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https://gitlab.science.ru.nl/mthesis-edeboone/m-thesis-introduction.git
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ZH: (WIP) fitting random phasor sum to antenna phases
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parent
1130f2c679
commit
103bde61f8
2 changed files with 78 additions and 12 deletions
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@ -206,7 +206,7 @@ if __name__ == "__main__":
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figsize=figsize,
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figsize=figsize,
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hist_kwargs=hist_kwargs,
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hist_kwargs=hist_kwargs,
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fit_gaussian=plot_residuals,
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fit_gaussian=plot_residuals,
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fit_ricianphase=plot_residuals,
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fit_randomphasesum=plot_residuals,
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return_fit_info = True,
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return_fit_info = True,
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)
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)
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@ -1,9 +1,35 @@
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import matplotlib.pyplot as plt
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import matplotlib.pyplot as plt
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import numpy as np
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import numpy as np
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import scipy.stats as stats
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from scipy import stats
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from scipy import special
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from scipy import optimize
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from itertools import zip_longest
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from itertools import zip_longest
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def expectation(x,pdfx):
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dx = x[1]-x[0]
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return np.sum(x*pdfx*dx)
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def variance(x,pdfx):
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mu = expectation(x,pdfx)
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dx = x[1]-x[0]
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return np.sum((x**2*pdfx*dx))-mu**2
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def random_phase_sum_distribution(theta, sigma, s=1):
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theta = np.asarray(theta)
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ct = np.cos(theta)
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st = np.sin(theta)
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k = s/sigma
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pipi = 2*np.pi
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return (np.exp(-k**2/2)/pipi) + (
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(pipi**-0.5)*k*np.exp(-(k*st)**2/2)) * (
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(1.+special.erf(k*ct*2**-0.5))*ct/2)
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def gaussian_phase_distribution(theta, sigma, s=1):
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theta = np.asarray(theta)
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k=s/sigma
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return (2*np.pi)**-0.5*k*np.exp(-(k*theta)**2/2)
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def phase_comparison_figure(
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def phase_comparison_figure(
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measured_phases,
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measured_phases,
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true_phases,
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true_phases,
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@ -16,6 +42,7 @@ def phase_comparison_figure(
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legend_on_scatter=True,
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legend_on_scatter=True,
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secondary_axis='time',
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secondary_axis='time',
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fit_gaussian=False,
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fit_gaussian=False,
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fit_randomphasesum=False,
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mean_snr=None,
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mean_snr=None,
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return_fit_info=False,
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return_fit_info=False,
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**fig_kwargs
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**fig_kwargs
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@ -29,14 +56,19 @@ def phase_comparison_figure(
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default_text_kwargs = dict(fontsize=14, verticalalignment='top')
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default_text_kwargs = dict(fontsize=14, verticalalignment='top')
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default_sc_kwargs = dict(alpha=0.6, ls='none')
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default_sc_kwargs = dict(alpha=0.6, ls='none')
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do_hist_plot = hist_kwargs is not False
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if hist_kwargs is False:
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hist_kwargs = {}
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do_scatter_plot = sc_kwargs is not False
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if sc_kwargs is False:
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sc_kwargs = {}
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fig_kwargs = {**default_fig_kwargs, **fig_kwargs}
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fig_kwargs = {**default_fig_kwargs, **fig_kwargs}
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hist_kwargs = {**default_hist_kwargs, **hist_kwargs}
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hist_kwargs = {**default_hist_kwargs, **hist_kwargs}
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text_kwargs = {**default_text_kwargs, **text_kwargs}
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text_kwargs = {**default_text_kwargs, **text_kwargs}
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sc_kwargs = {**default_sc_kwargs, **sc_kwargs}
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sc_kwargs = {**default_sc_kwargs, **sc_kwargs}
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do_hist_plot = hist_kwargs is not False
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do_scatter_plot = sc_kwargs is not False
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fig, axs = plt.subplots(0+do_hist_plot+do_scatter_plot, 1, **fig_kwargs)
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fig, axs = plt.subplots(0+do_hist_plot+do_scatter_plot, 1, **fig_kwargs)
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if not hasattr(axs, '__len__'):
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if not hasattr(axs, '__len__'):
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@ -67,10 +99,14 @@ def phase_comparison_figure(
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text_kwargs=text_kwargs,
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text_kwargs=text_kwargs,
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hist_kwargs={**hist_kwargs, **dict(label='Measured', color=colors[0], ls='solid')},
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hist_kwargs={**hist_kwargs, **dict(label='Measured', color=colors[0], ls='solid')},
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mean_snr=mean_snr,
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mean_snr=mean_snr,
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fit_distr=[],
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)
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)
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if fit_gaussian:
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if fit_gaussian:
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this_kwargs['fit_distr'] = 'gaussian'
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this_kwargs['fit_distr'].append('gaussian')
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if fit_randomphasesum:
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this_kwargs['fit_distr'].append('randomphasesum')
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_, fit_info = fitted_histogram_figure(
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_, fit_info = fitted_histogram_figure(
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measured_phases,
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measured_phases,
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@ -126,7 +162,7 @@ def fitted_histogram_figure(
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text_kwargs = {**default_text_kwargs, **text_kwargs}
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text_kwargs = {**default_text_kwargs, **text_kwargs}
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if ax is None:
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if ax is None:
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fig, ax = plt.subplots(1,1, **fig_kwargs)
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fig, ax = plt.subplots(1, 1, **fig_kwargs)
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else:
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else:
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fig = ax.get_figure()
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fig = ax.get_figure()
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@ -139,6 +175,8 @@ def fitted_histogram_figure(
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min_x = min(amplitudes)
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min_x = min(amplitudes)
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max_x = max(amplitudes)
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max_x = max(amplitudes)
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bin_centers = bins[:-1] + np.diff(bins) / 2
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dx = bins[1] - bins[0]
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dx = bins[1] - bins[0]
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scale = len(amplitudes) * dx
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scale = len(amplitudes) * dx
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@ -146,6 +184,9 @@ def fitted_histogram_figure(
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for distr in fit_distr:
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for distr in fit_distr:
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fit_params2text_params = lambda x: x
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fit_params2text_params = lambda x: x
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fit_ys = None
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fit_params = None
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cdf = None
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if 'rice' == distr:
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if 'rice' == distr:
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name = "Rice"
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name = "Rice"
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@ -166,19 +207,44 @@ def fitted_histogram_figure(
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fit_params2text_params = lambda x: (x[0]+x[1]/2,)
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fit_params2text_params = lambda x: (x[0]+x[1]/2,)
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elif 'randomphasesum' == distr:
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name = "RandPhaseS"
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param_names = [ "$\\sigma$", 's']
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pdf = random_phase_sum_distribution
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bounds = ((0,0.9999), (np.inf,1))
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fit_params, pcov = optimize.curve_fit(pdf, bin_centers, counts, bounds=bounds)
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fit_ys = pdf( xs, *fit_params)
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fit_params2text_params = lambda x: (x[1], x[0])
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elif 'gaussphase' == distr:
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name = 'GaussPhase'
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param_names = [ "$\\sigma$", 's']
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pdf = gaussian_phase_distribution
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bounds = ((0,0.9999), (np.inf,1))
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fit_params, pcov = optimize.curve_fit(pdf, bin_centers, counts, bounds=bounds)
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fit_ys = pdf( xs, *fit_params)
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fit_params2text_params = lambda x: (x[1], x[0])
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else:
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else:
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raise ValueError('Unknown distribution function '+distr)
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raise ValueError('Unknown distribution function '+distr)
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label = name +"(" + ','.join(param_names) + ')'
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label = name +"(" + ','.join(param_names) + ')'
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if fit_ys is None:
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fit_params = distr_func.fit(amplitudes)
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fit_params = distr_func.fit(amplitudes)
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fit_ys = distr_func.pdf(xs, *fit_params)
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fit_ys = scale * distr_func.pdf(xs, *fit_params)
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cdf = distr_func.cdf
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ax.plot(xs, fit_ys*scale, label=label)
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ax.plot(xs, fit_ys, label=label)
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chisq_strs = []
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chisq_strs = []
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if calc_chisq:
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if calc_chisq and cdf:
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ct = np.diff(distr_func.cdf(bins, *fit_params))*np.sum(counts)
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ct = np.diff(cdf(bins, *fit_params))*np.sum(counts)
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c2t = stats.chisquare(counts, ct, ddof=len(fit_params))
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c2t = stats.chisquare(counts, ct, ddof=len(fit_params))
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chisq_strs = [
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chisq_strs = [
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f"$\\chi^2$/dof = {c2t[0]: .2g}/{len(fit_params)}"
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f"$\\chi^2$/dof = {c2t[0]: .2g}/{len(fit_params)}"
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