brisk

1. #!/usr/bin/env python
2.  
3. '''
4. Affine invariant feature-based image matching sample.
5.  
6. This sample is similar to find_obj.py, but uses the affine transformation
7. space sampling technique, called ASIFT [1]. While the original implementation
8. is based on SIFT, you can try to use SURF or ORB detectors instead. Homography RANSAC
9. is used to reject outliers. Threading is used for faster affine sampling.
10.  
11. [1] http://www.ipol.im/pub/algo/my_affine_sift/
12.  
13. USAGE
14.  asift.py [--feature=<sift|surf|orb|brisk>[-flann]] [ <image1> <image2> ]
15.  
16.  --feature  - Feature to use. Can be sift, surf, orb or brisk. Append '-flann'
17.               to feature name to use Flann-based matcher instead bruteforce.
18.  
19.  Press left mouse button on a feature point to see its mathcing point.
20. '''
21.  
22. import numpy as np
23. import cv2
24.  
25. # built-in modules
26. import itertools as it
27. from multiprocessing.pool import ThreadPool
28.  
29. # local modules
30. from common import Timer
31. from find_obj import init_feature, filter_matches, explore_match
32.  
33.  
34. def affine_skew(tilt, phi, img, mask=None):
35.     '''
36.    affine_skew(tilt, phi, img, mask=None) -> skew_img, skew_mask, Ai
37.  
38.    Ai - is an affine transform matrix from skew_img to img
39.    '''
40.     h, w = img.shape[:2]
41.     if mask is None:
42.         mask = np.zeros((h, w), np.uint8)
43.         mask[:] = 255
44.     A = np.float32([[1, 0, 0], [0, 1, 0]])
45.     if phi != 0.0:
46.         phi = np.deg2rad(phi)
47.         s, c = np.sin(phi), np.cos(phi)
48.         A = np.float32([[c,-s], [ s, c]])
49.         corners = [[0, 0], [w, 0], [w, h], [0, h]]
50.         tcorners = np.int32( np.dot(corners, A.T) )
51.         x, y, w, h = cv2.boundingRect(tcorners.reshape(1,-1,2))
52.         A = np.hstack([A, [[-x], [-y]]])
53.         img = cv2.warpAffine(img, A, (w, h), flags=cv2.INTER_LINEAR, borderMode=cv2.BORDER_REPLICATE)
54.     if tilt != 1.0:
55.         s = 0.8*np.sqrt(tilt*tilt-1)
56.         img = cv2.GaussianBlur(img, (0, 0), sigmaX=s, sigmaY=0.01)
57.         img = cv2.resize(img, (0, 0), fx=1.0/tilt, fy=1.0, interpolation=cv2.INTER_NEAREST)
58.         A[0] /= tilt
59.     if phi != 0.0 or tilt != 1.0:
60.         h, w = img.shape[:2]
61.         mask = cv2.warpAffine(mask, A, (w, h), flags=cv2.INTER_NEAREST)
62.     Ai = cv2.invertAffineTransform(A)
63.     return img, mask, Ai
64.  
65.  
66. def affine_detect(detector, img, mask=None, pool=None):
67.     '''
68.    affine_detect(detector, img, mask=None, pool=None) -> keypoints, descrs
69.  
70.    Apply a set of affine transormations to the image, detect keypoints and
71.    reproject them into initial image coordinates.
72.    See http://www.ipol.im/pub/algo/my_affine_sift/ for the details.
73.  
74.    ThreadPool object may be passed to speedup the computation.
75.    '''
76.     params = [(1.0, 0.0)]
77.     for t in 2**(0.5*np.arange(1,6)):
78.         for phi in np.arange(0, 180, 72.0 / t):
79.             params.append((t, phi))
80.  
81.     def f(p):
82.         t, phi = p
83.         timg, tmask, Ai = affine_skew(t, phi, img)
84.         keypoints, descrs = detector.detectAndCompute(timg, tmask)
85.         for kp in keypoints:
86.             x, y = kp.pt
87.             kp.pt = tuple( np.dot(Ai, (x, y, 1)) )
88.         if descrs is None:
89.             descrs = []
90.         return keypoints, descrs
91.  
92.     keypoints, descrs = [], []
93.     if pool is None:
94.         ires = it.imap(f, params)
95.     else:
96.         ires = pool.imap(f, params)
97.  
98.     for i, (k, d) in enumerate(ires):
99.         print 'affine sampling: %d / %d\r' % (i+1, len(params)),
100.         keypoints.extend(k)
101.         descrs.extend(d)
102.  
103.     print
104.     return keypoints, np.array(descrs)
105.  
106. if __name__ == '__main__':
107.     print __doc__
108.  
109.     import sys, getopt
110.     opts, args = getopt.getopt(sys.argv[1:], '', ['feature='])
111.     opts = dict(opts)
112.     feature_name = opts.get('--feature', 'sift-flann')
113.     try:
114.         fn1, fn2 = args
115.     except:
116.         fn1 = 'data/aero1.jpg'
117.         fn2 = 'data/aero3.jpg'
118.  
119.     img1 = cv2.imread(fn1, 0)
120.     img2 = cv2.imread(fn2, 0)
121.     detector, matcher = init_feature(feature_name)
122.  
123.     if img1 is None:
124.         print 'Failed to load fn1:', fn1
125.         sys.exit(1)
126.  
127.     if img2 is None:
128.         print 'Failed to load fn2:', fn2
129.         sys.exit(1)
130.  
131.     if detector is None:
132.         print 'unknown feature:', feature_name
133.         sys.exit(1)
134.  
135.     print 'using', feature_name
136.  
137.     pool=ThreadPool(processes = cv2.getNumberOfCPUs())
138.     kp1, desc1 = affine_detect(detector, img1, pool=pool)
139.     kp2, desc2 = affine_detect(detector, img2, pool=pool)
140.     print 'img1 - %d features, img2 - %d features' % (len(kp1), len(kp2))
141.  
142.     def match_and_draw(win):
143.         with Timer('matching'):
144.             raw_matches = matcher.knnMatch(desc1, trainDescriptors = desc2, k = 2) #2
145.         p1, p2, kp_pairs = filter_matches(kp1, kp2, raw_matches)
146.         if len(p1) >= 4:
147.             H, status = cv2.findHomography(p1, p2, cv2.RANSAC, 5.0)
148.             print '%d / %d  inliers/matched' % (np.sum(status), len(status))
149.             # do not draw outliers (there will be a lot of them)
150.             kp_pairs = [kpp for kpp, flag in zip(kp_pairs, status) if flag]
151.         else:
152.             H, status = None, None
153.             print '%d matches found, not enough for homography estimation' % len(p1)
154.  
155.         vis = explore_match(win, img1, img2, kp_pairs, None, H)
156.  
157.  
158.     match_and_draw('affine find_obj')
159.     cv2.waitKey()
160.     cv2.destroyAllWindows()