1210 lines
47 KiB
Python
1210 lines
47 KiB
Python
import numpy as np
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from uncertainties import ufloat
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import lmfit
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from lmfit.models import (ConstantModel, ComplexConstantModel, LinearModel, QuadraticModel,
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PolynomialModel, SineModel, GaussianModel, Gaussian2dModel, LorentzianModel,
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SplitLorentzianModel, VoigtModel, PseudoVoigtModel, MoffatModel,
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Pearson7Model, StudentsTModel, BreitWignerModel, LognormalModel,
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DampedOscillatorModel, ExponentialGaussianModel, SkewedGaussianModel,
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SkewedVoigtModel, ThermalDistributionModel, DoniachModel, PowerLawModel,
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ExponentialModel, StepModel, RectangleModel, ExpressionModel, DampedHarmonicOscillatorModel)
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from lmfit.models import (guess_from_peak, guess_from_peak2d, fwhm_expr, height_expr,
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update_param_vals)
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from lmfit.lineshapes import (not_zero, breit_wigner, damped_oscillator, dho, doniach,
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expgaussian, exponential, gaussian, gaussian2d,
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linear, lognormal, lorentzian, moffat, parabolic,
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pearson7, powerlaw, pvoigt, rectangle, sine,
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skewed_gaussian, skewed_voigt, split_lorentzian, step,
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students_t, thermal_distribution, tiny, voigt)
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from lmfit import Model
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import numpy as np
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from numpy import (arctan, copysign, cos, exp, isclose, isnan, log, pi, real,
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sin, sqrt, where)
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from scipy.special import erf, erfc
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from scipy.special import gamma as gamfcn
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from scipy.special import wofz
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from scipy.optimize import curve_fit
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import xarray as xr
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import copy
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log2 = log(2)
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s2pi = sqrt(2*pi)
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s2 = sqrt(2.0)
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def gaussianWithOffset(x, amplitude=1.0, center=0.0, sigma=1.0, offset=0.0):
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"""Return a 1-dimensional Gaussian function with an offset.
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gaussian(x, amplitude, center, sigma) =
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(amplitude/(s2pi*sigma)) * exp(-(1.0*x-center)**2 / (2*sigma**2))
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"""
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return ((amplitude/(max(tiny, s2pi*sigma)))
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* exp(-(1.0*x-center)**2 / max(tiny, (2*sigma**2))) + offset)
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def lorentzianWithOffset(x, amplitude=1.0, center=0.0, sigma=1.0, offset=0.0):
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return ((amplitude/(1 + ((1.0*x-center)/max(tiny, sigma))**2))
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/ max(tiny, (pi*sigma)) + offset)
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def exponentialWithOffset(x, amplitude=1.0, decay=1.0, offset=0.0):
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decay = not_zero(decay)
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return amplitude * exp(-x/decay) + offset
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def expansion(x, amplitude=1.0, offset=0.0):
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return np.sqrt(amplitude*x*x + offset)
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def dampingOscillation(x, center=0, amplitude=1.0, frequency=1.0, decay=1.0, offset=0.0):
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return amplitude * np.exp(-decay*x)*np.sin(2*np.pi*frequency*(x-center)) + offset
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def two_gaussian2d(x, y=0.0, A_amplitude=1.0, A_centerx=0.0, A_centery=0.0, A_sigmax=1.0,
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A_sigmay=1.0, B_amplitude=1.0, B_centerx=0.0, B_centery=0.0, B_sigmax=1.0,
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B_sigmay=1.0):
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"""Return a 2-dimensional Gaussian function.
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gaussian2d(x, y, amplitude, centerx, centery, sigmax, sigmay) =
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amplitude/(2*pi*sigmax*sigmay) * exp(-(x-centerx)**2/(2*sigmax**2)
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-(y-centery)**2/(2*sigmay**2))
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"""
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z = A_amplitude*(gaussian(x, amplitude=1, center=A_centerx, sigma=A_sigmax) *
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gaussian(y, amplitude=1, center=A_centery, sigma=A_sigmay))
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z += B_amplitude*(gaussian(x, amplitude=1, center=B_centerx, sigma=B_sigmax) *
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gaussian(y, amplitude=1, center=B_centery, sigma=B_sigmay))
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return z
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def ThomasFermi_2d(x, y=0.0, centerx=0.0, centery=0.0, amplitude=1.0, sigmax=1.0, sigmay=1.0):
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res = (1- ((x-centerx)/(sigmax))**2 - ((y-centery)/(sigmay))**2)**(3 / 2)
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return amplitude * 5 / 2 / np.pi / max(tiny, sigmax * sigmay) * np.where(res > 0, res, 0)
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def polylog(power, numerator):
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order = 2
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dataShape = numerator.shape
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numerator = np.tile(numerator, (order, 1))
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numerator = np.power(numerator.T, np.arange(1, order+1)).T
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denominator = np.arange(1, order+1)
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denominator = np.tile(denominator, (dataShape[0], 1))
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denominator = denominator.T
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data = numerator/ np.power(denominator, power)
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return np.sum(data, axis=0)
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def polylog2_2d(x, y=0.0, centerx=0.0, centery=0.0, amplitude=1.0, sigmax=1.0, sigmay=1.0):
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## Approximation of the polylog function with 2D gaussian as argument. -> discribes the thermal part of the cloud
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return amplitude / 2 / np.pi / 1.20206 / max(tiny, sigmax * sigmay) * polylog(2, np.exp( -((x-centerx)**2/(2 * (sigmax)**2))-((y-centery)**2/( 2 * (sigmay)**2)) ))
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def density_profile_BEC_2d(x, y=0.0, BEC_amplitude=1.0, thermal_amplitude=1.0, BEC_centerx=0.0, BEC_centery=0.0, thermal_centerx=0.0, thermal_centery=0.0,
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BEC_sigmax=1.0, BEC_sigmay=1.0, thermal_sigmax=1.0, thermal_sigmay=1.0):
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return ThomasFermi_2d(x=x, y=y, centerx=BEC_centerx, centery=BEC_centery,
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amplitude=BEC_amplitude, sigmax=BEC_sigmax, sigmay=BEC_sigmay
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) + polylog2_2d(x=x, y=y, centerx=thermal_centerx, centery=thermal_centery,
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amplitude=thermal_amplitude, sigmax=thermal_sigmax, sigmay=thermal_sigmay)
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class GaussianWithOffsetModel(Model):
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fwhm_factor = 2*np.sqrt(2*np.log(2))
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height_factor = 1./np.sqrt(2*np.pi)
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def __init__(self, independent_vars=['x'], nan_policy='raise', prefix='', name=None, **kwargs):
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kwargs.update({'prefix': prefix, 'nan_policy': nan_policy,
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'independent_vars': independent_vars})
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super().__init__(gaussianWithOffset, **kwargs)
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self._set_paramhints_prefix()
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def _set_paramhints_prefix(self):
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self.set_param_hint('sigma', min=0)
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self.set_param_hint('fwhm', expr=fwhm_expr(self))
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self.set_param_hint('height', expr=height_expr(self))
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def guess(self, data, x, negative=False, **kwargs):
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offset = np.min(data)
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data = data - offset
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pars = guess_from_peak(self, data, x, negative)
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pars.add('offset', value=offset)
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return update_param_vals(pars, self.prefix, **kwargs)
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class LorentzianWithOffsetModel(Model):
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fwhm_factor = 2.0
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height_factor = 1./np.pi
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def __init__(self, independent_vars=['x'], prefix='', nan_policy='raise',
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**kwargs):
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kwargs.update({'prefix': prefix, 'nan_policy': nan_policy,
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'independent_vars': independent_vars})
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super().__init__(lorentzianWithOffset, **kwargs)
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self._set_paramhints_prefix()
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def _set_paramhints_prefix(self):
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self.set_param_hint('sigma', min=0)
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self.set_param_hint('fwhm', expr=fwhm_expr(self))
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self.set_param_hint('height', expr=height_expr(self))
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def guess(self, data, x, negative=False, **kwargs):
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"""Estimate initial model parameter values from data."""
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offset = np.min(data)
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data = data - offset
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pars = guess_from_peak(self, data, x, negative, ampscale=1.25)
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pars.add('offset', value=offset)
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return update_param_vals(pars, self.prefix, **kwargs)
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class ExponentialWithOffsetModel(Model):
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def __init__(self, independent_vars=['x'], prefix='', nan_policy='raise',
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**kwargs):
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kwargs.update({'prefix': prefix, 'nan_policy': nan_policy,
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'independent_vars': independent_vars})
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super().__init__(exponentialWithOffset, **kwargs)
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def guess(self, data, x, **kwargs):
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"""Estimate initial model parameter values from data."""
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offset = np.min(data)
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data = data - offset
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try:
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sval, oval = np.polyfit(x, np.log(abs(data)+1.e-15), 1)
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except TypeError:
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sval, oval = 1., np.log(abs(max(data)+1.e-9))
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pars = self.make_params(amplitude=np.exp(oval), decay=-1.0/sval)
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pars.add('offset', value=offset)
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return update_param_vals(pars, self.prefix, **kwargs)
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class ExpansionModel(Model):
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def __init__(self, independent_vars=['x'], prefix='', nan_policy='raise',
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**kwargs):
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kwargs.update({'prefix': prefix, 'nan_policy': nan_policy,
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'independent_vars': independent_vars})
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super().__init__(expansion, **kwargs)
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def guess(self, data, x, **kwargs):
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"""Estimate initial model parameter values from data."""
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popt1, pcov1 = curve_fit(expansion, x, data)
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pars = self.make_params(amplitude=popt1[0], offset=popt1[1])
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return update_param_vals(pars, self.prefix, **kwargs)
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class DampingOscillationModel(Model):
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def __init__(self, independent_vars=['x'], prefix='', nan_policy='raise',
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**kwargs):
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kwargs.update({'prefix': prefix, 'nan_policy': nan_policy,
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'independent_vars': independent_vars})
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super().__init__(dampingOscillation, **kwargs)
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def guess(self, data, x, **kwargs):
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"""Estimate initial model parameter values from data."""
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try:
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popt1, pcov1 = curve_fit(dampingOscillation, x, data, np.array(0, 5, 5e2, 1e3, 16))
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pars = self.make_params(center=popt1[0], amplitude=popt1[1], frequency=popt1[2], decay=popt1[3], offset=popt1[4])
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except:
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pars = self.make_params(center=0, amplitude=5.0, frequency=5e2, decay=1.0e3, offset=16.0)
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return update_param_vals(pars, self.prefix, **kwargs)
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class TwoGaussian2dModel(Model):
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fwhm_factor = 2*np.sqrt(2*np.log(2))
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height_factor = 1./2*np.pi
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def __init__(self, independent_vars=['x', 'y'], prefix='', nan_policy='raise',
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**kwargs):
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kwargs.update({'prefix': prefix, 'nan_policy': nan_policy,
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'independent_vars': independent_vars})
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self.helperModel = Gaussian2dModel()
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super().__init__(two_gaussian2d, **kwargs)
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self._set_paramhints_prefix()
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def _set_paramhints_prefix(self):
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self.set_param_hint('delta', value=-1, max=0)
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self.set_param_hint('A_sigmax', expr=f'{self.prefix}delta + {self.prefix}B_sigmax')
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def guess(self, data, x, y, negative=False, **kwargs):
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pars_guess = guess_from_peak2d(self.helperModel, data, x, y, negative)
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pars = self.make_params(A_amplitude=pars_guess['amplitude'].value, A_centerx=pars_guess['centerx'].value, A_centery=pars_guess['centery'].value,
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A_sigmax=pars_guess['sigmax'].value, A_sigmay=pars_guess['sigmay'].value,
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B_amplitude=pars_guess['amplitude'].value, B_centerx=pars_guess['centerx'].value, B_centery=pars_guess['centery'].value,
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B_sigmax=pars_guess['sigmax'].value, B_sigmay=pars_guess['sigmay'].value)
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pars[f'{self.prefix}A_sigmax'].set(expr=f'delta + {self.prefix}B_sigmax')
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pars.add(f'{self.prefix}delta', value=-1, max=0, min=-np.inf, vary=True)
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pars[f'{self.prefix}A_sigmay'].set(min=0.0)
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pars[f'{self.prefix}B_sigmax'].set(min=0.0)
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pars[f'{self.prefix}B_sigmay'].set(min=0.0)
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return pars
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class Polylog22dModel(Model):
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fwhm_factor = 2*np.sqrt(2*np.log(2))
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height_factor = 1./2*np.pi
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def __init__(self, independent_vars=['x', 'y'], prefix='', nan_policy='raise',
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**kwargs):
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kwargs.update({'prefix': prefix, 'nan_policy': nan_policy,
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'independent_vars': independent_vars})
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super().__init__(polylog2_2d, **kwargs)
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self._set_paramhints_prefix()
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def _set_paramhints_prefix(self):
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self.set_param_hint('Rx', min=0)
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self.set_param_hint('Ry', min=0)
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def guess(self, data, x, y, negative=False, **kwargs):
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"""Estimate initial model parameter values from data."""
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pars = guess_from_peak2d(self, data, x, y, negative)
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return update_param_vals(pars, self.prefix, **kwargs)
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class ThomasFermi2dModel(Model):
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fwhm_factor = 1
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height_factor = 0.5
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def __init__(self, independent_vars=['x', 'y'], prefix='', nan_policy='raise',
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**kwargs):
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kwargs.update({'prefix': prefix, 'nan_policy': nan_policy,
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'independent_vars': independent_vars})
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super().__init__(ThomasFermi_2d, **kwargs)
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self._set_paramhints_prefix()
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def _set_paramhints_prefix(self):
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self.set_param_hint('Rx', min=0)
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self.set_param_hint('Ry', min=0)
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def guess(self, data, x, y, negative=False, **kwargs):
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"""Estimate initial model parameter values from data."""
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pars = guess_from_peak2d(self, data, x, y, negative)
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# amplitude = pars['amplitude'].value
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# simgax = pars['sigmax'].value
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# sigmay = pars['sigmay'].value
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# pars['amplitude'].set(value=amplitude/s2pi/simgax/sigmay)
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simgax = pars['sigmax'].value
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sigmay = pars['sigmay'].value
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pars['simgax'].set(value=simgax / 2.355)
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pars['sigmay'].set(value=sigmay / 2.355)
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return update_param_vals(pars, self.prefix, **kwargs)
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class DensityProfileBEC2dModel(Model):
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fwhm_factor = 2*np.sqrt(2*np.log(2))
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height_factor = 1./2*np.pi
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def __init__(self, independent_vars=['x', 'y'], prefix='', nan_policy='raise',
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**kwargs):
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kwargs.update({'prefix': prefix, 'nan_policy': nan_policy,
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'independent_vars': independent_vars})
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super().__init__(density_profile_BEC_2d, **kwargs)
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self._set_paramhints_prefix()
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def _set_paramhints_prefix(self):
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# self.set_param_hint('BEC_sigmax', min=0)
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self.set_param_hint('deltax', min=0)
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self.set_param_hint('BEC_sigmax', expr=f'3 * {self.prefix}thermal_sigmax - {self.prefix}deltax')
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self.set_param_hint('BEC_sigmay', min=0)
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self.set_param_hint('thermal_sigmax', min=0)
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# self.set_param_hint('thermal_sigmay', min=0)
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self.set_param_hint('BEC_amplitude', min=0)
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self.set_param_hint('thermal_amplitude', min=0)
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self.set_param_hint('thermalAspectRatio', min=0.8, max=1.2)
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self.set_param_hint('thermal_sigmay', expr=f'{self.prefix}thermalAspectRatio * {self.prefix}thermal_sigmax')
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# self.set_param_hint('betax', value=0)
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# self.set_param_hint('BEC_centerx', expr=f'{self.prefix}thermal_sigmax - {self.prefix}betax')
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self.set_param_hint('condensate_fraction', expr=f'{self.prefix}BEC_amplitude / ({self.prefix}BEC_amplitude + {self.prefix}thermal_amplitude)')
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def guess(self, data, x, y, negative=False, pureBECThreshold=0.5, noBECThThreshold=0.0, **kwargs):
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"""Estimate initial model parameter values from data."""
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fitModel = TwoGaussian2dModel()
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pars = fitModel.guess(data, x=x, y=y, negative=negative)
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pars['A_amplitude'].set(min=0)
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pars['B_amplitude'].set(min=0)
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pars['A_centerx'].set(min=pars['A_centerx'].value - 3 * pars['A_sigmax'],
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max=pars['A_centerx'].value + 3 * pars['A_sigmax'],)
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pars['A_centery'].set(min=pars['A_centery'].value - 3 * pars['A_sigmay'],
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max=pars['A_centery'].value + 3 * pars['A_sigmay'],)
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pars['B_centerx'].set(min=pars['B_centerx'].value - 3 * pars['B_sigmax'],
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max=pars['B_centerx'].value + 3 * pars['B_sigmax'],)
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pars['B_centery'].set(min=pars['B_centery'].value - 3 * pars['B_sigmay'],
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max=pars['B_centery'].value + 3 * pars['B_sigmay'],)
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fitResult = fitModel.fit(data, x=x, y=y, params=pars, **kwargs)
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pars_guess = fitResult.params
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BEC_amplitude = pars_guess['A_amplitude'].value
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thermal_amplitude = pars_guess['B_amplitude'].value
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pars = self.make_params(BEC_amplitude=BEC_amplitude,
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thermal_amplitude=thermal_amplitude,
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BEC_centerx=pars_guess['A_centerx'].value, BEC_centery=pars_guess['A_centery'].value,
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# BEC_sigmax=(pars_guess['A_sigmax'].value / 2.355),
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deltax = 3 * (pars_guess['B_sigmax'].value * s2) - (pars_guess['A_sigmax'].value / 2.355),
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BEC_sigmay=(pars_guess['A_sigmay'].value / 2.355),
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thermal_centerx=pars_guess['B_centerx'].value, thermal_centery=pars_guess['B_centery'].value,
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thermal_sigmax=(pars_guess['B_sigmax'].value * s2),
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thermalAspectRatio=(pars_guess['B_sigmax'].value * s2) / (pars_guess['B_sigmay'].value * s2)
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# thermal_sigmay=(pars_guess['B_sigmay'].value * s2)
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)
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nBEC = pars[f'{self.prefix}BEC_amplitude'] / 2 / np.pi / 5.546 / pars[f'{self.prefix}BEC_sigmay'] / pars[f'{self.prefix}BEC_sigmax']
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if (pars[f'{self.prefix}condensate_fraction']>0.95) and (np.max(data) > 1.05 * nBEC):
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temp = ((np.max(data) - nBEC) * s2pi * pars[f'{self.prefix}thermal_sigmay'] / pars[f'{self.prefix}thermal_sigmax'])
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if temp > pars[f'{self.prefix}BEC_amplitude']:
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pars[f'{self.prefix}thermal_amplitude'].set(value=pars[f'{self.prefix}BEC_amplitude'] / 2)
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else:
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pars[f'{self.prefix}thermal_amplitude'].set(value=temp * 10)
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if BEC_amplitude / (thermal_amplitude + BEC_amplitude) > pureBECThreshold:
|
|
pars[f'{self.prefix}thermal_amplitude'].set(value=0)
|
|
pars[f'{self.prefix}BEC_amplitude'].set(value=(thermal_amplitude + BEC_amplitude))
|
|
|
|
if BEC_amplitude / (thermal_amplitude + BEC_amplitude) < noBECThThreshold:
|
|
pars[f'{self.prefix}BEC_amplitude'].set(value=0)
|
|
pars[f'{self.prefix}thermal_amplitude'].set(value=(thermal_amplitude + BEC_amplitude))
|
|
|
|
pars[f'{self.prefix}BEC_centerx'].set(
|
|
min=pars[f'{self.prefix}BEC_centerx'].value - 10 * pars[f'{self.prefix}BEC_sigmax'].value,
|
|
max=pars[f'{self.prefix}BEC_centerx'].value + 10 * pars[f'{self.prefix}BEC_sigmax'].value,
|
|
)
|
|
|
|
pars[f'{self.prefix}thermal_centerx'].set(
|
|
min=pars[f'{self.prefix}thermal_centerx'].value - 3 * pars[f'{self.prefix}thermal_sigmax'].value,
|
|
max=pars[f'{self.prefix}thermal_centerx'].value + 3 * pars[f'{self.prefix}thermal_sigmax'].value,
|
|
)
|
|
|
|
pars[f'{self.prefix}BEC_centery'].set(
|
|
min=pars[f'{self.prefix}BEC_centery'].value - 10 * pars[f'{self.prefix}BEC_sigmay'].value,
|
|
max=pars[f'{self.prefix}BEC_centery'].value + 10 * pars[f'{self.prefix}BEC_sigmay'].value,
|
|
)
|
|
|
|
pars[f'{self.prefix}thermal_centery'].set(
|
|
min=pars[f'{self.prefix}thermal_centery'].value - 3 * pars[f'{self.prefix}thermal_sigmay'].value,
|
|
max=pars[f'{self.prefix}thermal_centery'].value + 3 * pars[f'{self.prefix}thermal_sigmay'].value,
|
|
)
|
|
|
|
pars[f'{self.prefix}BEC_sigmay'].set(
|
|
max=5 * pars[f'{self.prefix}BEC_sigmay'].value,
|
|
)
|
|
|
|
pars[f'{self.prefix}thermal_sigmax'].set(
|
|
max=5 * pars[f'{self.prefix}thermal_sigmax'].value,
|
|
)
|
|
|
|
return update_param_vals(pars, self.prefix, **kwargs)
|
|
|
|
|
|
class NewFitModel(Model):
|
|
|
|
def __init__(self, func, independent_vars=['x'], prefix='', nan_policy='raise',
|
|
**kwargs):
|
|
kwargs.update({'prefix': prefix, 'nan_policy': nan_policy,
|
|
'independent_vars': independent_vars})
|
|
|
|
super().__init__(func, **kwargs)
|
|
|
|
def guess(self, *args, **kwargs):
|
|
return self.make_params()
|
|
|
|
|
|
lmfit_models = {'Constant': ConstantModel,
|
|
'Complex Constant': ComplexConstantModel,
|
|
'Linear': LinearModel,
|
|
'Quadratic': QuadraticModel,
|
|
'Polynomial': PolynomialModel,
|
|
'Gaussian': GaussianModel,
|
|
'Gaussian-2D': Gaussian2dModel,
|
|
'Lorentzian': LorentzianModel,
|
|
'Split-Lorentzian': SplitLorentzianModel,
|
|
'Voigt': VoigtModel,
|
|
'PseudoVoigt': PseudoVoigtModel,
|
|
'Moffat': MoffatModel,
|
|
'Pearson7': Pearson7Model,
|
|
'StudentsT': StudentsTModel,
|
|
'Breit-Wigner': BreitWignerModel,
|
|
'Log-Normal': LognormalModel,
|
|
'Damped Oscillator': DampedOscillatorModel,
|
|
'Damped Harmonic Oscillator': DampedHarmonicOscillatorModel,
|
|
'Exponential Gaussian': ExponentialGaussianModel,
|
|
'Skewed Gaussian': SkewedGaussianModel,
|
|
'Skewed Voigt': SkewedVoigtModel,
|
|
'Thermal Distribution': ThermalDistributionModel,
|
|
'Doniach': DoniachModel,
|
|
'Power Law': PowerLawModel,
|
|
'Exponential': ExponentialModel,
|
|
'Step': StepModel,
|
|
'Rectangle': RectangleModel,
|
|
'Expression': ExpressionModel,
|
|
'Gaussian With Offset':GaussianWithOffsetModel,
|
|
'Lorentzian With Offset':LorentzianWithOffsetModel,
|
|
'Expansion':ExpansionModel,
|
|
'Damping Oscillation Model':DampingOscillationModel,
|
|
'Two Gaussian-2D':TwoGaussian2dModel,
|
|
'Thomas Fermi-2D': ThomasFermi2dModel,
|
|
'Density Profile of BEC-2D': DensityProfileBEC2dModel,
|
|
'Polylog2-2D': polylog2_2d,
|
|
}
|
|
|
|
|
|
class FitAnalyser():
|
|
"""This is a class integrated all the functions to do a fit.
|
|
"""
|
|
|
|
def __init__(self, fitModel, fitDim=1, **kwargs) -> None:
|
|
"""Initialize function
|
|
|
|
:param fitModel: The fitting model of fit function
|
|
:type fitModel: lmfit Model
|
|
:param fitDim: The dimension of the fit, defaults to 1
|
|
:type fitDim: int, optional
|
|
"""
|
|
|
|
if isinstance(fitModel, str):
|
|
self.fitModel = lmfit_models[fitModel](**kwargs)
|
|
else:
|
|
self.fitModel = fitModel
|
|
|
|
self.fitDim = fitDim
|
|
|
|
def print_params_set_template(self, params=None):
|
|
"""Print a template to manually set the initial parameters of the fit
|
|
|
|
:param params: An object of Parameters class to print, defaults to None
|
|
:type params: lmfit Paraemters, optional
|
|
"""
|
|
|
|
if params is None:
|
|
params = self.fitModel.make_params()
|
|
|
|
for key in params:
|
|
res = "params.add("
|
|
res += "name=\"" + key + "\", "
|
|
if not params[key].expr is None:
|
|
res += "expr=\"" + params[key].expr +"\")"
|
|
else:
|
|
res += "value=" + f'{params[key].value:3g}' + ", "
|
|
if str(params[key].max)=="inf":
|
|
res += "max=np.inf, "
|
|
else:
|
|
res += "max=" + f'{params[key].max:3g}' + ", "
|
|
if str(params[key].min)=="-inf":
|
|
res += "min=-np.inf, "
|
|
else:
|
|
res += "min=" + f'{params[key].min:3g}' + ", "
|
|
res += "vary=" + str(params[key].vary) + ")"
|
|
print(res)
|
|
|
|
def _guess_1D(self, data, x, **kwargs):
|
|
"""Call the guess function of the 1D fit model to guess the initial value.
|
|
|
|
:param data: The data to fit
|
|
:type data: 1D numpy array
|
|
:param x: The data of x axis
|
|
:type x: 1D numpy array
|
|
:return: The guessed initial parameters for the fit
|
|
:rtype: lmfit Parameters
|
|
"""
|
|
return self.fitModel.guess(data=data, x=x, **kwargs)
|
|
|
|
def _guess_2D(self, data, x, y, **kwargs):
|
|
"""Call the guess function of the 2D fit model to guess the initial value.
|
|
|
|
:param data: The flattened data to fit
|
|
:type data: 1D numpy array
|
|
:param x: The flattened data of x axis
|
|
:type x: 1D numpy array
|
|
:param y: The flattened data of y axis
|
|
:type y: 1D numpy array
|
|
:return: The guessed initial parameters for the fit
|
|
:rtype: lmfit Parameters
|
|
"""
|
|
data = data.flatten(order='F')
|
|
return self.fitModel.guess(data=data, x=x, y=y, **kwargs)
|
|
|
|
def guess(self, dataArray, x=None, y=None, guess_kwargs={}, input_core_dims=None, dask='parallelized', vectorize=True, keep_attrs=True, daskKwargs=None, **kwargs):
|
|
"""Call the guess function of the fit model to guess the initial value.
|
|
|
|
:param dataArray: The data for the fit
|
|
:type dataArray: xarray DataArray
|
|
:param x: The name of x axis in data or the data of x axis, defaults to None
|
|
:type x: str or numpy array, optional
|
|
:param y: The name of y axis in data or the data of y axis, defaults to None
|
|
:type y: str or numpy array, optional
|
|
:param guess_kwargs: the keyworded arguments to send to the guess function, defaults to {}
|
|
:type guess_kwargs: dict, optional
|
|
:param input_core_dims: over write of the same argument in xarray.apply_ufunc, defaults to None
|
|
:type input_core_dims: list or array like, optional
|
|
:param dask: over write of the same argument in xarray.apply_ufunc,, defaults to 'parallelized'
|
|
:type dask: str, optional
|
|
:param vectorize: over write of the same argument in xarray.apply_ufunc, defaults to True
|
|
:type vectorize: bool, optional
|
|
:param keep_attrs: over write of the same argument in xarray.apply_ufunc, defaults to True
|
|
:type keep_attrs: bool, optional
|
|
:param daskKwargs: over write of the same argument in xarray.apply_ufunc, defaults to None
|
|
:type daskKwargs: dict, optional
|
|
:return: The guessed initial parameters for the fit
|
|
:rtype: xarray DataArray
|
|
"""
|
|
|
|
kwargs.update(
|
|
{
|
|
"dask": dask,
|
|
"vectorize": vectorize,
|
|
"input_core_dims": input_core_dims,
|
|
'keep_attrs': keep_attrs,
|
|
|
|
}
|
|
)
|
|
|
|
if not daskKwargs is None:
|
|
kwargs.update({"dask_gufunc_kwargs": daskKwargs})
|
|
|
|
if input_core_dims is None:
|
|
kwargs.update(
|
|
{
|
|
"input_core_dims": [['x']],
|
|
}
|
|
)
|
|
|
|
if x is None:
|
|
if 'x' in dataArray.dims:
|
|
x = dataArray['x'].to_numpy()
|
|
else:
|
|
if isinstance(x, str):
|
|
if input_core_dims is None:
|
|
kwargs.update(
|
|
{
|
|
"input_core_dims": [[x]],
|
|
}
|
|
)
|
|
x = dataArray[x].to_numpy()
|
|
|
|
if self.fitDim == 1:
|
|
|
|
guess_kwargs.update(
|
|
{
|
|
'x':x,
|
|
}
|
|
)
|
|
|
|
return xr.apply_ufunc(self._guess_1D, dataArray, kwargs=guess_kwargs,
|
|
output_dtypes=[type(self.fitModel.make_params())],
|
|
**kwargs
|
|
)
|
|
|
|
if self.fitDim == 2:
|
|
|
|
if y is None:
|
|
if 'y' in dataArray.dims:
|
|
y = dataArray['y'].to_numpy()
|
|
if input_core_dims is None:
|
|
kwargs.update(
|
|
{
|
|
"input_core_dims": [['x', 'y']],
|
|
}
|
|
)
|
|
else:
|
|
if isinstance(y, str):
|
|
kwargs["input_core_dims"][0] = np.append(kwargs["input_core_dims"][0], y)
|
|
y = dataArray[y].to_numpy()
|
|
elif input_core_dims is None:
|
|
kwargs.update(
|
|
{
|
|
"input_core_dims": [['x', 'y']],
|
|
}
|
|
)
|
|
|
|
_x, _y = np.meshgrid(x, y)
|
|
_x = _x.flatten()
|
|
_y = _y.flatten()
|
|
|
|
# dataArray = dataArray.stack(_z=(kwargs["input_core_dims"][0][0], kwargs["input_core_dims"][0][1]))
|
|
|
|
# kwargs["input_core_dims"][0] = ['_z']
|
|
|
|
guess_kwargs.update(
|
|
{
|
|
'x':_x,
|
|
'y':_y,
|
|
}
|
|
)
|
|
|
|
return xr.apply_ufunc(self._guess_2D, dataArray, kwargs=guess_kwargs,
|
|
output_dtypes=[type(self.fitModel.make_params())],
|
|
**kwargs
|
|
)
|
|
|
|
def _fit_1D(self, data, params, x):
|
|
"""Call the fit function of the 1D fit model to do the fit.
|
|
|
|
:param data: The data to fit
|
|
:type data: 1D numpy array
|
|
:param params: The initial paramters of the fit
|
|
:type params: lmfit Parameters
|
|
:param x: The data of x axis
|
|
:type x: 1D numpy array
|
|
:return: The result of the fit
|
|
:rtype: lmfit FitResult
|
|
"""
|
|
return self.fitModel.fit(data=data, x=x, params=params, nan_policy='omit')
|
|
|
|
def _fit_2D(self, data, params, x, y):
|
|
"""Call the fit function of the 2D fit model to do the fit.
|
|
|
|
:param data: The flattened data to fit
|
|
:type data: 1D numpy array
|
|
:param params: The flattened initial paramters of the fit
|
|
:type params: lmfit Parameters
|
|
:param x: The flattened data of x axis
|
|
:type x: 1D numpy array
|
|
:param y: The flattened data of y axis
|
|
:type y: 1D numpy array
|
|
:return: The result of the fit
|
|
:rtype: lmfit FitResult
|
|
"""
|
|
data = data.flatten(order='F')
|
|
return self.fitModel.fit(data=data, x=x, y=y, params=params, nan_policy='omit')
|
|
|
|
def fit(self, dataArray, paramsArray, x=None, y=None, input_core_dims=None, dask='parallelized', vectorize=True, keep_attrs=True, daskKwargs=None, **kwargs):
|
|
"""Call the fit function of the fit model to do the fit.
|
|
|
|
:param dataArray: The data for the fit
|
|
:type dataArray: xarray DataArray
|
|
:param paramsArray: The flattened initial paramters of the fit
|
|
:type paramsArray: xarray DataArray or lmfit Parameters
|
|
:param x: The name of x axis in data or the data of x axis, defaults to None
|
|
:type x: str or numpy array, optional
|
|
:param y: The name of y axis in data or the data of y axis, defaults to None
|
|
:type y: str or numpy array, optional
|
|
:param input_core_dims: over write of the same argument in xarray.apply_ufunc, defaults to None, defaults to None
|
|
:type input_core_dims: list or array like, optional
|
|
:param dask: over write of the same argument in xarray.apply_ufunc, defaults to None, defaults to 'parallelized'
|
|
:type dask: str, optional
|
|
:param vectorize: over write of the same argument in xarray.apply_ufunc, defaults to None, defaults to True
|
|
:type vectorize: bool, optional
|
|
:param keep_attrs: over write of the same argument in xarray.apply_ufunc, defaults to None, defaults to True
|
|
:type keep_attrs: bool, optional
|
|
:param daskKwargs: over write of the same argument in xarray.apply_ufunc, defaults to None, defaults to None
|
|
:type daskKwargs: dict, optional
|
|
:return: The fit result
|
|
:rtype: xarray DataArray
|
|
"""
|
|
kwargs.update(
|
|
{
|
|
"dask": dask,
|
|
"vectorize": vectorize,
|
|
"input_core_dims": input_core_dims,
|
|
'keep_attrs': keep_attrs,
|
|
}
|
|
)
|
|
|
|
if not daskKwargs is None:
|
|
kwargs.update({"dask_gufunc_kwargs": daskKwargs})
|
|
|
|
if isinstance(paramsArray, type(self.fitModel.make_params())):
|
|
|
|
if input_core_dims is None:
|
|
kwargs.update(
|
|
{
|
|
"input_core_dims": [['x']],
|
|
}
|
|
)
|
|
|
|
if x is None:
|
|
if 'x' in dataArray.dims:
|
|
x = dataArray['x'].to_numpy()
|
|
else:
|
|
if isinstance(x, str):
|
|
if input_core_dims is None:
|
|
kwargs.update(
|
|
{
|
|
"input_core_dims": [[x]],
|
|
}
|
|
)
|
|
x = dataArray[x].to_numpy()
|
|
|
|
if self.fitDim == 1:
|
|
|
|
res = xr.apply_ufunc(self._fit_1D, dataArray, kwargs={'params':paramsArray,'x':x},
|
|
output_dtypes=[type(lmfit.model.ModelResult(self.fitModel, self.fitModel.make_params()))],
|
|
**kwargs)
|
|
|
|
if keep_attrs:
|
|
res.attrs = copy.copy(dataArray.attrs)
|
|
|
|
return res
|
|
|
|
if self.fitDim == 2:
|
|
|
|
if y is None:
|
|
if 'y' in dataArray.dims:
|
|
y = dataArray['y'].to_numpy()
|
|
if input_core_dims is None:
|
|
kwargs.update(
|
|
{
|
|
"input_core_dims": [['x', 'y']],
|
|
}
|
|
)
|
|
else:
|
|
if isinstance(y, str):
|
|
kwargs["input_core_dims"][0] = np.append(kwargs["input_core_dims"][0], y)
|
|
y = dataArray[y].to_numpy()
|
|
elif input_core_dims is None:
|
|
kwargs.update(
|
|
{
|
|
"input_core_dims": [['x', 'y']],
|
|
}
|
|
)
|
|
|
|
_x, _y = np.meshgrid(x, y)
|
|
_x = _x.flatten()
|
|
_y = _y.flatten()
|
|
|
|
# dataArray = dataArray.stack(_z=(kwargs["input_core_dims"][0][0], kwargs["input_core_dims"][0][1]))
|
|
|
|
# kwargs["input_core_dims"][0] = ['_z']
|
|
|
|
res = xr.apply_ufunc(self._fit_2D, dataArray, kwargs={'params':paramsArray,'x':_x, 'y':_y},
|
|
output_dtypes=[type(lmfit.model.ModelResult(self.fitModel, self.fitModel.make_params()))],
|
|
**kwargs)
|
|
|
|
if keep_attrs:
|
|
res.attrs = copy.copy(dataArray.attrs)
|
|
|
|
return res
|
|
|
|
else:
|
|
|
|
if input_core_dims is None:
|
|
kwargs.update(
|
|
{
|
|
"input_core_dims": [['x'], []],
|
|
}
|
|
)
|
|
|
|
if x is None:
|
|
if 'x' in dataArray.dims:
|
|
x = dataArray['x'].to_numpy()
|
|
else:
|
|
if isinstance(x, str):
|
|
if input_core_dims is None:
|
|
kwargs.update(
|
|
{
|
|
"input_core_dims": [[x], []],
|
|
}
|
|
)
|
|
x = dataArray[x].to_numpy()
|
|
|
|
if self.fitDim == 1:
|
|
return xr.apply_ufunc(self._fit_1D, dataArray, paramsArray, kwargs={'x':x},
|
|
output_dtypes=[type(lmfit.model.ModelResult(self.fitModel, self.fitModel.make_params()))],
|
|
**kwargs)
|
|
|
|
if self.fitDim == 2:
|
|
|
|
if input_core_dims is None:
|
|
kwargs.update(
|
|
{
|
|
"input_core_dims": [['x', 'y'], []],
|
|
}
|
|
)
|
|
|
|
if y is None:
|
|
if 'y' in dataArray.dims:
|
|
y = dataArray['y'].to_numpy()
|
|
else:
|
|
if isinstance(y, str):
|
|
y = dataArray[y].to_numpy()
|
|
kwargs["input_core_dims"][0] = np.append(kwargs["input_core_dims"][0], y)
|
|
|
|
_x, _y = np.meshgrid(x, y)
|
|
_x = _x.flatten()
|
|
_y = _y.flatten()
|
|
|
|
# dataArray = dataArray.stack(_z=(kwargs["input_core_dims"][0][0], kwargs["input_core_dims"][0][1]))
|
|
|
|
# kwargs["input_core_dims"][0] = ['_z']
|
|
|
|
return xr.apply_ufunc(self._fit_2D, dataArray, paramsArray, kwargs={'x':_x, 'y':_y},
|
|
output_dtypes=[type(lmfit.model.ModelResult(self.fitModel, self.fitModel.make_params()))],
|
|
**kwargs)
|
|
|
|
def _eval_1D(self, fitResult, x):
|
|
"""Call the eval function of the 1D fit model to calculate the curve.
|
|
|
|
:param fitResult: The result of fit
|
|
:type fitResult: lmfit FitResult
|
|
:param x: The data of x axis
|
|
:type x: 1D numpy array
|
|
:return: The curve based on the fit result
|
|
:rtype: 1D numpy array
|
|
"""
|
|
return self.fitModel.eval(x=x, **fitResult.best_values)
|
|
|
|
def _eval_2D(self, fitResult, x, y, shape):
|
|
"""Call the eval function of the 2D fit model to calculate the curve.
|
|
|
|
:param fitResult: The result of fit
|
|
:type fitResult: lmfit FitResult
|
|
:param x: The data of x axis
|
|
:type x: 1D numpy array
|
|
:param y: The flattened data of y axis
|
|
:type y: 1D numpy array
|
|
:param shape: The desired shape for output
|
|
:type shape: list, tuple or array like
|
|
:return: The curve based on the fit result
|
|
:rtype: 2D numpy array
|
|
"""
|
|
res = self.fitModel.eval(x=x, y=y, **fitResult.best_values)
|
|
return res.reshape(shape, order='F')
|
|
|
|
def eval(self, fitResultArray, x=None, y=None, output_core_dims=None, prefix="", dask='parallelized', vectorize=True, daskKwargs=None, **kwargs):
|
|
"""Call the eval function of the fit model to calculate the curve.
|
|
|
|
:param fitResultArray: The result of fit
|
|
:type fitResultArray: xarray DataArray
|
|
:param x: The name of x axis in data or the data of x axis, defaults to None
|
|
:type x: str or numpy array, optional
|
|
:param y: The name of y axis in data or the data of y axis, defaults to None
|
|
:type y: str or numpy array, optional
|
|
:param output_core_dims: over write of the same argument in xarray.apply_ufunc, defaults to None
|
|
:type output_core_dims: list, optional
|
|
:param prefix: prefix str of the fit model, defaults to ""
|
|
:type prefix: str, optional
|
|
:param dask: over write of the same argument in xarray.apply_ufunc, defaults to 'parallelized'
|
|
:type dask: str, optional
|
|
:param vectorize: over write of the same argument in xarray.apply_ufunc, defaults to True
|
|
:type vectorize: bool, optional
|
|
:param daskKwargs: over write of the same argument in xarray.apply_ufunc, defaults to None
|
|
:type daskKwargs: dict, optional
|
|
:return: The curve based on the fit result
|
|
:rtype: xarray
|
|
"""
|
|
|
|
kwargs.update(
|
|
{
|
|
"dask": dask,
|
|
"vectorize": vectorize,
|
|
"output_core_dims": output_core_dims,
|
|
}
|
|
)
|
|
|
|
if daskKwargs is None:
|
|
daskKwargs = {}
|
|
|
|
if self.fitDim == 1:
|
|
|
|
if output_core_dims is None:
|
|
kwargs.update(
|
|
{
|
|
"output_core_dims": prefix+'x',
|
|
}
|
|
)
|
|
output_core_dims = [prefix+'x']
|
|
|
|
daskKwargs.update(
|
|
{
|
|
'output_sizes': {
|
|
output_core_dims[0]: np.size(x),
|
|
},
|
|
'meta': np.ndarray((0,0), dtype=float)
|
|
}
|
|
)
|
|
|
|
kwargs.update(
|
|
{
|
|
"dask_gufunc_kwargs": daskKwargs,
|
|
}
|
|
)
|
|
|
|
res = xr.apply_ufunc(self._eval_1D, fitResultArray, kwargs={"x":x}, **kwargs)
|
|
return res.assign_coords({prefix+'x':np.array(x)})
|
|
|
|
if self.fitDim == 2:
|
|
if output_core_dims is None:
|
|
kwargs.update(
|
|
{
|
|
"output_core_dims": [[prefix+'x', prefix+'y']],
|
|
}
|
|
)
|
|
output_core_dims = [prefix+'x', prefix+'y']
|
|
|
|
daskKwargs.update(
|
|
{
|
|
'output_sizes': {
|
|
output_core_dims[0]: np.size(x),
|
|
output_core_dims[1]: np.size(y),
|
|
},
|
|
'meta': np.ndarray((0,0), dtype=float)
|
|
},
|
|
)
|
|
|
|
kwargs.update(
|
|
{
|
|
"dask_gufunc_kwargs": daskKwargs,
|
|
}
|
|
)
|
|
|
|
_x, _y = np.meshgrid(x, y)
|
|
_x = _x.flatten()
|
|
_y = _y.flatten()
|
|
|
|
res = xr.apply_ufunc(self._eval_2D, fitResultArray, kwargs={"x":_x, "y":_y, "shape":(len(x), len(y))}, **kwargs)
|
|
return res.assign_coords({prefix+'x':np.array(x), prefix+'y':np.array(y)})
|
|
|
|
def _get_fit_value_single(self, fitResult, key):
|
|
"""get value of one single parameter from fit result
|
|
|
|
:param fitResult: The result of the fit
|
|
:type fitResult: lmfit FitResult
|
|
:param key: The name of the parameter
|
|
:type key: str
|
|
:return: The vaule of the parameter
|
|
:rtype: float
|
|
"""
|
|
return fitResult.params[key].value
|
|
|
|
def _get_fit_value(self, fitResult, params):
|
|
"""get value of parameters from fit result
|
|
|
|
:param fitResult: The result of the fit
|
|
:type fitResult: lmfit FitResult
|
|
:param params: A list of the name of paramerters to read
|
|
:type params: list or array like
|
|
:return: The vaule of the parameter
|
|
:rtype: 1D numpy array
|
|
"""
|
|
func = np.vectorize(self._get_fit_value_single)
|
|
res = tuple(
|
|
func(fitResult, key)
|
|
for key in params
|
|
)
|
|
|
|
return res
|
|
|
|
def get_fit_value(self, fitResult, dask='parallelized', **kwargs):
|
|
"""get value of parameters from fit result
|
|
|
|
:param fitResult: The result of the fit
|
|
:type fitResult: lmfit FitResult
|
|
:param dask: over write of the same argument in xarray.apply_ufunc, defaults to 'parallelized'
|
|
:type dask: str, optional
|
|
:return: The vaule of the parameter
|
|
:rtype: xarray DataArray
|
|
"""
|
|
firstIndex = {
|
|
key: fitResult[key][0]
|
|
for key in fitResult.dims
|
|
}
|
|
firstFitResult = fitResult.sel(firstIndex).item()
|
|
|
|
params = list(firstFitResult.params.keys())
|
|
|
|
output_core_dims=[ [] for _ in range(len(params))]
|
|
|
|
kwargs.update(
|
|
{
|
|
"dask": dask,
|
|
"output_core_dims": output_core_dims,
|
|
}
|
|
)
|
|
|
|
value = xr.apply_ufunc(self._get_fit_value, fitResult, kwargs=dict(params=params), **kwargs)
|
|
|
|
value = xr.Dataset(
|
|
data_vars={
|
|
params[i]: value[i]
|
|
for i in range(len(params))
|
|
},
|
|
attrs=fitResult.attrs
|
|
)
|
|
|
|
return value
|
|
|
|
def _get_fit_std_single(self, fitResult, key):
|
|
"""get standard deviation of one single parameter from fit result
|
|
|
|
:param fitResult: The result of the fit
|
|
:type fitResult: lmfit FitResult
|
|
:param key: The name of the parameter
|
|
:type key: str
|
|
:return: The vaule of the parameter
|
|
:rtype: float
|
|
"""
|
|
return fitResult.params[key].stderr
|
|
|
|
def _get_fit_std(self, fitResult, params):
|
|
"""get standard deviation of parameters from fit result
|
|
|
|
:param fitResult: The result of the fit
|
|
:type fitResult: lmfit FitResult
|
|
:param params: A list of the name of paramerters to read
|
|
:type params: list or array like
|
|
:return: The vaule of the parameter
|
|
:rtype: 1D numpy array
|
|
"""
|
|
func = np.vectorize(self._get_fit_std_single)
|
|
res = tuple(
|
|
func(fitResult, key)
|
|
for key in params
|
|
)
|
|
|
|
return res
|
|
|
|
def get_fit_std(self, fitResult, dask='parallelized', **kwargs):
|
|
"""get standard deviation of parameters from fit result
|
|
|
|
:param fitResult: The result of the fit
|
|
:type fitResult: lmfit FitResult
|
|
:param dask: over write of the same argument in xarray.apply_ufunc, defaults to 'parallelized'
|
|
:type dask: str, optional
|
|
:return: The vaule of the parameter
|
|
:rtype: xarray DataArray
|
|
"""
|
|
firstIndex = {
|
|
key: fitResult[key][0]
|
|
for key in fitResult.dims
|
|
}
|
|
firstFitResult = fitResult.sel(firstIndex).item()
|
|
|
|
params = list(firstFitResult.params.keys())
|
|
|
|
output_core_dims=[ [] for _ in range(len(params))]
|
|
|
|
kwargs.update(
|
|
{
|
|
"dask": dask,
|
|
"output_core_dims": output_core_dims,
|
|
}
|
|
)
|
|
|
|
value = xr.apply_ufunc(self._get_fit_std, fitResult, kwargs=dict(params=params), **kwargs)
|
|
|
|
value = xr.Dataset(
|
|
data_vars={
|
|
params[i]: value[i]
|
|
for i in range(len(params))
|
|
},
|
|
attrs=fitResult.attrs
|
|
)
|
|
|
|
return value
|
|
|
|
def _get_fit_full_result_single(self, fitResult, key):
|
|
"""get the full result of one single parameter from fit result
|
|
|
|
:param fitResult: The result of the fit
|
|
:type fitResult: lmfit FitResult
|
|
:param key: The name of the parameter
|
|
:type key: str
|
|
:return: The vaule of the parameter
|
|
:rtype: float
|
|
"""
|
|
|
|
if not fitResult.params[key].value is None:
|
|
value = fitResult.params[key].value
|
|
else:
|
|
value = np.nan
|
|
|
|
if not fitResult.params[key].stderr is None:
|
|
std = fitResult.params[key].stderr
|
|
else:
|
|
std = np.nan
|
|
|
|
return ufloat(value, std)
|
|
|
|
def _get_fit_full_result(self, fitResult, params):
|
|
"""get the full result of parameters from fit result
|
|
|
|
:param fitResult: The result of the fit
|
|
:type fitResult: lmfit FitResult
|
|
:param params: A list of the name of paramerters to read
|
|
:type params: list or array like
|
|
:return: The vaule of the parameter
|
|
:rtype: 1D numpy array
|
|
"""
|
|
func = np.vectorize(self._get_fit_full_result_single)
|
|
res = tuple(
|
|
func(fitResult, key)
|
|
for key in params
|
|
)
|
|
|
|
return res
|
|
|
|
def get_fit_full_result(self, fitResult, dask='parallelized', **kwargs):
|
|
"""get the full result of parameters from fit result
|
|
|
|
:param fitResult: The result of the fit
|
|
:type fitResult: lmfit FitResult
|
|
:param dask: over write of the same argument in xarray.apply_ufunc, defaults to 'parallelized'
|
|
:type dask: str, optional
|
|
:return: The vaule of the parameter
|
|
:rtype: xarray DataArray
|
|
"""
|
|
firstIndex = {
|
|
key: fitResult[key][0]
|
|
for key in fitResult.dims
|
|
}
|
|
firstFitResult = fitResult.sel(firstIndex).item()
|
|
|
|
params = list(firstFitResult.params.keys())
|
|
|
|
output_core_dims=[ [] for _ in range(len(params))]
|
|
|
|
kwargs.update(
|
|
{
|
|
"dask": dask,
|
|
"output_core_dims": output_core_dims,
|
|
}
|
|
)
|
|
|
|
value = xr.apply_ufunc(self._get_fit_full_result, fitResult, kwargs=dict(params=params), **kwargs)
|
|
|
|
value = xr.Dataset(
|
|
data_vars={
|
|
params[i]: value[i]
|
|
for i in range(len(params))
|
|
},
|
|
attrs=fitResult.attrs
|
|
)
|
|
|
|
return value
|
|
|
|
|
|
|