I am having issues with the numerical accuracy of scipy.optimize.curve_fit function in python. It seems to me that I can only get ~ 8 digits of accuracy when I desire ~ 15 digits. I have some data (at this point artificially created) made from the following data creation:
where term 1 ~ 10^-3, term 2 ~ 10^-6, and term 3 is ~ 10^-11. In the data, I vary
A randomly (it is a Gaussian error). I then try to fit this to a model:
where lambda is a constant, and I only fit
alpha (it is a parameter in the function). Now what I would expect is to see a linear relationship between
A because terms 1 and 2 in the data creation are also in the model, so they should cancel perfectly;
However, what happens is for small
A (~10^-11 and below),
alpha does not scale with
A, that is to say, as
A gets smaller and smaller,
alpha levels out and remains constant.
For reference, I call the following: op, pcov = scipy.optimize.curve_fit(model, xdata, ydata, p0=None, sigma=sig)
My first thought was that I was not using double precision, but I am pretty sure that python automatically creates numbers in double precision. Then I thought it was an issue with the documentation perhaps that cuts off the digits? Anyways, I could put my code in here but it is sort of complicated. Is there a way to ensure that the curve fitting function saves my digits?
Thank you so much for your help!
EDIT: The below is my code:
# Import proper packages import numpy as np import numpy.random as npr import scipy as sp import scipy.constants as spc import scipy.optimize as spo from matplotlib import pyplot as plt from numpy import ndarray as nda from decimal import * # Declare global variables AU = 149597871000.0 test_lambda = 20*AU M_Sun = (1.98855*(sp.power(10.0,30.0))) M_Jupiter = (M_Sun/1047.3486) test_jupiter_mass = M_Jupiter test_sun_mass = M_Sun rad_jup = 5.2*AU ran = np.linspace(AU, 100*AU, num=100) delta_a = np.power(10.0, -11.0) chi_limit = 118.498 # Model acceleration of the spacecraft from the sun (with Yukawa term) def model1(distance, A): return (spc.G)*(M_Sun/(distance**2.0))*(1 +A*(np.exp(-distance/test_lambda))) + (spc.G)*(M_Jupiter*distance)/((distance**2.0 + rad_jup**2.0)**(3.0/2.0)) # Function that creates a data point for test 1 def data1(distance, dela): return (spc.G)*(M_Sun/(distance**2.0) + (M_Jupiter*distance)/((distance**2.0 + rad_jup**2.0)**(3.0/2.0))) + dela # Generates a list of 100 data sets varying by ~&a for test 1 def generate_data1(): data_list =  for i in range(100): acc_lst =  for dist in ran: x = data1(dist, npr.normal(0, delta_a)) acc_lst.append(x) data_list.append(acc_lst) return data_list # Generates a list of standard deviations at each distance from the sun. Since &a is constant, the standard deviation of each point is constant def generate_sig(): sig =  for i in range(100): sig.append(delta_a) return sig # Finds alpha for test 1, since we vary &a in test 1, we need to generate new data for each time we find alpha def find_alpha1(data_list, sig): alphas =  for data in data_list: op, pcov = spo.curve_fit(model1, ran, data, p0=None, sigma=sig) alphas.append(op) return alphas # Tests the dependence of alpha on &a and plots the dependence def test1(): global delta_a global test_lambda test_lambda = 20*AU delta_a = 10.0**-20.0 alphas =  delta_as =  for i in range(20): print i data_list = generate_data1() print np.array(data_list) sig = generate_sig() alpha = find_alpha1(data_list, sig) delas =  for alp in alpha: if alp < 0: x = 0 plt.loglog(delta_a, abs(alp), '.' 'r') else: x = 0 plt.loglog(delta_a, alp, '.' 'b') delta_a *= 10 plt.xlabel('Delta A') plt.ylabel('Alpha (at Lambda = 5 AU)') plt.show() def main(): test1() if __name__ == '__main__': main()