
        res2.sig_level = 0.05
        res2.power = 0.0540740302835667
        res2.alternative = 'greater'
        res2.note = 'n is number in *each* group'
        res2.method = 'Two-sample t test power calculation'

        self.res2 = res2
        self.kwds = {'effect_size': res2.d, 'nobs1': res2.n,
                     'alpha': res2.sig_level, 'power':res2.power}
        self.kwds_extra = {'alternative': 'larger'}
        self.cls = smp.TTestIndPower
    def __init__(self):

        res2 = Holder()
        #> p = pwr.t.test(d=1,n=30,sig.level=0.05,type="two.sample",alternative="greater")
        #> cat_items(p, prefix='tt_power2_1g.')
        res2.n = 30
        res2.d = 1
        res2.sig_level = 0.05
        res2.power = 0.985459690251624
        res2.alternative = 'greater'
        res2.note = 'n is number in *each* group'
        res2.method = 'Two-sample t test power calculation'

        self.res2 = res2
        self.kwds = {'effect_size': res2.d, 'nobs1': res2.n,
                     'alpha': res2.sig_level, 'power':res2.power, 'ratio': 1}
        self.kwds_extra = {'alternative': 'larger'}
        self.cls = smp.TTestIndPower
    def __init__(self):

        res2 = Holder()
        #> p = pwr.t.test(d=0.1,n=20,sig.level=0.05,type="two.sample",alternative="two.sided")
        #> cat_items(p, "res2.")
        res2.n = 20
        res2.d = 0.1
        res2.sig_level = 0.05
        res2.power = 0.06095912465411235
        res2.alternative = 'two.sided'
        res2.note = 'n is number in *each* group'
        res2.method = 'Two-sample t test power calculation'

        self.res2 = res2
        self.kwds = {'effect_size': res2.d, 'nobs1': res2.n,
                     'alpha': res2.sig_level, 'power': res2.power, 'ratio': 1}
        self.kwds_extra = {}
        self.cls = smp.TTestIndPower
    def __init__(self):

        res2 = Holder()
        #> p = pwr.t.test(d=-0.2,n=20,sig.level=0.05,type="one.sample",alternative="less")
        #> cat_items(p, "res2.")
        res2.n = 20
        res2.d = -0.2
        res2.sig_level = 0.05
        res2.power = 0.21707518167191
        res2.alternative = 'less'
        res2.note = '''NULL'''
        res2.method = 'One-sample t test power calculation'

        self.res2 = res2
        self.kwds = {'effect_size': res2.d, 'nobs': res2.n,
                     'alpha': res2.sig_level, 'power': res2.power}
        self.kwds_extra = {'alternative': 'smaller'}
        self.cls = smp.TTestPower
    def __init__(self):

        res2 = Holder()
        #> p = pwr.t.test(d=0.05,n=20,sig.level=0.05,type="one.sample",alternative="greater")
        #> cat_items(p, "res2.")
        res2.n = 20
        res2.d = 0.05
        res2.sig_level = 0.05
        res2.power = 0.0764888785042198
        res2.alternative = 'greater'
        res2.note = '''NULL'''
        res2.method = 'One-sample t test power calculation'

        self.res2 = res2
        self.kwds = {'effect_size': res2.d, 'nobs': res2.n,
                     'alpha': res2.sig_level, 'power': res2.power}
        self.kwds_extra = {'alternative': 'larger'}
        self.cls = smp.TTestPower
    def __init__(self):

        res2 = Holder()
        #> p = pwr.t.test(d=1,n=30,sig.level=0.05,type="one.sample",alternative="greater")
        #> cat_items(p, prefix='tt_power1_1g.')
        res2.n = 30
        res2.d = 1
        res2.sig_level = 0.05
        res2.power = 0.999892010204909
        res2.alternative = 'greater'
        res2.note = 'NULL'
        res2.method = 'One-sample t test power calculation'

        self.res2 = res2
        self.kwds = {'effect_size': res2.d, 'nobs': res2.n,
                     'alpha': res2.sig_level, 'power': res2.power}
        self.kwds_extra = {'alternative': 'larger'}
        self.cls = smp.TTestPower
示例#10
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    def __init__(self):

        res2 = Holder()
        #> p = pwr.t.test(d=0.2,n=20,sig.level=0.05,type="one.sample",alternative="two.sided")
        #> cat_items(p, "res2.")
        res2.n = 20
        res2.d = 0.2
        res2.sig_level = 0.05
        res2.power = 0.1359562887679666
        res2.alternative = 'two.sided'
        res2.note = '''NULL'''
        res2.method = 'One-sample t test power calculation'

        self.res2 = res2
        self.kwds = {'effect_size': res2.d, 'nobs': res2.n,
                     'alpha': res2.sig_level, 'power':res2.power}
        self.kwds_extra = {}
        self.cls = smp.TTestPower
示例#11
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    def __init__(self):

        #> p = pwr.t.test(d=1,n=30,sig.level=0.05,type="two.sample",alternative="two.sided")
        #> cat_items(p, prefix='tt_power2_1.')
        res2 = Holder()
        res2.n = 30
        res2.d = 1
        res2.sig_level = 0.05
        res2.power = 0.9995636009612725
        res2.alternative = 'two.sided'
        res2.note = 'NULL'
        res2.method = 'One-sample t test power calculation'

        self.res2 = res2
        self.kwds = {'effect_size': res2.d, 'nobs': res2.n,
                     'alpha': res2.sig_level, 'power':res2.power}
        self.kwds_extra = {}
        self.cls = smp.TTestPower
示例#12
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    def __init__(self):

        #> p = pwr.t.test(d=1,n=30,sig.level=0.05,type="two.sample",alternative="two.sided")
        #> cat_items(p, prefix='tt_power2_1.')
        res2 = Holder()
        res2.n = 30
        res2.d = 1
        res2.sig_level = 0.05
        res2.power = 0.967708258242517
        res2.alternative = 'two.sided'
        res2.note = 'n is number in *each* group'
        res2.method = 'Two-sample t test power calculation'

        self.res2 = res2
        self.kwds = {'effect_size': res2.d, 'nobs1': res2.n,
                     'alpha': res2.sig_level, 'power': res2.power, 'ratio': 1}
        self.kwds_extra = {}
        self.cls = smp.TTestIndPower
示例#13
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    def __init__(self):

        res2 = Holder()
        #> p = pwr.t.test(d=0.2,n=20,sig.level=0.05,type="one.sample",alternative="less")
        #> cat_items(p, "res2.")
        res2.n = 20
        res2.d = 0.2
        res2.sig_level = 0.05
        res2.power = 0.006063932667926375
        res2.alternative = 'less'
        res2.note = '''NULL'''
        res2.method = 'One-sample t test power calculation'

        self.res2 = res2
        self.kwds = {'effect_size': res2.d, 'nobs': res2.n,
                     'alpha': res2.sig_level, 'power': res2.power}
        self.kwds_extra = {'alternative': 'smaller'}
        self.cls = smp.TTestPower
示例#14
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    def setup_class(cls):

        #> p = pwr.t.test(d=1,n=30,sig.level=0.05,type="two.sample",alternative="two.sided")
        #> cat_items(p, prefix='tt_power2_1.')
        res2 = Holder()
        res2.n = 30
        res2.d = 1
        res2.sig_level = 0.05
        res2.power = 0.967708258242517
        res2.alternative = 'two.sided'
        res2.note = 'n is number in *each* group'
        res2.method = 'Two-sample t test power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs1': res2.n,
                     'alpha': res2.sig_level, 'power': res2.power, 'ratio': 1}
        cls.kwds_extra = {}
        cls.cls = smp.TTestIndPower
示例#15
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    def __init__(self):

        res2 = Holder()
        #> p = pwr.t2n.test(d=0.1,n1=20, n2=30,sig.level=0.05,alternative="two.sided")
        #> cat_items(p, "res2.")
        res2.n1 = 20
        res2.n2 = 30
        res2.d = 0.1
        res2.sig_level = 0.05
        res2.power = 0.0633081832564667
        res2.alternative = 'two.sided'
        res2.method = 't test power calculation'

        self.res2 = res2
        self.kwds = {'effect_size': res2.d, 'nobs1': res2.n1,
                     'alpha': res2.sig_level, 'power':res2.power, 'ratio': 1.5}
        self.kwds_extra = {'alternative': 'two-sided'}
        self.cls = smp.TTestIndPower
示例#16
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    def setup_class(cls):

        res2 = Holder()
        #> p = pwr.t2n.test(d=0.1,n1=20, n2=30,sig.level=0.05,alternative="greater")
        #> cat_items(p, "res2.")
        res2.n1 = 20
        res2.n2 = 30
        res2.d = 0.1
        res2.sig_level = 0.05
        res2.power = 0.09623589080917805
        res2.alternative = 'greater'
        res2.method = 't test power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs1': res2.n1,
                     'alpha': res2.sig_level, 'power':res2.power, 'ratio': 1.5}
        cls.kwds_extra = {'alternative': 'larger'}
        cls.cls = smp.TTestIndPower
示例#17
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    def setup_class(cls):

        res2 = Holder()
        #> p = pwr.t2n.test(d=0.1,n1=20, n2=30,sig.level=0.05,alternative="two.sided")
        #> cat_items(p, "res2.")
        res2.n1 = 20
        res2.n2 = 30
        res2.d = 0.1
        res2.sig_level = 0.05
        res2.power = 0.0633081832564667
        res2.alternative = 'two.sided'
        res2.method = 't test power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs1': res2.n1,
                     'alpha': res2.sig_level, 'power':res2.power, 'ratio': 1.5}
        cls.kwds_extra = {'alternative': 'two-sided'}
        cls.cls = smp.TTestIndPower
示例#18
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    def setup_class(cls):

        res2 = Holder()
        #> p = pwr.t.test(d=0.2,n=20,sig.level=0.05,type="one.sample",alternative="less")
        #> cat_items(p, "res2.")
        res2.n = 20
        res2.d = 0.2
        res2.sig_level = 0.05
        res2.power = 0.006063932667926375
        res2.alternative = 'less'
        res2.note = '''NULL'''
        res2.method = 'One-sample t test power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs': res2.n,
                     'alpha': res2.sig_level, 'power': res2.power}
        cls.kwds_extra = {'alternative': 'smaller'}
        cls.cls = smp.TTestPower
示例#19
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    def setup_class(cls):

        res2 = Holder()
        #> p = pwr.t.test(d=1,n=30,sig.level=0.05,type="two.sample",alternative="greater")
        #> cat_items(p, prefix='tt_power2_1g.')
        res2.n = 30
        res2.d = 1
        res2.sig_level = 0.05
        res2.power = 0.985459690251624
        res2.alternative = 'greater'
        res2.note = 'n is number in *each* group'
        res2.method = 'Two-sample t test power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs1': res2.n,
                     'alpha': res2.sig_level, 'power':res2.power, 'ratio': 1}
        cls.kwds_extra = {'alternative': 'larger'}
        cls.cls = smp.TTestIndPower
示例#20
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    def setup_class(cls):

        res2 = Holder()
        #> p = pwr.t.test(d=0.01,n=30,sig.level=0.05,type="two.sample",alternative="greater")
        #> cat_items(p, "res2.")
        res2.n = 30
        res2.d = 0.01
        res2.sig_level = 0.05
        res2.power = 0.0540740302835667
        res2.alternative = 'greater'
        res2.note = 'n is number in *each* group'
        res2.method = 'Two-sample t test power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs1': res2.n,
                     'alpha': res2.sig_level, 'power':res2.power}
        cls.kwds_extra = {'alternative': 'larger'}
        cls.cls = smp.TTestIndPower
示例#21
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    def setup_class(cls):

        res2 = Holder()
        #> p = pwr.t.test(d=-0.2,n=20,sig.level=0.05,type="one.sample",alternative="less")
        #> cat_items(p, "res2.")
        res2.n = 20
        res2.d = -0.2
        res2.sig_level = 0.05
        res2.power = 0.21707518167191
        res2.alternative = 'less'
        res2.note = '''NULL'''
        res2.method = 'One-sample t test power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs': res2.n,
                     'alpha': res2.sig_level, 'power': res2.power}
        cls.kwds_extra = {'alternative': 'smaller'}
        cls.cls = smp.TTestPower
示例#22
0
    def setup_class(cls):

        res2 = Holder()
        #> p = pwr.t.test(d=0.1,n=20,sig.level=0.05,type="two.sample",alternative="two.sided")
        #> cat_items(p, "res2.")
        res2.n = 20
        res2.d = 0.1
        res2.sig_level = 0.05
        res2.power = 0.06095912465411235
        res2.alternative = 'two.sided'
        res2.note = 'n is number in *each* group'
        res2.method = 'Two-sample t test power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs1': res2.n,
                     'alpha': res2.sig_level, 'power': res2.power, 'ratio': 1}
        cls.kwds_extra = {}
        cls.cls = smp.TTestIndPower
示例#23
0
    def setup_class(cls):

        res2 = Holder()
        #> p = pwr.t.test(d=0.05,n=20,sig.level=0.05,type="one.sample",alternative="greater")
        #> cat_items(p, "res2.")
        res2.n = 20
        res2.d = 0.05
        res2.sig_level = 0.05
        res2.power = 0.0764888785042198
        res2.alternative = 'greater'
        res2.note = '''NULL'''
        res2.method = 'One-sample t test power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs': res2.n,
                     'alpha': res2.sig_level, 'power': res2.power}
        cls.kwds_extra = {'alternative': 'larger'}
        cls.cls = smp.TTestPower
示例#24
0
    def setup_class(cls):

        res2 = Holder()
        #> p = pwr.t.test(d=1,n=30,sig.level=0.05,type="one.sample",alternative="greater")
        #> cat_items(p, prefix='tt_power1_1g.')
        res2.n = 30
        res2.d = 1
        res2.sig_level = 0.05
        res2.power = 0.999892010204909
        res2.alternative = 'greater'
        res2.note = 'NULL'
        res2.method = 'One-sample t test power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs': res2.n,
                     'alpha': res2.sig_level, 'power': res2.power}
        cls.kwds_extra = {'alternative': 'larger'}
        cls.cls = smp.TTestPower
示例#25
0
    def setup_class(cls):

        res2 = Holder()
        #> p = pwr.t.test(d=0.2,n=20,sig.level=0.05,type="one.sample",alternative="two.sided")
        #> cat_items(p, "res2.")
        res2.n = 20
        res2.d = 0.2
        res2.sig_level = 0.05
        res2.power = 0.1359562887679666
        res2.alternative = 'two.sided'
        res2.note = '''NULL'''
        res2.method = 'One-sample t test power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs': res2.n,
                     'alpha': res2.sig_level, 'power':res2.power}
        cls.kwds_extra = {}
        cls.cls = smp.TTestPower
示例#26
0
    def setup_class(cls):

        #> p = pwr.t.test(d=1,n=30,sig.level=0.05,type="two.sample",alternative="two.sided")
        #> cat_items(p, prefix='tt_power2_1.')
        res2 = Holder()
        res2.n = 30
        res2.d = 1
        res2.sig_level = 0.05
        res2.power = 0.9995636009612725
        res2.alternative = 'two.sided'
        res2.note = 'NULL'
        res2.method = 'One-sample t test power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs': res2.n,
                     'alpha': res2.sig_level, 'power':res2.power}
        cls.kwds_extra = {}
        cls.cls = smp.TTestPower
示例#27
0
    def __init__(self):
        # forcing one-sample by using ratio=0
        res2 = Holder()
        #> np = pwr.norm.test(d=0.01,n=40,sig.level=0.05,alternative="less")
        #> cat_items(np, "res2.")
        res2.d = 0.01
        res2.n = 40
        res2.sig_level = 0.05
        res2.power = 0.0438089705093578
        res2.alternative = 'less'
        res2.method = 'Mean power calculation for normal distribution with known variance'

        self.res2 = res2
        self.kwds = {'effect_size': res2.d, 'nobs1': res2.n,
                     'alpha': res2.sig_level, 'power':res2.power}
        # keyword for which we don't look for root:
        self.kwds_extra = {'ratio': 0, 'alternative':'smaller'}

        self.cls = smp.NormalIndPower
示例#28
0
    def setup_class(cls):
        # forcing one-sample by using ratio=0
        res2 = Holder()
        #> np = pwr.norm.test(d=0.01,n=40,sig.level=0.05,alternative="less")
        #> cat_items(np, "res2.")
        res2.d = 0.01
        res2.n = 40
        res2.sig_level = 0.05
        res2.power = 0.0438089705093578
        res2.alternative = 'less'
        res2.method = 'Mean power calculation for normal distribution with known variance'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs1': res2.n,
                     'alpha': res2.sig_level, 'power':res2.power}
        # keyword for which we don't look for root:
        cls.kwds_extra = {'ratio': 0, 'alternative':'smaller'}

        cls.cls = smp.NormalIndPower
示例#29
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    def __init__(self):
        # forcing one-sample by using ratio=0
        #> example from above
        # results copied not directly from R
        res2 = Holder()
        res2.n = 40
        res2.d = 0.3
        res2.sig_level = 0.05
        res2.power = 0.475100870572638
        res2.alternative = 'two.sided'
        res2.note = 'NULL'
        res2.method = 'two sample power calculation'

        self.res2 = res2
        self.kwds = {'effect_size': res2.d, 'nobs1': res2.n,
                     'alpha': res2.sig_level, 'power':res2.power}
        # keyword for which we don't look for root:
        self.kwds_extra = {'ratio': 0}

        self.cls = smp.NormalIndPower
示例#30
0
    def setup_class(cls):
        # forcing one-sample by using ratio=0
        #> example from above
        # results copied not directly from R
        res2 = Holder()
        res2.n = 40
        res2.d = 0.3
        res2.sig_level = 0.05
        res2.power = 0.475100870572638
        res2.alternative = 'two.sided'
        res2.note = 'NULL'
        res2.method = 'two sample power calculation'

        cls.res2 = res2
        cls.kwds = {'effect_size': res2.d, 'nobs1': res2.n,
                     'alpha': res2.sig_level, 'power':res2.power}
        # keyword for which we don't look for root:
        cls.kwds_extra = {'ratio': 0}

        cls.cls = smp.NormalIndPower