# fitting exponential decay with no initial guessing

Does anyone know a scipy/numpy module which will allow to fit exponential decay to data?

Google search returned a few blog posts, for example - http://exnumerus.blogspot.com/2010/04/how-to-fit-exponential-decay-example-in.html , but that solution requires y-offset to be pre-specified, which is not always possible

EDIT:

curve_fit works, but it can fail quite miserably with no initial guess for parameters, and that is sometimes needed. The code I'm working with is

``````#!/usr/bin/env python
import numpy as np
import scipy as sp
import pylab as pl
from scipy.optimize.minpack import curve_fit

x = np.array([  50.,  110.,  170.,  230.,  290.,  350.,  410.,  470.,
530.,  590.])
y = np.array([ 3173.,  2391.,  1726.,  1388.,  1057.,   786.,   598.,
443.,   339.,   263.])

smoothx = np.linspace(x[0], x[-1], 20)

guess_a, guess_b, guess_c = 4000, -0.005, 100
guess = [guess_a, guess_b, guess_c]

exp_decay = lambda x, A, t, y0: A * np.exp(x * t) + y0

params, cov = curve_fit(exp_decay, x, y, p0=guess)

A, t, y0 = params

print "A = %s\nt = %s\ny0 = %s\n" % (A, t, y0)

pl.clf()
best_fit = lambda x: A * np.exp(t * x) + y0

pl.plot(x, y, 'b.')
pl.plot(smoothx, best_fit(smoothx), 'r-')
pl.show()
``````

which works, but if we remove "p0=guess", it fails miserably.

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it fails miserably because the default guess for p0 is [1,1,1]. The problem is that the second variable should be negative. If you either change your exp_decay function to reflect this (use np.exp(-x * t)) or use p0=[1,-1,1], I am guessing that it will work. These methods can have problems with sign changes in variables. – Justin Peel Oct 15 '10 at 4:29

You have two options:

1. Linearize the system, and fit a line to the log of the data.
2. Use a non-linear solver (e.g. `scipy.optimize.curve_fit`

The first option is by far the fastest and most robust. However, it requires that you know the y-offset a-priori, otherwise it's impossible to linearize the equation. (i.e. `y = A * exp(K * t)` can be linearized by fitting `y = log(A * exp(K * t)) = K * t + log(A)`, but `y = A*exp(K*t) + C` can only be linearized by fitting `y - C = K*t + log(A)`, and as `y` is your independent variable, `C` must be known beforehand for this to be a linear system.

If you use a non-linear method, it's a) not guaranteed to converge and yield a solution, b) will be much slower, c) gives a much poorer estimate of the uncertainty in your parameters, and d) is often much less precise. However, a non-linear method has one huge advantage over a linear inversion: It can solve a non-linear system of equations. In your case, this means that you don't have to know `C` beforehand.

Just to give an example, let's solve for y = A * exp(K * t) with some noisy data using both linear and nonlinear methods:

``````import numpy as np
import matplotlib.pyplot as plt
import scipy as sp
import scipy.optimize

def main():
# Actual parameters
A0, K0, C0 = 2.5, -4.0, 2.0

# Generate some data based on these
tmin, tmax = 0, 0.5
num = 20
t = np.linspace(tmin, tmax, num)
y = model_func(t, A0, K0, C0)

noisy_y = y + 0.5 * (np.random.random(num) - 0.5)

fig = plt.figure()

# Non-linear Fit
A, K, C = fit_exp_nonlinear(t, noisy_y)
fit_y = model_func(t, A, K, C)
plot(ax1, t, y, noisy_y, fit_y, (A0, K0, C0), (A, K, C0))
ax1.set_title('Non-linear Fit')

# Linear Fit (Note that we have to provide the y-offset ("C") value!!
A, K = fit_exp_linear(t, y, C0)
fit_y = model_func(t, A, K, C0)
plot(ax2, t, y, noisy_y, fit_y, (A0, K0, C0), (A, K, 0))
ax2.set_title('Linear Fit')

plt.show()

def model_func(t, A, K, C):
return A * np.exp(K * t) + C

def fit_exp_linear(t, y, C=0):
y = y - C
y = np.log(y)
K, A_log = np.polyfit(t, y, 1)
A = np.exp(A_log)
return A, K

def fit_exp_nonlinear(t, y):
opt_parms, parm_cov = sp.optimize.curve_fit(model_func, t, y, maxfev=1000)
A, K, C = opt_parms
return A, K, C

def plot(ax, t, y, noisy_y, fit_y, orig_parms, fit_parms):
A0, K0, C0 = orig_parms
A, K, C = fit_parms

ax.plot(t, y, 'k--',
label='Actual Function:\n \$y = %0.2f e^{%0.2f t} + %0.2f\$' % (A0, K0, C0))
ax.plot(t, fit_y, 'b-',
label='Fitted Function:\n \$y = %0.2f e^{%0.2f t} + %0.2f\$' % (A, K, C))
ax.plot(t, noisy_y, 'ro')

if __name__ == '__main__':
main()
``````

Note that the linear solution provides a result much closer to the actual values. However, we have to provide the y-offset value in order to use a linear solution. The non-linear solution doesn't require this a-priori knowledge.

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Thank you! Unfortunately, the problem with curve_fit is that it can fail miserably if no initial guess for parameters is provided – George Karpenkov Oct 15 '10 at 0:22
@cheshire - That's a mathematical fact of life when using any non-linear solution. There's no "best" way around it, though some non-linear methods will work better than others for your particular problem. In your case, you can specify the Jacobian, which will help immensely in this situation. You can also use the input data to make an intelligent guess for the starting parameters. – Joe Kington Oct 15 '10 at 0:25
I've used QtiPlot before, and it does very good fit without any initial guessing – George Karpenkov Oct 15 '10 at 0:28
One possible improvement in this case would be to do a nested optimization, linear inside non-linear. Given the offset, you can directly calculate the remaining two parameters. So, in the outer optimization only the offset needs to be chosen with a non-linear optimizer. I guess that, in this case, it will be easier to find a good starting value or global optimizer. – user333700 Oct 18 '10 at 3:20
Whoa, hold up. "The first option is by far... most robust." Absolutely not true for exponential fitting. The LLS estimate is more sensitive to small perturbations in the observed data than the NLS estimate. – Steve Tjoa Oct 21 '10 at 23:10

I would use the `scipy.optimize.curve_fit` function. The doc string for it even has an example of fitting an exponential decay in it which I'll copy here:

``````>>> import numpy as np
>>> 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)
``````

The fitted parameters will vary because of the random noise added in, but I got 2.47990495, 1.40709306, 0.53753635 as a, b, and c so that's not so bad with the noise in there. If I fit to y instead of yn I get the exact a, b, and c values.

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You beat me to it! That's what I get for taking so long to type up an example.! :) I'll leave mine up, as well, though, as it elaborates a bit on the pros and cons... – Joe Kington Oct 15 '10 at 0:18

The right way to do it is to do Prony estimation and use the result as the initial guess for least squares fitting (or some other more robust fitting routine). Prony estimation does not need an initial guess, but it does need many points to yield a good a estimate.

Here is an overview

http://www.statsci.org/other/prony.html

In Octave this is implemented as `expfit`, so you can write your own routine based on the Octave library function.

Prony estimation does need the offset to be known, but if you go "far enough" into your decay, you have a reasonable estimate of the offset, so you can just shift the data to place the offset at 0. At any rate, Prony estimation is just a way to get a reasonable initial guess for other fitting routines.

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Actually, for Prony estimation and related methods (ESPRIT, MUSIC) the offset does not need to be know. As long as you have enough samples the algorithm can infer the offset. – Marcus P S Dec 18 '14 at 16:17

I never got curve_fit to work properly, as you say I don't want to guess anything. I was trying to simplify Joe Kington's example and this is what I got working. The idea is to translate the 'noisy' data into log and then transalte it back and use polyfit and polyval to figure out the parameters:

``````model = np.polyfit(xVals, np.log(yVals) , 1);
splineYs = np.exp(np.polyval(model,xVals[0]));
pyplot.plot(xVals,yVals,','); #show scatter plot of original data
pyplot.plot(xVals,splineYs('b-'); #show fitted line
pyplot.show()
``````

where xVals and yVals are just lists.

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I don't know python, but I do know a simple way to non-iteratively estimate the coefficients of exponential decay with an offset, given three data points with a fixed difference in their independent coordinate. Your data points have a fixed difference in their independent coordinate (your x values are spaced at an interval of 60), so my method can be applied to them. You can surely translate the math into python.

Assume

``````y = A + B*exp(-c*x) = A + B*C^x
``````

where `C = exp(-c)`

Given y_0, y_1, y_2, for x = 0, 1, 2, we solve

``````y_0 = A + B
y_1 = A + B*C
y_2 = A + B*C^2
``````

to find A, B, C as follows:

``````A = (y_0*y_2 - y_1^2)/(y_0 + y_2 - 2*y_1)
B = (y_1 - y_0)^2/(y_0 + y_2 - 2*y_1)
C = (y_2 - y_1)/(y_1 - y_0)
``````

The corresponding exponential passes exactly through the three points (0,y_0), (1,y_1), and (2,y_2). If your data points are not at x coordinates 0, 1, 2 but rather at k, k + s, and k + 2*s, then

``````y = A′ + B′*C′^(k + s*x) = A′ + B′*C′^k*(C′^s)^x = A + B*C^x
``````

so you can use the above formulas to find A, B, C and then calculate

``````A′ = A
C′ = C^(1/s)
B′ = B/(C′^k)
``````

The resulting coefficients are very sensitive to errors in the y coordinates, which can lead to large errors if you extrapolate beyond the range defined by the three used data points, so it is best to calculate A, B, C from three data points that are as far apart as possible (while still having a fixed distance between them).

Your data set has 10 equidistant data points. Let's pick the three data points (110, 2391), (350, 786), (590, 263) for use ― these have the greatest possible fixed distance (240) in the independent coordinate. So, y_0 = 2391, y_1 = 786, y_2 = 263, k = 110, s = 240. Then A = 10.20055, B = 2380.799, C = 0.3258567, A′ = 10.20055, B′ = 3980.329, C′ = 0.9953388. The exponential is

``````y = 10.20055 + 3980.329*0.9953388^x = 10.20055 + 3980.329*exp(-0.004672073*x)
``````

You can use this exponential as the initial guess in a non-linear fitting algorithm.

The formula for calculating A is the same as that used by the Shanks transformation (http://en.wikipedia.org/wiki/Shanks_transformation).

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