# Fitting arbitrary gaussian functions, massive memory consumption in python

I'm trying to (in python) fit a series of an arbitrary number of gaussian functions (determined by a simple algorithm still being improved) to a data set. For my current sample data set, I have 174 gaussian functions. I have a procedure for doing the fit, but it's basically complicated guess-and-check, and consumes all 4GB of memory available.

Is there any way to accomplish this using something in scipy or numpy?

Here is what I'm trying to use, where wavelength[] is the list of x-coordinates, and fluxc[] is the list of y-coordinates:

```#Pick a gaussian
for repeat in range(0,2):
for f in range(0,len(centroid)):
#Iterate over every other gaussian
for i in range(0,len(centroid)):
if i!= f:
#For every wavelength,
for w in wavelength:
#Append the value of each to an list, called others
others.append(height[i]*math.exp(-(w-centroid[i])**2/(2*width[i]**2)))

#Optimize the centroid of the current gaussian
prev = centroid[f]
best = centroid[f]
#Pick an order of magnitude
for p in range (int(round(math.log10(centroid[i]))-3-repeat),int(round(math.log10(centroid[i])))-6-repeat,-1):
#Pick a value of that order of magnitude
for m in range (-5,9):
#Change the value of the current item
centroid[f] = prev + m * 10 **(p)
#Increment over all wavelengths, make a list of the new values
variancy = 0
residual = 0
test = []
#Increment across every wavelength and evaluate if this change gets R^2 any larger
for k in range(0,len(wavelength)):
test.append(height[i]*math.exp(-(wavelength[k]-centroid[f])**2/(2*width[i]**2)))
residual += (test[k]+others[k]-cflux[k])**2
variancy += (test[k]+others[k]-avgcflux)**2
rsquare = 1-(residual/variancy)
#Check the R^2 value for this new fit
if rsquare > bestr:
bestr = rsquare
best = centroid[f]
centroid[f] = best

#Optimize the height of the current gaussian
prev = height[f]
best = height[f]
#Pick an order of magnitude
for p in range (int(round(math.log10(height[i]))-repeat),int(round(math.log10(height[i])))-3-repeat,-1):
#Pick a value of that order of magnitude
for m in range (-5,9):
#Change the value of the current item
height[f] = prev + m * 10 **(p)
#Increment over all wavelengths, make a list of the new values
variancy = 0
residual = 0
test = []
#Increment across every wavelength and evaluate if this change gets R^2 any larger
for k in range(0,len(wavelength)):
test.append(height[f]*math.exp(-(wavelength[k]-centroid[i])**2/(2*width[i]**2)))
residual += (test[k]+others[k]-cflux[k])**2
variancy += (test[k]+others[k]-avgcflux)**2
rsquare = 1-(residual/variancy)
#Check the R^2 value for this new fit
if rsquare > bestr:
bestr = rsquare
best = height[f]
height[f] = best

#Optimize the width of the current gaussian
prev = width[f]
best = width[f]
#Pick an order of magnitude
for p in range (int(round(math.log10(width[i]))-repeat),int(round(math.log10(width[i])))-3-repeat,-1):
#Pick a value of that order of magnitude
for m in range (-5,9):
if prev + m * 10**(p) == 0:
m+=1
#Change the value of the current item
width[f] = prev + m * 10 **(p)
#Increment over all wavelengths, make a list of the new values
variancy = 0
residual = 0
test = []
#Increment across every wavelength and evaluate if this change gets R^2 any larger
for k in range(0,len(wavelength)):
test.append(height[i]*math.exp(-(wavelength[k]-centroid[i])**2/(2*width[f]**2)))
residual += (test[k]+others[k]-cflux[k])**2
variancy += (test[k]+others[k]-avgcflux)**2
rsquare = 1-(residual/variancy)
#Check the R^2 value for this new fit
if rsquare > bestr:
bestr = rsquare
best = width[f]
width[f] = best
count += 1
#print '{} of {} peaks optimized, iteration {} of {}'.format(f+1,len(centroid),repeat+1,2)
complete = round(100*(count/(float(len(centroid))*2)),2)
print '{}% completed'.format(complete)
print 'New R^2 = {}'.format(bestr)
```
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## 1 Answer

Yes, it can likely be done better (easier) using scipy. But firstly, refactor your code into smaller functions; it justs makes it a lot easier to read and understand what's going on.

As for the memory consumption: you're probably overextending a list far too much somewhere (`others` is a candidate: I never see it cleared (or initialized!), while it gets filled in a quadruple loop). That, or your data is simply that large (in which case you really should be using numpy arrays, just to speed up things). I can't tell, because you're introducing various variables without giving any idea of the size (how big is `wavelengths`? How large does `others` get? What and where are all the initializations of your data arrays?)

Also, fitting 174 Gaussians is just a bit crazy; either look into another way of determining whatever you want to get out of your data, or split things up. From the `wavelengths` variable, it appears you're trying to fit lines in a high resolution spectrum; perhaps isolating most of the lines and fitting those isolated groups separately is better. If they all overlap, I doubt any normal fitting technique is going to help you.

Lastly, perhaps a package like pandas can help (e.g., the computation subpackage).

Perhaps very lastly, since I see a lot that can be improved in the code. At some point codereview may also be useful. Though for now I guess your memory usage is the most problematic part.

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Thanks for your reply! This is only about a third of all the code I've written, everything is initialized earlier on. It is for analyzing a high-resolution spectra, right now with 992 data points. Is that far too many? I'd like to try to avoid breaking up the data before analyzing it, so I can extract as much useful data as possible. – Saethlin Apr 19 '13 at 15:35
Ha! Others was my memory problem, thanks. – Saethlin Apr 19 '13 at 15:51