I'm trying to get
python to return, as close as possible, the center of the most obvious clustering in an image like the one below:
In my previous question I asked how to get the global maximum and the local maximums of a 2d array, and the answers given worked perfectly. The issue is that the center estimation I can get by averaging the global maximum obtained with different bin sizes is always slightly off than the one I would set by eye, because I'm only accounting for the biggest bin instead of a group of biggest bins (like one does by eye).
I tried adapting the answer to this question to my problem, but it turns out my image is too noisy for that algorithm to work. Here's my code implementing that answer:
import numpy as np from scipy.ndimage.filters import maximum_filter from scipy.ndimage.morphology import generate_binary_structure, binary_erosion import matplotlib.pyplot as pp from os import getcwd from os.path import join, realpath, dirname # Save path to dir where this code exists. mypath = realpath(join(getcwd(), dirname(__file__))) myfile = 'data_file.dat' x, y = np.loadtxt(join(mypath,myfile), usecols=(1, 2), unpack=True) xmin, xmax = min(x), max(x) ymin, ymax = min(y), max(y) rang = [[xmin, xmax], [ymin, ymax]] paws =  for d_b in range(25, 110, 25): # Number of bins in x,y given the bin width 'd_b' binsxy = [int((xmax - xmin) / d_b), int((ymax - ymin) / d_b)] H, xedges, yedges = np.histogram2d(x, y, range=rang, bins=binsxy) paws.append(H) def detect_peaks(image): """ Takes an image and detect the peaks usingthe local maximum filter. Returns a boolean mask of the peaks (i.e. 1 when the pixel's value is the neighborhood maximum, 0 otherwise) """ # define an 8-connected neighborhood neighborhood = generate_binary_structure(2,2) #apply the local maximum filter; all pixel of maximal value #in their neighborhood are set to 1 local_max = maximum_filter(image, footprint=neighborhood)==image #local_max is a mask that contains the peaks we are #looking for, but also the background. #In order to isolate the peaks we must remove the background from the mask. #we create the mask of the background background = (image==0) #a little technicality: we must erode the background in order to #successfully subtract it form local_max, otherwise a line will #appear along the background border (artifact of the local maximum filter) eroded_background = binary_erosion(background, structure=neighborhood, border_value=1) #we obtain the final mask, containing only peaks, #by removing the background from the local_max mask detected_peaks = local_max - eroded_background return detected_peaks #applying the detection and plotting results for i, paw in enumerate(paws): detected_peaks = detect_peaks(paw) pp.subplot(4,2,(2*i+1)) pp.imshow(paw) pp.subplot(4,2,(2*i+2) ) pp.imshow(detected_peaks) pp.show()
and here's the result of that (varying the bin size):
Clearly my background is too noisy for that algorithm to work, so the question is: how can I make that algorithm less sensitive? If an alternative solution exists then please let me know.
Following Bi Rico advise I attempted smoothing my 2d array before passing it on to the local maximum finder, like so:
H, xedges, yedges = np.histogram2d(x, y, range=rang, bins=binsxy) H1 = gaussian_filter(H, 2, mode='nearest') paws.append(H1)
These were the results with a
sigma of 2, 4 and 8:
mode ='constant' seems to work much better than
nearest. It converges to the right center with a
sigma=2 for the largest bin size:
So, how do I get the coordinates of the maximum that shows in the last image?