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145 lines
4.9 KiB
145 lines
4.9 KiB
#!/usr/bin/env python |
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''' |
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Affine invariant feature-based image matching sample. |
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This sample is similar to find_obj.py, but uses the affine transformation |
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space sampling technique, called ASIFT [1]. While the original implementation |
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is based on SIFT, you can try to use SURF or ORB detectors instead. Homography RANSAC |
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is used to reject outliers. Threading is used for faster affine sampling. |
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[1] http://www.ipol.im/pub/algo/my_affine_sift/ |
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USAGE |
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asift.py [--feature=<sift|surf|orb>[-flann]] [ <image1> <image2> ] |
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--feature - Feature to use. Can be sift, surf of orb. Append '-flann' to feature name |
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to use Flann-based matcher instead bruteforce. |
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Press left mouse button on a feature point to see its mathcing point. |
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''' |
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import numpy as np |
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import cv2 |
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import itertools as it |
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from multiprocessing.pool import ThreadPool |
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from common import Timer |
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from find_obj import init_feature, filter_matches, explore_match |
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def affine_skew(tilt, phi, img, mask=None): |
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''' |
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affine_skew(tilt, phi, img, mask=None) -> skew_img, skew_mask, Ai |
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Ai - is an affine transform matrix from skew_img to img |
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''' |
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h, w = img.shape[:2] |
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if mask is None: |
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mask = np.zeros((h, w), np.uint8) |
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mask[:] = 255 |
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A = np.float32([[1, 0, 0], [0, 1, 0]]) |
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if phi != 0.0: |
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phi = np.deg2rad(phi) |
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s, c = np.sin(phi), np.cos(phi) |
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A = np.float32([[c,-s], [ s, c]]) |
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corners = [[0, 0], [w, 0], [w, h], [0, h]] |
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tcorners = np.int32( np.dot(corners, A.T) ) |
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x, y, w, h = cv2.boundingRect(tcorners.reshape(1,-1,2)) |
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A = np.hstack([A, [[-x], [-y]]]) |
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img = cv2.warpAffine(img, A, (w, h), flags=cv2.INTER_LINEAR, borderMode=cv2.BORDER_REPLICATE) |
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if tilt != 1.0: |
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s = 0.8*np.sqrt(tilt*tilt-1) |
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img = cv2.GaussianBlur(img, (0, 0), sigmaX=s, sigmaY=0.01) |
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img = cv2.resize(img, (0, 0), fx=1.0/tilt, fy=1.0, interpolation=cv2.INTER_NEAREST) |
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A[0] /= tilt |
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if phi != 0.0 or tilt != 1.0: |
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h, w = img.shape[:2] |
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mask = cv2.warpAffine(mask, A, (w, h), flags=cv2.INTER_NEAREST) |
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Ai = cv2.invertAffineTransform(A) |
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return img, mask, Ai |
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def affine_detect(detector, img, mask=None, pool=None): |
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''' |
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affine_detect(detector, img, mask=None, pool=None) -> keypoints, descrs |
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Apply a set of affine transormations to the image, detect keypoints and |
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reproject them into initial image coordinates. |
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See http://www.ipol.im/pub/algo/my_affine_sift/ for the details. |
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ThreadPool object may be passed to speedup the computation. |
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''' |
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params = [(1.0, 0.0)] |
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for t in 2**(0.5*np.arange(1,6)): |
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for phi in np.arange(0, 180, 72.0 / t): |
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params.append((t, phi)) |
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def f(p): |
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t, phi = p |
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timg, tmask, Ai = affine_skew(t, phi, img) |
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keypoints, descrs = detector.detectAndCompute(timg, tmask) |
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for kp in keypoints: |
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x, y = kp.pt |
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kp.pt = tuple( np.dot(Ai, (x, y, 1)) ) |
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if descrs is None: |
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descrs = [] |
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return keypoints, descrs |
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keypoints, descrs = [], [] |
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if pool is None: |
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ires = it.imap(f, params) |
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else: |
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ires = pool.imap(f, params) |
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for i, (k, d) in enumerate(ires): |
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print 'affine sampling: %d / %d\r' % (i+1, len(params)), |
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keypoints.extend(k) |
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descrs.extend(d) |
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print |
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return keypoints, np.array(descrs) |
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if __name__ == '__main__': |
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print __doc__ |
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import sys, getopt |
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opts, args = getopt.getopt(sys.argv[1:], '', ['feature=']) |
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opts = dict(opts) |
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feature_name = opts.get('--feature', 'sift-flann') |
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try: fn1, fn2 = args |
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except: |
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fn1 = 'data/aero1.jpg' |
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fn2 = 'data/aero3.jpg' |
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img1 = cv2.imread(fn1, 0) |
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img2 = cv2.imread(fn2, 0) |
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detector, matcher = init_feature(feature_name) |
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if detector != None: |
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print 'using', feature_name |
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else: |
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print 'unknown feature:', feature_name |
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sys.exit(1) |
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pool=ThreadPool(processes = cv2.getNumberOfCPUs()) |
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kp1, desc1 = affine_detect(detector, img1, pool=pool) |
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kp2, desc2 = affine_detect(detector, img2, pool=pool) |
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print 'img1 - %d features, img2 - %d features' % (len(kp1), len(kp2)) |
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def match_and_draw(win): |
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with Timer('matching'): |
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raw_matches = matcher.knnMatch(desc1, trainDescriptors = desc2, k = 2) #2 |
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p1, p2, kp_pairs = filter_matches(kp1, kp2, raw_matches) |
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if len(p1) >= 4: |
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H, status = cv2.findHomography(p1, p2, cv2.RANSAC, 5.0) |
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print '%d / %d inliers/matched' % (np.sum(status), len(status)) |
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# do not draw outliers (there will be a lot of them) |
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kp_pairs = [kpp for kpp, flag in zip(kp_pairs, status) if flag] |
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else: |
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H, status = None, None |
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print '%d matches found, not enough for homography estimation' % len(p1) |
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vis = explore_match(win, img1, img2, kp_pairs, None, H) |
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match_and_draw('affine find_obj') |
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cv2.waitKey() |
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cv2.destroyAllWindows() |
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