I'm trying to plot some visualisations with matplotlib, and in one of my functions, I check if waves are logarithmic. This is my current working version:

```
import numpy as np
def is_logarithmic(waves):
def expfunc(x, a, b, c):
return a*np.exp(b*x) + c
wcopy = list(waves)
wcopy.sort()
# If the ratio of x-max : x-min < 10, don't use a logarithmic scale
# (at least in matplotlib)
if (wcopy[-1] / wcopy[0]) < 10:
return False
# Take a guess at whether it is logarithmic by seeing how well the x-scale
# fits an exponential curve
diffs = []
for ii in range(len(wcopy) - 1):
diffs.append(wcopy[ii + 1] - wcopy[ii])
# Fit the diffs to an exponential curve
x = np.arange(len(wcopy)-1)
try:
popt, pcov = curve_fit(expfunc, x, diffs)
except Exception as e:
print e
popt = [0.0, 0.0, 0.0]
pcov = np.inf
# If a > 0.5 and covsum < 1000.0
# use a logarithmic scale.
if type(pcov) == float:
# It's probably np.inf
covsum = pcov
else:
covsum = pcov.diagonal().sum()
res = (covsum < 1000.0) & (popt[0] > 0.5)
return res
```

I'm trying to find an alternative to scipy's `curve_fit()`

, because I don't want to install such a big library just to use that one function. Is there something else I can use, or a combination of other functions from using ideally just numpy and matplotlib, to get a similar result?

`curve_fit`

uses the Levenberg-Marquardt algorithm to do the minimization of errors. You can always implement it yourself.`46 MB`

(installed on linux) for scipy is not that much. Matplotlib is`72 MB`

in comparison.