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This python script reads in the lists of particles for each image generated by the python image processing step and outputs a list of steps in "steps.txt" and also images of the particle associations in each step between figures in "match*.png". | This python script reads in the lists of particles for each image generated by the python image processing step and outputs a list of steps in "steps.txt" and also images of the particle associations in each step between figures in "match*.png". | ||
Revision as of 03:52, 10 February 2014
Back to 2014.
This python script reads in the lists of particles for each image generated by the python image processing step and outputs a list of steps in "steps.txt" and also images of the particle associations in each step between figures in "match*.png".
# -*- coding: utf-8 -*-
import numpy as np
import pylab as plt
from glob import glob
#Adjustable parameters:
image_width=1600
image_height=1200
min_pix = 40 #minimum number of pixels a particle must have
max_dist = 60 #particle association radius (pixel units)
max_pix_diff = 10 #maximum difference in pixel count in particle association
max_num_steps = 120 #maximum number of steps to find (b/f removing outliers)
outlier_threshold = 35 #maximum dx or dy allowed for step consult ...
# xy_step_histogram.png & variance calculation. ...
# For ~100 steps a 3.5 sigma cut seems reasonable.
#Read in the particle locations and pixel count for all images
filelist = glob('*.txt')
particle_lists=[] #list of lists for all images
for filename in filelist:
particle_lists.append(np.loadtxt(filename))
dx = []
dy = []
for i in range(len(particle_lists)-1):
print "Processing steps between %s and %s." % (filelist[i], filelist[i+1])
for p1 in particle_lists[i]:
displacements = []
if p1[2] < min_pix: #Skip if pixels in p1 are too few
continue
for p2 in particle_lists[i+1]:
if p2[2] <= min_pix: #Skip if pixels in p2 are too few
continue
if abs(p1[2]-p2[2])>max_pix_diff:
continue
dist = np.sqrt((p1[0]-p2[0])**2 + (p1[1]-p2[1])**2)
if dist <= max_dist: # Are p1 and p2 associated?
displacements.append([(p1[0]-p2[0]),(p1[1]-p2[1])])
#Veto p1 if it has no associations or if it has more than one
if len(displacements)==0 or len(displacements) > 1:
#print displacements
continue
#Otherwise we've found a good association! Record the displacements.
dy.append(displacements[0][0])
dx.append(displacements[0][1])
#Plot the association in a scatter plot "matches*.png"
plt.scatter([p1[1], (p1[1]-dx[-1])], [image_height- p1[0],image_height-(p1[0]-dy[-1])])
plt.xlim([0,image_width])
plt.ylim([0,image_height])
if len(dx)>max_num_steps: #Stop after we have 100
break
if len(dx)>max_num_steps: #Stop after we have 100
break
plt.savefig('matches_%s_%s.png' % (filelist[i].split('.')[0],filelist[i+1].split('.')[0]))
plt.clf()
plt.clf()
#Convert from list type to numpy array and calibrate
dx = np.array(dx)
dy = np.array(dy)
print "Standard deviation in dx:", dx.std()
print "Standard deviation in dy:", dy.std()
#Plot histograms
plt.hist(dx, bins=15, range=[-max_dist,max_dist], histtype='step', color='blue', label=r'$\Delta$x')
plt.hist(dy, bins=15, range=[-max_dist,max_dist], histtype='step', color='red', label=r'$\Delta$y')
plt.xlabel('Distance (pixels)')
plt.legend()
plt.savefig('xy_step_histogram.png')
plt.clf()
#Remove outlier steps: require dx AND dy be less than outlier threshold
inds = np.where((abs(dx)<outlier_threshold)*(abs(dy)<outlier_threshold))
dx = dx[inds]
dy = dy[inds]
print "%d steps remain after outlier cut." % len(dx)
#Write out steps:
np.savetxt('steps.txt', np.array([dx,dy]).transpose())