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I have a set of data and I want to compare which line describes it best (polynomials of different orders, exponential or logarithmic).

I use Python and Numpy and for polynomial fitting there is a function polyfit(). But I found no such functions for exponential and logarithmic fitting.

Are there any? Or how to solve it otherwise?

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3 Answers 3

up vote 30 down vote accepted

For fitting y = A + B log x, just fit y against log x.

For fitting y = AeBx, take the logarithm of both side gives log y = log A + Bx. So just fit log y against x.

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Thank you, that's perfect, but how do I find the base of the logarithm that suits the best? –  Tomas Novotny Aug 8 '10 at 9:34
1  
@Tomas: Usually the natural log, but any log works. Just remember that if you use base K, then the equation becomes y = A*K^(Bx). –  KennyTM Aug 8 '10 at 9:44
    
So the quality of the fitting (for example R2) is not dependent on the base of the logarithm? Thank you once again, the answers are perfect, very useful, I will give you a point as soon as I reach enough reputation. –  Tomas Novotny Aug 8 '10 at 10:38
1  
@Tomas: Right. Changing the base of log just multiplies a constant to log x or log y, which doesn't affect r^2. –  KennyTM Aug 8 '10 at 11:20
    
This will give greater weight to values at small y. Hence it is better to weight contributions to the chi-squared values by y_i –  Rupert Nash Aug 8 '10 at 16:54

You can also fit a set of a data to whatever function you like using curve_fit from scipy.optimize. For example if you want to fit an exponential function (from the documentation at http://docs.scipy.org/doc/scipy/reference/generated/scipy.optimize.curve_fit.html):

import numpy as np
import matplotlib.pyplot as plt
from scipy.optimize import curve_fit

def func(x, a, b, c):
    return a * np.exp(-b * x) + c

x = np.linspace(0,4,50)
y = func(x, 2.5, 1.3, 0.5)
yn = y + 0.2*np.random.normal(size=len(x))

popt, pcov = curve_fit(func, x, yn)

And then if you want to plot, you could do:

plt.figure()
plt.plot(x, yn, 'ko', label="Original Noised Data")
plt.plot(x, func(x, *popt), 'r-', label="Fitted Curve")
plt.legend()
plt.show()

(Note: the * in front of popt when you plot will expand out the terms into the a, b, and c that func is expecting.)

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I was having some trouble with this so let me be very explicit so noobs like me can understand.

Lets say that we have a data file or something like that

# -*- coding: utf-8 -*-

import matplotlib.pyplot as plt
from scipy.optimize import curve_fit
import numpy as np
import sympy as sym

"""
Generate some data, let's imagine that you already have this. 
"""
x = np.linspace(0, 3, 50)
y = np.exp(x)

"""
Plot your data
"""
plt.plot(x, y, 'ro',label="Original Data")

"""
brutal force to avoid errors
"""    
x = [float(xn) for xn in x] #every element (xn) in x becomes a float
y = [float(yn) for yn in y] #every element (yn) in y becomes a float
x = np.array(x) #transform your data in a numpy array, 
y = np.array(y) #so the curve_fit can work

"""
create a function to fit with your data. a, b, c and d are the coefficients
that curve_fit will calculate for you. 
In this part you need to guess and/or use mathematical knowledge to find
a function that resembles your data
"""
def func(x, a, b, c, d):
    return a*x**3 + b*x**2 +c*x + d

"""
make the curve_fit
"""
popt, pcov = curve_fit(func, x, y)

"""
The result is:
popt[0] = a , popt[1] = b, popt[2] = c and popt[2] = d of the function,
so f(x) = popt[0]*x**3 + popt[1]*x**2 + popt[2]*x + popt[3].
"""
print "a = %s , b = %s, c = %s, d = %s" % (popt[0], popt[1], popt[2], popt[3])

"""
Use sympy to generate the latex sintax of the function
"""
xs = sym.Symbol('\lambda')    
tex = sym.latex(func(xs,*popt)).replace('$', '')
plt.title(r'$f(\lambda)= %s$' %(tex),fontsize=16)

"""
Print the coefficients and plot the funcion.
"""

plt.plot(x, func(x, *popt), label="Fitted Curve") #same as line above \/
#plt.plot(x, popt[0]*x**3 + popt[1]*x**2 + popt[2]*x + popt[3], label="Fitted Curve") 

plt.legend(loc='upper left')
plt.show()

the result is: a = 0.849195983017 , b = -1.18101681765, c = 2.24061176543, d = 0.816643894816

Raw data and fitted function

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2  
y = [np.exp(i) for i in x] is very slow; one reason numpy was created was so you could write y=np.exp(x). Also, with that replacement, you can get rid of your brutal force section. In ipython, there is the %timeit magic from which In [27]: %timeit ylist=[exp(i) for i in x] 10000 loops, best of 3: 172 us per loop In [28]: %timeit yarr=exp(x) 100000 loops, best of 3: 2.85 us per loop –  esmit Apr 4 at 16:33
    
Thank you esmit, you are right, but the brutal force part I still need to use when I'm dealing with data from a csv, xls or other formats that I've faced using this algorithm. I think that the use of it only make sense when someone is trying to fit a function from a experimental or simulation data, and in my experience this data always come in strange formats. –  Leandro Aug 17 at 0:24
    
x = np.array(x, dtype=float) should enable you to get rid of slow list comprehension. –  Ajasja Nov 9 at 22:19

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