def test_with_cov(self):
simdict = Simulations()
meadict = Measurements()
covdict = Covariances()
# mock measurements
dtuple = DomainTuple.make((RGSpace(1), RGSpace(12)))
arr_a = np.random.rand(1, 12)
comm.Bcast(arr_a, root=0)
mea = Observable(dtuple, arr_a)
meadict.append(('test', 'nan', '12', 'nan'), mea, True)
# mock sims
dtuple = DomainTuple.make((RGSpace(5*mpisize), RGSpace(12)))
arr_b = np.random.rand(5, 12)
sim = Observable(dtuple, arr_b)
simdict.append(('test', 'nan', '12', 'nan'), sim, True)
# mock covariance
arr_c = np.random.rand(12, 12)
comm.Bcast(arr_c, root=0)
dtuple = DomainTuple.make((RGSpace(shape=arr_c.shape)))
cov = Field.from_global_data(dtuple, arr_c)
covdict.append(('test', 'nan', '12', 'nan'), cov, True)
# with covariance
lh = SimpleLikelihood(meadict, covdict)
# calc by likelihood
rslt = lh(simdict) # feed variable value, not parameter value
# calc by hand
arr_b = sim.to_global_data() # get global arr_b
diff = (np.mean(arr_b, axis=0) - arr_a)
(sign, logdet) = np.linalg.slogdet(arr_c*2.*np.pi)
baseline = -float(0.5)*float(np.vdot(diff, np.linalg.solve(arr_c, diff.T))+sign*logdet)
self.assertAlmostEqual(rslt, baseline)
def test_without_simcov(self):
simdict = Simulations()
meadict = Measurements()
covdict = Covariances()
# mock measurements
dtuple = DomainTuple.make((RGSpace(1), HPSpace(nside=2)))
arr_a = np.random.rand(1, 48)
comm.Bcast(arr_a, root=0)
mea = Observable(dtuple, arr_a)
meadict.append(('test', 'nan', '2', 'nan'), mea)
# mock covariance
dtuple = DomainTuple.make((RGSpace(shape=(48, 48))))
arr_c = np.random.rand(48, 48)
comm.Bcast(arr_c, root=0)
cov = Field.from_global_data(dtuple, arr_c)
covdict.append(('test', 'nan', '2', 'nan'), cov)
# mock observable with repeated single realisation
dtuple = DomainTuple.make((RGSpace(5*mpisize), HPSpace(nside=2)))
arr_b = np.random.rand(1, 48)
comm.Bcast(arr_b, root=0)
arr_ens = np.zeros((5, 48))
for i in range(len(arr_ens)):
arr_ens[i] = arr_b
sim = Observable(dtuple, arr_ens)
simdict.append(('test', 'nan', '2', 'nan'), sim)
# simplelikelihood
lh_simple = SimpleLikelihood(meadict, covdict)
rslt_simple = lh_simple(simdict)
# ensemblelikelihood
lh_ensemble = EnsembleLikelihood(meadict, covdict)
rslt_ensemble = lh_ensemble(simdict)
self.assertEqual(rslt_ensemble, rslt_simple)
def test_with_cov(self):
simdict = Simulations()
meadict = Measurements()
covdict = Covariances()
# mock measurements
arr_a = np.random.rand(1, 4 * mpisize)
comm.Bcast(arr_a, root=0)
mea = Observable(arr_a, 'measured')
meadict.append(('test', 'nan', str(4 * mpisize), 'nan'), mea, True)
# mock sims
arr_b = np.random.rand(5, 4 * mpisize)
sim = Observable(arr_b, 'simulated')
simdict.append(('test', 'nan', str(4 * mpisize), 'nan'), sim, True)
# mock covariance
arr_c = np.random.rand(4, 4 * mpisize)
cov = Observable(arr_c, 'covariance')
covdict.append(('test', 'nan', str(4 * mpisize), 'nan'), cov, True)
# with covariance
lh = SimpleLikelihood(meadict, covdict)
# calc by likelihood
rslt = lh(simdict) # feed variable value, not parameter value
# calc by hand
full_b = np.vstack(comm.allgather(arr_b)) # global arr_b
diff = (np.mean(full_b, axis=0) - arr_a)
full_cov = np.vstack(comm.allgather(arr_c)) # global covariance
(sign, logdet) = np.linalg.slogdet(full_cov * 2. * np.pi)
baseline = -float(0.5) * float(
np.vdot(diff, np.linalg.solve(full_cov, diff.T)) + sign * logdet)
self.assertAlmostEqual(rslt, baseline)
def test_without_simcov(self):
simdict = Simulations()
meadict = Measurements()
covdict = Covariances()
# mock measurements
arr_a = np.random.rand(1, 4 * mpisize)
comm.Bcast(arr_a, root=0)
mea = Observable(arr_a, 'measured')
meadict.append(('test', 'nan', str(4 * mpisize), 'nan'), mea, True)
# mock covariance
arr_c = np.random.rand(4, 4 * mpisize)
cov = Observable(arr_c, 'covariance')
covdict.append(('test', 'nan', str(4 * mpisize), 'nan'), cov, True)
# mock observable with repeated single realisation
arr_b = np.random.rand(1, 4 * mpisize)
comm.Bcast(arr_b, root=0)
arr_ens = np.zeros((2, 4 * mpisize))
for i in range(len(arr_ens)):
arr_ens[i] = arr_b
sim = Observable(arr_ens, 'simulated')
simdict.append(('test', 'nan', str(4 * mpisize), 'nan'), sim, True)
# simplelikelihood
lh_simple = SimpleLikelihood(meadict, covdict)
rslt_simple = lh_simple(simdict)
# ensemblelikelihood
lh_ensemble = EnsembleLikelihood(meadict, covdict)
rslt_ensemble = lh_ensemble(simdict)
self.assertEqual(rslt_ensemble, rslt_simple)
def test_covdict_apply_mask(self):
msk = np.random.randint(0, 2, 2 * mpisize).reshape(1, -1)
mskdict = Masks()
comm.Bcast(msk, root=0)
mskdict.append(('test', 'nan', str(2 * mpisize), 'nan'), msk, True)
cov = np.random.rand(2, 2 * mpisize)
covdict = Covariances()
covdict.append(('test', 'nan', str(2 * mpisize), 'nan'), cov, True)
covdict.apply_mask(mskdict)
pix_num = msk.sum()
self.assertTrue(('test', 'nan', str(pix_num), 'nan') in covdict.keys())
def test_covdict_apply_mask(self):
msk = np.array([0, 1, 0, 1, 1]).reshape(1, 5)
mskdict = Masks()
mskdict.append(('test', 'nan', '5', 'nan'), msk, True)
cov_field = Field.from_global_data(RGSpace(shape=(5, 5)),
np.random.rand(5, 5))
arr = cov_field.local_data
covdict = Covariances()
covdict.append(('test', 'nan', '5', 'nan'), arr, True)
covdict.apply_mask(mskdict)
arr = np.delete(cov_field.to_global_data(), [0, 2], 0)
arr = np.delete(arr, [0, 2], 1)
for i in range(arr.shape[0]):
self.assertListEqual(
list((covdict[('test', 'nan', '3',
'nan')].to_global_data())[i]), list(arr[i]))
def test_covdict_append_observable(self):
cov = Observable(np.random.rand(2, 2 * mpisize), 'covariance')
covdict = Covariances()
covdict.append(('test', 'nan', str(2 * mpisize), 'nan'), cov,
True) # plain covariance
for i in range(len(cov.data)):
self.assertListEqual(
list((covdict[('test', 'nan', str(2 * mpisize),
'nan')].data)[i]), list((cov.data)[i]))
cov = Observable(np.random.rand(12 * mpisize, 12 * mpisize * mpisize),
'covariance')
covdict.append(('test', 'nan', str(mpisize), 'nan'),
cov) # healpix covariance
for i in range(len(cov.data)):
self.assertListEqual(
list((covdict[('test', 'nan', str(mpisize), 'nan')].data)[i]),
list((cov.data)[i]))
def test_covdict_append_field(self):
cov_field = Field.from_global_data(RGSpace(shape=(3, 3)),
np.random.rand(3, 3))
covdict = Covariances()
covdict.append(('test', 'nan', '3', 'nan'), cov_field,
True) # plain covariance
for i in range(len(cov_field.local_data)):
self.assertListEqual(
list((covdict[('test', 'nan', '3', 'nan')].local_data)[i]),
list((cov_field.local_data)[i]))
cov_field = Field.from_global_data(RGSpace(shape=(48, 48)),
np.random.rand(48, 48))
covdict.append(('test', 'nan', '2', 'nan'),
cov_field) # healpix covariance
for i in range(len(cov_field.local_data)):
self.assertListEqual(
list((covdict[('test', 'nan', '2', 'nan')].local_data)[i]),
list((cov_field.local_data)[i]))
def test_covdict_append_array(self):
cov = (Field.from_global_data(RGSpace(shape=(5, 5)),
np.random.rand(5, 5))).local_data
covdict = Covariances()
covdict.append(('test', 'nan', '5', 'nan'), cov,
True) # plain covariance
self.assertEqual(covdict[('test', 'nan', '5', 'nan')].shape, (5, 5))
for i in range(len(cov)):
self.assertListEqual(
list((covdict[('test', 'nan', '5', 'nan')].local_data)[i]),
list(cov[i]))
cov = np.random.rand(48, 48)
comm.Bcast(cov, root=0)
covdict.append(('test', 'nan', '2', 'nan'), cov) # healpix covariance
self.assertEqual(covdict[('test', 'nan', '2', 'nan')].shape, (48, 48))
for i in range(len(cov)):
self.assertListEqual(
list((covdict[('test', 'nan', '2',
'nan')].to_global_data())[i]), list(cov[i]))
def test_covdict_append_array(self):
cov = np.random.rand(2, 2 * mpisize)
covdict = Covariances()
covdict.append(('test', 'nan', str(2 * mpisize), 'nan'), cov,
True) # plain covariance
self.assertEqual(
covdict[('test', 'nan', str(2 * mpisize), 'nan')].shape,
(2 * mpisize, 2 * mpisize))
for i in range(len(cov)):
self.assertListEqual(
list((covdict[('test', 'nan', str(2 * mpisize),
'nan')].data)[i]), list(cov[i]))
cov = np.random.rand(12 * mpisize, 12 * mpisize * mpisize)
covdict.append(('test', 'nan', str(mpisize), 'nan'),
cov) # healpix covariance
self.assertEqual(covdict[('test', 'nan', str(mpisize), 'nan')].shape,
(12 * mpisize * mpisize, 12 * mpisize * mpisize))
for i in range(len(cov)):
self.assertListEqual(
list((covdict[('test', 'nan', str(mpisize), 'nan')].data)[i]),
list(cov[i]))
def testfield():
"""
:return:
log.basicConfig(filename='imagine.log', level=log.INFO)
"""
"""
# step 0, set 'a' and 'b', 'mea_std'
TestField in LiSimulator is modeled as
field = gaussian_random(mean=a,std=b)_x * cos(x)
where x in (0,2pi)
for generating mock data we need
true values of a and b: true_a, true_b, mea_seed
measurement uncertainty: mea_std
measurement points, positioned in (0,2pi) evenly, due to TestField modelling
"""
true_a = 3.
true_b = 6.
mea_std = 0.1 # std of gaussian measurement error
mea_seed = 233
mea_points = 10 # data points in measurements
truths = [true_a, true_b] # will be used in visualizing posterior
"""
# step 1, prepare mock data
"""
"""
# 1.1, generate measurements
mea_field = signal_field + noise_field
"""
x = np.linspace(0, 2. * np.pi, mea_points)
np.random.seed(mea_seed) # seed for signal field
signal_field = np.multiply(
np.cos(x), np.random.normal(loc=true_a, scale=true_b, size=mea_points))
mea_field = np.vstack([
signal_field + np.random.normal(loc=0., scale=mea_std, size=mea_points)
])
"""
# 1.2, generate covariances
"""
# pre-defined according to measurement error
mea_cov = (mea_std**2) * np.eye(mea_points)
"""
# 1.3 assemble in imagine convention
"""
mock_data = Measurements() # create empty Measrurements object
mock_cov = Covariances() # create empty Covariance object
# pick up a measurement
mock_data.append(('test', 'nan', str(mea_points), 'nan'), mea_field, True)
mock_cov.append(('test', 'nan', str(mea_points), 'nan'), mea_cov, True)
"""
# 1.4, visualize mock data
"""
#if mpirank == 0:
#matplotlib.pyplot.plot(x, mock_data[('test', 'nan', str(mea_points), 'nan')].to_global_data()[0])
#matplotlib.pyplot.savefig('testfield_mock.pdf')
"""
# step 2, prepare pipeline and execute analysis
"""
"""
# 2.1, ensemble likelihood
"""
likelihood = EnsembleLikelihood(
mock_data, mock_cov) # initialize likelihood with measured info
"""
# 2.2, field factory list
"""
factory = TestFieldFactory(
active_parameters=('a', 'b')) # factory with single active parameter
factory.parameter_ranges = {
'a': (0, 10),
'b': (0, 10)
} # adjust parameter range for Bayesian analysis
factory_list = [factory] # likelihood requires a list/tuple of factories
"""
# 2.3, flat prior
"""
prior = FlatPrior()
"""
# 2.4, simulator
"""
simer = LiSimulator(mock_data)
"""
# 2.5, pipeline
"""
ensemble_size = 10
pipe = MultinestPipeline(simer, factory_list, likelihood, prior,
ensemble_size)
pipe.random_type = 'free'
pipe.sampling_controllers = {
'n_iter_before_update': 1,
'n_live_points': 400,
'verbose': True,
'resume': False
}
results = pipe() # run with pymultinest
"""
# step 3, visualize (with corner package)
"""
if mpirank == 0:
samples = results['samples']
for i in range(len(
pipe.active_parameters)): # convert variables into parameters
low, high = pipe.active_ranges[pipe.active_parameters[i]]
for j in range(samples.shape[0]):
samples[j, i] = unity_mapper(samples[j, i], low, high)
# corner plot
corner.corner(samples[:, :len(pipe.active_parameters)],
range=[0.99] * len(pipe.active_parameters),
quantiles=[0.02, 0.5, 0.98],
labels=pipe.active_parameters,
show_titles=True,
title_kwargs={"fontsize": 15},
color='steelblue',
truths=truths,
truth_color='firebrick',
plot_contours=True,
hist_kwargs={'linewidth': 2},
label_kwargs={'fontsize': 15})
matplotlib.pyplot.savefig('testfield_posterior.pdf')
def testfield(measure_size, simulation_size, make_plots=True, debug=False):
if debug:
log.basicConfig(filename='imagine_li_dynesty.log', level=log.DEBUG)
else:
log.basicConfig(filename='imagine_li_dynesty.log')
"""
:return:
log.basicConfig(filename='imagine.log', level=log.INFO)
"""
"""
# step 0, set 'a' and 'b', 'mea_std'
TestField in LiSimulator is modeled as
field = gaussian_random(mean=a,std=b)_x * cos(x)
where x in (0,2pi)
for generating mock data we need
true values of a and b: true_a, true_b, mea_seed
measurement uncertainty: mea_std
measurement points, positioned in (0,2pi) evenly, due to TestField modelling
"""
true_a = 3.
true_b = 6.
mea_std = 0.1 # std of gaussian measurement error
mea_seed = 233
truths = [true_a, true_b] # will be used in visualizing posterior
"""
# step 1, prepare mock data
"""
"""
# 1.1, generate measurements
mea_field = signal_field + noise_field
"""
x = np.linspace(0, 2. * np.pi, measure_size) # data points in measurements
np.random.seed(mea_seed) # seed for signal field
signal_field = np.multiply(
np.cos(x), np.random.normal(loc=true_a,
scale=true_b,
size=measure_size))
mea_field = np.vstack([
signal_field +
np.random.normal(loc=0., scale=mea_std, size=measure_size)
])
"""
# 1.2, generate covariances
what's the difference between pre-define dan re-estimated?
"""
# re-estimate according to measurement error
mea_repeat = np.zeros((simulation_size, measure_size))
for i in range(simulation_size): # times of repeated measurements
mea_repeat[i, :] = signal_field + np.random.normal(
loc=0., scale=mea_std, size=measure_size)
mea_cov = oas_mcov(mea_repeat)[1]
print(mpirank, 're-estimated: \n', mea_cov, 'slogdet',
mpi_slogdet(mea_cov))
# pre-defined according to measurement error
mea_cov = (mea_std**2) * mpi_eye(measure_size)
print(mpirank, 'pre-defined: \n', mea_cov, 'slogdet', mpi_slogdet(mea_cov))
"""
# 1.3 assemble in imagine convention
"""
mock_data = Measurements() # create empty Measrurements object
mock_cov = Covariances() # create empty Covariance object
# pick up a measurement
mock_data.append(('test', 'nan', str(measure_size), 'nan'), mea_field,
True)
mock_cov.append(('test', 'nan', str(measure_size), 'nan'), mea_cov, True)
"""
# 1.4, visualize mock data
"""
if mpirank == 0 and make_plots:
plt.plot(x,
mock_data[('test', 'nan', str(measure_size), 'nan')].data[0])
plt.savefig('testfield_mock_li.pdf')
"""
# step 2, prepare pipeline and execute analysis
"""
"""
# 2.1, ensemble likelihood
"""
likelihood = EnsembleLikelihood(
mock_data, mock_cov) # initialize likelihood with measured info
"""
# 2.2, field factory list
"""
factory = TestFieldFactory(
active_parameters=('a', 'b')) # factory with single active parameter
factory.parameter_ranges = {
'a': (0, 10),
'b': (0, 10)
} # adjust parameter range for Bayesian analysis
factory_list = [factory] # likelihood requires a list/tuple of factories
"""
# 2.3, flat prior
"""
prior = FlatPrior()
"""
# 2.4, simulator
"""
simer = LiSimulator(mock_data)
"""
# 2.5, pipeline
"""
pipe = DynestyPipeline(simer, factory_list, likelihood, prior,
simulation_size)
pipe.random_type = 'controllable' # 'fixed' random_type doesnt work for Dynesty pipeline, yet
pipe.seed_tracer = int(23)
pipe.sampling_controllers = {'nlive': 400}
tmr = Timer()
tmr.tick('test')
results = pipe()
tmr.tock('test')
if mpirank == 0:
print('\n elapse time ' + str(tmr.record['test']) + '\n')
"""
# step 3, visualize (with corner package)
"""
if mpirank == 0 and make_plots:
samples = results['samples']
for i in range(len(
pipe.active_parameters)): # convert variables into parameters
low, high = pipe.active_ranges[pipe.active_parameters[i]]
for j in range(samples.shape[0]):
samples[j, i] = unity_mapper(samples[j, i], low, high)
# corner plot
corner.corner(samples[:, :len(pipe.active_parameters)],
range=[0.99] * len(pipe.active_parameters),
quantiles=[0.02, 0.5, 0.98],
labels=pipe.active_parameters,
show_titles=True,
title_kwargs={"fontsize": 15},
color='steelblue',
truths=truths,
truth_color='firebrick',
plot_contours=True,
hist_kwargs={'linewidth': 2},
label_kwargs={'fontsize': 20})
plt.savefig('testfield_posterior_li_dynesty.pdf')
def mock_errprop(_nside, _freq):
"""
return masked mock synchrotron Q, U
error propagated from theoretical uncertainties
"""
# hammurabi parameter base file
xmlpath = './params_masked_random.xml'
# active parameters
true_b0 = 3.0
true_psi0 = 27.0
true_psi1 = 0.9
true_chi0 = 25.
true_alpha = 3.0
true_r0 = 5.0
true_z0 = 1.0
true_rms = 6.0
true_rho = 0.8
true_a0 = 1.7
#
_npix = 12 * _nside**2
#
x = np.zeros((1, _npix)) # only for triggering simulator
trigger = Measurements()
trigger.append(('sync', str(_freq), str(_nside), 'Q'), x) # Q map
trigger.append(('sync', str(_freq), str(_nside), 'U'), x) # U map
# initialize simulator
mocksize = 20 # ensemble of mock data
error = 0.1 # theoretical raltive uncertainty for each (active) parameter
mocker = Hammurabi(measurements=trigger, xml_path=xmlpath)
# prepare theoretical uncertainty
b0_var = np.random.normal(true_b0, error * true_b0, mocksize)
psi0_var = np.random.normal(true_psi0, error * true_psi0, mocksize)
psi1_var = np.random.normal(true_psi1, error * true_psi1, mocksize)
chi0_var = np.random.normal(true_chi0, error * true_chi0, mocksize)
alpha_var = np.random.normal(true_alpha, error * true_alpha, mocksize)
r0_var = np.random.normal(true_r0, error * true_r0, mocksize)
z0_var = np.random.normal(true_z0, error * true_z0, mocksize)
rms_var = np.random.normal(true_rms, error * ture_rms, mocksize)
rho_var = np.random.normal(true_rho, error * true_rho, mocksize)
a0_var = np.random.normal(true_a0, error * true_a0, mocksize)
mock_raw_q = np.zeros((mocksize, _npix))
mock_raw_u = np.zeros((mocksize, _npix))
# start simulation
for i in range(mocksize): # get one realization each time
# BregWMAP field
paramlist = {
'b0': b0_var[i],
'psi0': psi0_var[i],
'psi1': psi1_var[i],
'chi0': chi0_var[i]
}
breg_wmap = BregWMAP(paramlist, 1)
# CREAna field
paramlist = {
'alpha': alpha_var[i],
'beta': 0.0,
'theta': 0.0,
'r0': r0_var[i],
'z0': z0_var[i],
'E0': 20.6,
'j0': 0.0217
}
cre_ana = CREAna(paramlist, 1)
# FEregYMW16 field
paramlist = dict()
fereg_ymw16 = FEregYMW16(paramlist, 1)
# BrndES field
paramlist = {
'rms': rms_var[i],
'k0': 0.1,
'a0': a0_var[i],
'rho': rho_var[i],
'r0': 8.0,
'z0': 1.0
}
brnd_es = BrndES(paramlist, 1)
# collect mock data and covariance
outputs = mocker([breg_wmap, cre_ana, fereg_ymw16, brnd_es])
mock_raw_q[i, :] = outputs[('sync', str(_freq), str(_nside),
'Q')].local_data
mock_raw_u[i, :] = outputs[('sync', str(_freq), str(_nside),
'U')].local_data
# collect mean and cov from simulated results
sim_data = Simulations()
mock_data = Measurements()
mock_cov = Covariances()
sim_data.append(('sync', str(_freq), str(_nside), 'Q'), mock_raw_q)
sim_data.append(('sync', str(_freq), str(_nside), 'U'), mock_raw_u)
mock_mask = mask_map(_nside, _freq)
sim_data.apply_mask(mock_mask)
for key in sim_data.keys():
mock_data.append(
key,
np.vstack([(sim_data[key].to_global_data())[np.random.randint(
0, mocksize)]]), True)
mock_cov.append(key, oas_cov(sim_data[key].to_global_data()), True)
return mock_data, mock_cov
def mock_errfix(_nside, _freq):
"""
return masked mock synchrotron Q, U
error fixed
"""
# hammurabi parameter base file
xmlpath = './params_masked_random.xml'
# active parameters
true_b0 = 3.0
true_psi0 = 27.0
true_psi1 = 0.9
true_chi0 = 25.
true_alpha = 3.0
true_r0 = 5.0
true_z0 = 1.0
true_rms = 6.0
true_rho = 0.8
true_a0 = 1.7
#
_npix = 12 * _nside**2
#
x = np.zeros((1, _npix)) # only for triggering simulator
trigger = Measurements()
trigger.append(('sync', str(_freq), str(_nside), 'Q'), x) # Q map
trigger.append(('sync', str(_freq), str(_nside), 'U'), x) # U map
# initialize simulator
error = 0.1
mocker = Hammurabi(measurements=trigger, xml_path=xmlpath)
# start simulation
# BregWMAP field
paramlist = {
'b0': true_b0,
'psi0': true_psi0,
'psi1': true_psi1,
'chi0': true_chi0
}
breg_wmap = BregWMAP(paramlist, 1)
# CREAna field
paramlist = {
'alpha': true_alpha,
'beta': 0.0,
'theta': 0.0,
'r0': true_r0,
'z0': true_z0,
'E0': 20.6,
'j0': 0.0217
}
cre_ana = CREAna(paramlist, 1)
# FEregYMW16 field
paramlist = dict()
fereg_ymw16 = FEregYMW16(paramlist, 1)
# BrndES field
paramlist = {
'rms': true_rms,
'k0': 0.1,
'a0': true_a0,
'rho': true_rho,
'r0': 8.0,
'z0': 1.0
}
brnd_es = BrndES(paramlist, 1)
# collect mock data and covariance
outputs = mocker([breg_wmap, cre_ana, fereg_ymw16, brnd_es])
mock_raw_q = outputs[('sync', str(_freq), str(_nside), 'Q')].local_data
mock_raw_u = outputs[('sync', str(_freq), str(_nside), 'U')].local_data
# collect mean and cov from simulated results
mock_data = Measurements()
mock_cov = Covariances()
mock_data.append(('sync', str(_freq), str(_nside), 'Q'), mock_raw_q)
mock_data.append(('sync', str(_freq), str(_nside), 'U'), mock_raw_u)
mock_mask = mask_map(_nside, _freq)
mock_data.apply_mask(mock_mask)
for key in mock_data.keys():
mock_cov.append(key, (error**2 * (np.std(mock_raw_q))**2) *
np.eye(int(key[2])), True)
return mock_data, mock_cov
def wmap_errprop():
#log.basicConfig(filename='imagine.log', level=log.DEBUG)
"""
only WMAP regular magnetic field model in test, @ 23GHz
Faraday rotation provided by YMW16 free electron model
full WMAP parameter set {b0, psi0, psi1, chi0}
"""
# hammurabi parameter base file
xmlpath = './params_fullsky_regular.xml'
# we take three active parameters
true_b0 = 6.0
true_psi0 = 27.0
true_psi1 = 0.9
true_chi0 = 25.
true_alpha = 3.0
true_r0 = 5.0
true_z0 = 1.0
mea_nside = 2 # observable Nside
mea_pix = 12 * mea_nside**2 # observable pixel number
"""
# step 1, prepare mock data
"""
x = np.zeros((1, mea_pix)) # only for triggering simulator
trigger = Measurements()
trigger.append(('sync', '23', str(mea_nside), 'I'), x) # only I map
# initialize simulator
mocksize = 10 # ensemble of mock data (per node)
error = 0.1 # theoretical raltive uncertainty for each (active) parameter
mocker = Hammurabi(measurements=trigger, xml_path=xmlpath)
# prepare theoretical uncertainty
b0_var = np.random.normal(true_b0, error * true_b0, mocksize)
psi0_var = np.random.normal(true_psi0, error * true_psi0, mocksize)
psi1_var = np.random.normal(true_psi1, error * true_psi1, mocksize)
chi0_var = np.random.normal(true_chi0, error * true_chi0, mocksize)
alpha_var = np.random.normal(true_alpha, error * true_alpha, mocksize)
r0_var = np.random.normal(true_r0, error * true_r0, mocksize)
z0_var = np.random.normal(true_z0, error * true_z0, mocksize)
mock_ensemble = Simulations()
# start simulation
for i in range(mocksize): # get one realization each time
# BregWMAP field
paramlist = {
'b0': b0_var[i],
'psi0': psi0_var[i],
'psi1': psi1_var[i],
'chi0': chi0_var[i]
} # inactive parameters at default
breg_wmap = BregWMAP(paramlist, 1)
# CREAna field
paramlist = {
'alpha': alpha_var[i],
'beta': 0.0,
'theta': 0.0,
'r0': r0_var[i],
'z0': z0_var[i],
'E0': 20.6,
'j0': 0.0217
} # inactive parameters at default
cre_ana = CREAna(paramlist, 1)
# FEregYMW16 field
fereg_ymw16 = FEregYMW16(dict(), 1)
# collect mock data and covariance
outputs = mocker([breg_wmap, cre_ana, fereg_ymw16])
mock_ensemble.append(('sync', '23', str(mea_nside), 'I'),
outputs[('sync', '23', str(mea_nside), 'I')])
# collect mean and cov from simulated results
mock_data = Measurements()
mock_cov = Covariances()
mean, cov = oas_mcov(mock_ensemble[('sync', '23', str(mea_nside), 'I')])
mock_data.append(('sync', '23', str(mea_nside), 'I'), mean)
mock_cov.append(('sync', '23', str(mea_nside), 'I'), cov)
"""
# step 2, prepare pipeline and execute analysis
"""
#likelihood = EnsembleLikelihood(mock_data, mock_cov)
likelihood = SimpleLikelihood(mock_data, mock_cov)
breg_factory = BregWMAPFactory(active_parameters=('b0', 'psi0', 'psi1',
'chi0'))
breg_factory.parameter_ranges = {
'b0': (0., 10.),
'psi0': (0., 50.),
'psi1': (0., 2.),
'chi0': (0., 50.)
}
cre_factory = CREAnaFactory(active_parameters=('alpha', 'r0', 'z0'))
cre_factory.parameter_ranges = {
'alpha': (1., 5.),
'r0': (1., 10.),
'z0': (0.1, 5.)
}
fereg_factory = FEregYMW16Factory()
factory_list = [breg_factory, cre_factory, fereg_factory]
prior = FlatPrior()
simer = Hammurabi(measurements=mock_data, xml_path=xmlpath)
ensemble_size = 1
pipe = MultinestPipeline(simer, factory_list, likelihood, prior,
ensemble_size)
pipe.random_type = 'free'
pipe.sampling_controllers = {
'n_live_points': 4000,
'resume': False,
'verbose': True
}
results = pipe()
"""
# step 3, visualize (with corner package)
"""
if mpirank == 0:
samples = results['samples']
np.savetxt('posterior_fullsky_regular_errprop.txt', samples)
"""
