In Python, I'm trying to normalize two arrays and then take the average of the region where they overlap to create a new composite array.
To do this, I figure I have to:
- find the region of overlap,
- interpolate the overlapped y values,
- iterate through to find the normalization constant of the best fit, and then
- paste the pieces together to form my new curve
With some semi-random values, here's what that looks like:
This code works great for small data sets whose y values aren't too far apart, but Python crashes when there are orders of magnitude between Y1 and Y2 (obviously due to the iteration). Here's the code:
X1o = [x for x in X1 if x > X2] X2o = [x for x in X2 if x < X1[-1]] Y1o = [y for y in Y1[(len(Y1)-len(X1o)):]] Y2o = [y for y in Y2[:len(X2o)]] Y2o = list(interp(X1o,X2o,Y2o)) c = abs(min(Y1o)-max(Y2o)) Y2test = [y2+c for y2 in Y2o] Y2s =  d = 0.01*min(Y2test) while min(Y2test) < max(Y1o): Y2test = [y+d for y in Y2test] Y2s.append(Y2test) plot(X1o,Y2test,c='k',alpha=0.5) idx = min(map(lambda i: (u.squaredError(Y1o, i), i, Y2s.index(i)), Y2s))[-1] Yavg = [(y1+y2)/2 for y1,y2 in zip(Y1o,Y2s[idx])] diff = Y2s[idx]-Y2o X = [x for x in X1 if x < X2] + X1o + [x for x in X2 if x > X1[-1]] Y = [y for x,y in zip(X1,Y1) if x < X2] + Yavg + [y+diff for x,y in zip(X2,Y2) if x > X1[-1]]
I really need to do this with stellar spectra with thousands of data points and up to 20 orders of magnitude in spread between the y values.
Any suggestions would be greatly appreciated!