def get_amp_first_harmonic(a, tes, freq_mod):
"""
This function takes the signal of a given TES, makes its spectrum
and get the amplitude of the first harmonic that should be around
the modulation frequency of the source.
Parameters
----------
a : qubicpack object
tes : int
tes number
freq_mod : float
modulation frequency of the external source
Returns
-------
"""
data = a.timeline(TES=tes)
t_data = a.timeline_timeaxis(axistype='pps')
FREQ_SAMPLING = 1. / (t_data[1] - t_data[0])
spectrum_f, freq_f = mlab.psd(data,
Fs=FREQ_SAMPLING,
NFFT=len(data),
window=mlab.window_hanning)
amp_peak = np.interp(freq_mod, freq_f, spectrum_f)
okfit = np.abs(freq_f - freq_mod) < 0.1
guess = np.array([
freq_mod, 0.01,
np.max(spectrum_f[okfit]),
np.median(spectrum_f[okfit])
])
res = ft.do_minuit(freq_f[okfit],
spectrum_f[okfit],
np.ones(np.sum(okfit)),
guess,
functname=dl.gauss,
fixpars=[1, 0, 0, 0, 0],
nohesse=True,
force_chi2_ndf=True)
return t_data, data, FREQ_SAMPLING, freq_f, spectrum_f, amp_peak, okfit, res
def minuit(self,
p0=None,
chi2=None,
verbose=True,
print_level=0,
ncallmax=10000,
extra_args=None,
nsplit=1,
return_chi2fct=False):
if p0 is None:
p0 = self.p0
if verbose & (print_level > 1):
print('About to call Minuit with chi2:')
print(chi2)
print('Initial parameters, fixed and bounds:')
for i in range(len(p0)):
print(
'Param {0:}: init={1:6.2f} Fixed={2:} Range=[{3:6.3f}, {4:6.3f}]'
.format(i, p0[i], self.fixedpars[i], self.flatprior[i][0],
self.flatprior[i][1]))
self.fitresult_minuit = ft.do_minuit(self.xvals,
self.yvals,
self.covar,
p0,
functname=self.model,
fixpars=self.fixedpars,
rangepars=self.flatprior,
verbose=verbose,
chi2=self.chi2,
print_level=print_level,
ncallmax=ncallmax,
extra_args=extra_args,
nsplit=nsplit)
if len(self.fitresult_minuit[3]) == 0:
cov = np.diag(self.fitresult_minuit[2])
else:
cov = self.fitresult_minuit[3]
if return_chi2fct:
return self.fitresult_minuit[1], cov, self.fitresult_minuit[6]
else:
return self.fitresult_minuit[1], cov
def fit_sb(flatmap_init,
az_init,
el_init,
model,
newsize=70,
dmax=5.,
az_center=0.,
el_center=50.,
doplot=False,
resample=False,
verbose=False,
extra_title='',
return_fitted=False,
precision=None,
nsiglo=1.,
nsighi=3.,
figsave=None):
#### If requested, resample the iage in order to speedup the fitting
if resample:
### Resample input map to have less pixels to deal with for fitting
flatmap = scsig.resample(scsig.resample(flatmap_init, newsize, axis=0),
newsize,
axis=1)
az = np.linspace(np.min(az_init), np.max(az_init), newsize)
el = np.linspace(np.min(el_init), np.max(el_init), newsize)
else:
flatmap = flatmap_init
az = np.array(az_init)
el = np.array(el_init)
az2d, el2d = np.meshgrid(az * np.cos(np.radians(el_center)), np.flip(el))
# if verbose:
# print('fit_sb: Model Name = ',model.name)
# print('Initial Parameters:')
# model.print_start()
### First find the location of the maximum closest to the center
distance_max = dmax
mask = np.array(
np.sqrt((az2d - az_center)**2 +
(el2d - el_center)**2) < distance_max).astype(int)
### We use a smoothed version of the map in order to avoid glitches
smoothed_flatmap = f.gaussian_filter(flatmap, 2.)
wmax = np.where((smoothed_flatmap * mask) == np.max(smoothed_flatmap *
mask))
maxval = flatmap[wmax][0]
# print('Maximum of map is {0:5.2g} and was found at: az={1:5.2f}, el={2:5.2f}'.format(maxval,az2d[wmax][0], el2d[wmax][0]))
### Get the fixed parameters
fixpars = model.fixpars
### Create range for the fitting around the initial values
ranges = model.ranges.T
### Update initial parameters with the values found on the map
parsinit = model.startpars
parsinit[0] = az2d[wmax][0]
parsinit[1] = el2d[wmax][0]
parsinit[9] = maxval
if model.name == 'SbModelIndepPeaksAmp':
parsinit[9:] = maxval
ranges[9:, 1] = maxval * 2
elif model.name == 'SbModelIndepPeaksAmpFWHM':
for i in range(model.npeaks):
parsinit[9 + 2 * i] = maxval
ranges[9 + 2 * i, 1] = maxval * 2
elif model.name == 'SbModelIndepPeaks':
for i in range(model.npeaks):
parsinit[9 + 4 * i] = maxval
ranges[9 + 4 * i, 1] = np.abs(maxval) * 2
### Run the fitting
x = [az2d, el2d]
mm, ss = ft.meancut(flatmap, 3)
if verbose:
print('Running Minuit with model: {}'.format(model.name))
model.print_start()
mychi2 = ft.MyChi2_nocov(x, np.ravel(flatmap),
np.zeros_like(np.ravel(flatmap)) + ss, model)
fit = ft.do_minuit(x,
np.ravel(flatmap),
np.zeros_like(np.ravel(flatmap)) + ss,
parsinit,
functname=model,
chi2=mychi2,
rangepars=ranges,
fixpars=fixpars,
force_chi2_ndf=False,
verbose=False,
nohesse=True,
precision=precision)
fitpars = fit[1]
fiterrs = fit[2]
### Get the peaks positions and amplitudes
themap, newxxyy = model(x, fitpars, return_peaks=True)
### Put the fitted amplitude values to zero when needed (when peak ouside the input image)
if model.name == 'SbModelIndepPeaksAmp':
xmin = np.min(az2d)
xmax = np.max(az2d)
ymin = np.min(el2d)
ymax = np.max(el2d)
for i in range(model.npeaks):
if (((newxxyy[0, i] < xmin) or (newxxyy[0, i] > xmax))
or ((newxxyy[1, i] < ymin) or (newxxyy[1, i] > ymax))):
fitpars[9 + i] = 0
fiterrs[9 + i] = 0
### Now get the map again with updated parameters
themap, newxxyy = model(x, fitpars, return_peaks=True)
elif model.name == 'SbModelIndepPeaksAmpFWHM':
xmin = np.min(az2d)
xmax = np.max(az2d)
ymin = np.min(el2d)
ymax = np.max(el2d)
for i in range(model.npeaks):
if (((newxxyy[0, i] < xmin) or (newxxyy[0, i] > xmax))
or ((newxxyy[1, i] < ymin) or (newxxyy[1, i] > ymax))):
fitpars[9 + 2 * i] = 0
fiterrs[9 + 2 * i] = 0
### Now get the map again with updated parameters
themap, newxxyy = model(x, fitpars, return_peaks=True)
elif model.name == 'SbModelIndepPeaks':
xmin = np.min(az2d)
xmax = np.max(az2d)
ymin = np.min(el2d)
ymax = np.max(el2d)
for i in range(model.npeaks):
if (((newxxyy[0, i] < xmin) or (newxxyy[0, i] > xmax))
or ((newxxyy[1, i] < ymin) or (newxxyy[1, i] > ymax))):
fitpars[9 + 4 * i] = 0
fiterrs[9 + 4 * i] = 0
if verbose:
print('===========================================================')
print('Fitted values:')
print('-----------------------------------------------------------')
for i in range(len(parsinit)):
print('{0:<20}: {1:>12.6f} +/- {2:>12.6f}'.format(
model.parnames[i], fitpars[i], fiterrs[i]))
print('-----------------------------------------------------------')
print('Residuals**2/pix : {0:^8.5g}'.format(
np.sum((flatmap - themap)**2) / np.size(flatmap)))
print('===========================================================')
if doplot:
rc('figure', figsize=(18, 4))
sh = np.shape(newxxyy)
mm, ss = ft.meancut(flatmap, 3)
subplot(1, 4, 1)
imshow(themap,
extent=[
np.min(az) * np.cos(np.radians(50)),
np.max(az) * np.cos(np.radians(50)),
np.min(el),
np.max(el)
],
vmin=mm - ss,
vmax=mm + 10 * ss)
colorbar()
title('Fitted Map ' + extra_title)
xlabel('Angle in Az direction [deg.]')
ylabel('Elevation [deg.]')
mm, ss = ft.meancut(flatmap - themap, 3)
subplot(1, 4, 2)
imshow(flatmap,
extent=[
np.min(az) * np.cos(np.radians(50)),
np.max(az) * np.cos(np.radians(50)),
np.min(el),
np.max(el)
],
vmin=mm - nsiglo * ss,
vmax=mm + nsighi * ss)
xlim(
np.min(az) * np.cos(np.radians(50)),
np.max(az) * np.cos(np.radians(50)))
ylim(np.min(el), np.max(el))
colorbar()
for i in range(sh[1]):
ax = plot(newxxyy[0, i], newxxyy[1, i], 'r.')
title('Input Map ' + extra_title)
xlabel('Angle in Az direction [deg.]')
ylabel('Elevation [deg.]')
subplot(1, 4, 3)
imshow(themap,
extent=[
np.min(az) * np.cos(np.radians(50)),
np.max(az) * np.cos(np.radians(50)),
np.min(el),
np.max(el)
],
vmin=mm - nsiglo * ss,
vmax=mm + nsighi * ss)
colorbar()
title('Fitted Map ' + extra_title)
xlabel('Angle in Az direction [deg.]')
ylabel('Elevation [deg.]')
subplot(1, 4, 4)
imshow(flatmap - themap,
extent=[
np.min(az) * np.cos(np.radians(50)),
np.max(az) * np.cos(np.radians(50)),
np.min(el),
np.max(el)
],
vmin=mm - nsiglo * ss,
vmax=mm + nsighi * ss)
colorbar()
title('Residual Map ' + extra_title)
xlabel('Angle in Az direction [deg.]')
ylabel('Elevation [deg.]')
tight_layout()
if figsave:
savefig(figsave)
show()
if return_fitted:
return fit, newxxyy, themap
else:
return fit, newxxyy
# set values for fold plot
pars = [dc, 0.05, 0., 1.2]
# theTES=45
# plot folded TES data
FoldedFiltTES(tt, pars, theTES, folded, folded_notch)
### Plot it along with a guess for fiber signal
#### Now fit the fiber signal
#### NB errors come from renormalizing chi2/ndf to 1
guess = [dc, 0.06, 0., 1.2]
fit_info = ft.do_minuit(tt,
folded[theTES, :],
np.ones(len(tt)),
guess,
functname=ft.simsig,
rangepars=[[0., 1.], [0., 1], [0., 1], [0., 1]],
fixpars=[0, 0, 0, 0],
force_chi2_ndf=True,
verbose=False,
nohesse=True)
# plot the free fit
FoldedTESFreeFit(tt, fit_info, theTES, folded)
##################################################
# ## Now do a kind a multipass analysis where
# ## TES exhibiting nice signal are manually picked
# ## I tried an automated algorithm but it was not
# ## very satisfying...
# ## Running the following with the keyword
# ## reselect_ok = True
# ## will go through all TES and ask for a [y] if it
