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import scipy
import numpy as np
# Fitting
def fit_gaussian(S, V, **kwargs):
gauss = lambda s, v0, vp, s0, sigma: v0+vp*np.exp(-0.5*((s-s0)/sigma)**2)
v0 = np.min(V)
vp = np.max(V)-v0
s0 = S[np.argmax(V)]
sigma = np.sqrt(np.abs(np.sum((S - s0) ** 2 * V) / np.sum(V)))
result = fit_function(gauss, S, V, p0=(v0, vp, s0, sigma), **kwargs)
param, param_error, function, [X, _] = result
param[3] = np.abs(param[3]) # return the positive sigma (could use bounds instead, but that's more likely to fail)
return param, param_error, function, [X, lorenzian(X, *param)]
def fit_lorenzian(S, V, log=False, **kwargs):
lorenzian = lambda s, v0, vp, s0, gamma: v0 + vp/(1+((s-s0)/gamma)**2)
v0 = np.min(V)
vp = np.max(V)-v0
s0 = S[np.argmax(V)]
sigma = np.sqrt(np.abs(np.sum((S - s0) ** 2 * (V-v0)) / np.sum(V-v0)))
result = fit_function(lorenzian, S, V, p0=(v0, vp, s0, sigma), **kwargs)
param, param_error, function, [X, _] = result
param[3] = np.abs(param[3]) # return the positive sigma (could use bounds instead, but that's more likely to fail)
return param, param_error, function, [X, lorenzian(X, *param)]
def fit_function(function, x, y, p0=None, **kwargs):
"""
:param log: if the y-data is log-scaled
"""
param, cov = scipy.optimize.curve_fit(function, x, y, p0, **kwargs)
param_error = np.sqrt(np.abs(cov.diagonal()))
X = np.linspace(min(x), max(x), 1000)
return param, param_error, function, [X, function(X, *param)]
def fit_exponential(S, V, **kwargs):
exponential = lambda s, v0, vp, s0: v0 + vp*np.exp(s/s0)
v0 = np.min(V)
vp = np.max(V)-v0
s0 = 1
return fit_function(exponential, S, V, p0=(v0, vp, s0), **kwargs)