opencv/samples/python2/plane_tracker.py

import numpy as np
import cv2
from collections import namedtuple
import video
import common


FLANN_INDEX_KDTREE = 1
FLANN_INDEX_LSH    = 6
flann_params= dict(algorithm = FLANN_INDEX_LSH,
                   table_number = 6, # 12
                   key_size = 12,     # 20
                   multi_probe_level = 1) #2

MIN_MATCH_COUNT = 10


PlanarTarget = namedtuple('PlaneTarget', 'image, rect, keypoints, descrs, data')
TrackedTarget = namedtuple('TrackedTarget', 'target, p0, p1, H, quad')

class PlaneTracker:
    def __init__(self):
        self.detector = cv2.ORB( nfeatures = 1000 )
        self.matcher = cv2.FlannBasedMatcher(flann_params, {})  # bug : need to pass empty dict (#1329)
        self.targets = []

    def add_target(self, image, rect, data=None):
        '''Add a new tracking target.'''
        x0, y0, x1, y1 = rect
        raw_points, raw_descrs = self.detect_features(image)
        points, descs = [], []
        for kp, desc in zip(raw_points, raw_descrs):
            x, y = kp.pt
            if x0 <= x <= x1 and y0 <= y <= y1:
                points.append(kp)
                descs.append(desc)
        descs = np.uint8(descs)
        self.matcher.add([descs])
        target = PlanarTarget(image = image, rect=rect, keypoints = points, descrs=descs, data=None)
        self.targets.append(target)

    def clear(self):
        '''Remove all targets'''
        self.targets = []
        self.matcher.clear()

    def track(self, frame):
        '''Returns a list of detected TrackedTarget objects'''
        self.frame_points, self.frame_descrs = self.detect_features(frame)
        if len(self.frame_points) < MIN_MATCH_COUNT:
            return []
        matches = self.matcher.knnMatch(self.frame_descrs, k = 2)
        matches = [m[0] for m in matches if len(m) == 2 and m[0].distance < m[1].distance * 0.75]
        if len(matches) < MIN_MATCH_COUNT:
            return []
        matches_by_id = [[] for _ in xrange(len(self.targets))]
        for m in matches:
            matches_by_id[m.imgIdx].append(m)
        tracked = []
        for imgIdx, matches in enumerate(matches_by_id):
            if len(matches) < MIN_MATCH_COUNT:
                continue
            target = self.targets[imgIdx]
            p0 = [target.keypoints[m.trainIdx].pt for m in matches]
            p1 = [self.frame_points[m.queryIdx].pt for m in matches]
            p0, p1 = np.float32((p0, p1))
            H, status = cv2.findHomography(p0, p1, cv2.RANSAC, 3.0)
            status = status.ravel() != 0
            if status.sum() < MIN_MATCH_COUNT:
                continue
            p0, p1 = p0[status], p1[status]
            
            x0, y0, x1, y1 = target.rect
            quad = np.float32([[x0, y0], [x1, y0], [x1, y1], [x0, y1]])
            quad = cv2.perspectiveTransform(quad.reshape(1, -1, 2), H).reshape(-1, 2)

            track = TrackedTarget(target=target, p0=p0, p1=p1, H=H, quad=quad)
            tracked.append(track)
        tracked.sort(key = lambda t: len(t.p0), reverse=True)
        return tracked

    def detect_features(self, frame):
        '''detect_features(self, frame) -> keypoints, descrs'''
        keypoints, descrs = self.detector.detectAndCompute(frame, None)
        if descrs is None:  # detectAndCompute returns descs=None if not keypoints found
            descrs = []
        return keypoints, descrs


class App:
    def __init__(self, src):
        self.cap = video.create_capture(src)
        self.frame = None
        self.paused = False
        self.tracker = PlaneTracker()

        cv2.namedWindow('plane')
        self.rect_sel = common.RectSelector('plane', self.on_rect)
    
    def on_rect(self, rect):
        self.tracker.add_target(self.frame, rect)

    def run(self):
        while True:
            playing = not self.paused and not self.rect_sel.dragging
            if playing or self.frame is None:
                ret, frame = self.cap.read()
                if not ret:
                    break
                self.frame = frame.copy()
            
            vis = self.frame.copy()
            if playing:
                tracked = self.tracker.track(self.frame)
                for tr in tracked:
                    cv2.polylines(vis, [np.int32(tr.quad)], True, (255, 255, 255), 2)
                    for (x, y) in np.int32(tr.p1):
                        cv2.circle(vis, (x, y), 2, (255, 255, 255))

            self.rect_sel.draw(vis)
            cv2.imshow('plane', vis)
            ch = cv2.waitKey(1)
            if ch == ord(' '):
                self.paused = not self.paused
            if ch == ord('c'):
                self.tracker.clear()
            if ch == 27:
                break

if __name__ == '__main__':
    print __doc__

    import sys
    try: video_src = sys.argv[1]
    except: video_src = 0
    App(video_src).run()
created PlaneTracker (int plane_tracker.py), which implements multitarget planar tracking rewritten feature_homography.py using it added plane_ar.py - simple augmented reality sample 12 years ago			`import numpy as np`
			`import cv2`
			`from collections import namedtuple`
			`import video`
			`import common`


			`FLANN_INDEX_KDTREE = 1`
			`FLANN_INDEX_LSH = 6`
			`flann_params= dict(algorithm = FLANN_INDEX_LSH,`
			`table_number = 6, # 12`
			`key_size = 12, # 20`
			`multi_probe_level = 1) #2`

			`MIN_MATCH_COUNT = 10`


			`PlanarTarget = namedtuple('PlaneTarget', 'image, rect, keypoints, descrs, data')`
			`TrackedTarget = namedtuple('TrackedTarget', 'target, p0, p1, H, quad')`

			`class PlaneTracker:`
			`def __init__(self):`
			`self.detector = cv2.ORB( nfeatures = 1000 )`
			`self.matcher = cv2.FlannBasedMatcher(flann_params, {}) # bug : need to pass empty dict (#1329)`
			`self.targets = []`

			`def add_target(self, image, rect, data=None):`
			`'''Add a new tracking target.'''`
			`x0, y0, x1, y1 = rect`
			`raw_points, raw_descrs = self.detect_features(image)`
			`points, descs = [], []`
			`for kp, desc in zip(raw_points, raw_descrs):`
			`x, y = kp.pt`
			`if x0 <= x <= x1 and y0 <= y <= y1:`
			`points.append(kp)`
			`descs.append(desc)`
			`descs = np.uint8(descs)`
			`self.matcher.add([descs])`
			`target = PlanarTarget(image = image, rect=rect, keypoints = points, descrs=descs, data=None)`
			`self.targets.append(target)`

			`def clear(self):`
			`'''Remove all targets'''`
			`self.targets = []`
			`self.matcher.clear()`

			`def track(self, frame):`
			`'''Returns a list of detected TrackedTarget objects'''`
			`self.frame_points, self.frame_descrs = self.detect_features(frame)`
			`if len(self.frame_points) < MIN_MATCH_COUNT:`
			`return []`
			`matches = self.matcher.knnMatch(self.frame_descrs, k = 2)`
			`matches = [m[0] for m in matches if len(m) == 2 and m[0].distance < m[1].distance * 0.75]`
			`if len(matches) < MIN_MATCH_COUNT:`
			`return []`
			`matches_by_id = [[] for _ in xrange(len(self.targets))]`
			`for m in matches:`
			`matches_by_id[m.imgIdx].append(m)`
			`tracked = []`
			`for imgIdx, matches in enumerate(matches_by_id):`
			`if len(matches) < MIN_MATCH_COUNT:`
			`continue`
			`target = self.targets[imgIdx]`
			`p0 = [target.keypoints[m.trainIdx].pt for m in matches]`
			`p1 = [self.frame_points[m.queryIdx].pt for m in matches]`
			`p0, p1 = np.float32((p0, p1))`
			`H, status = cv2.findHomography(p0, p1, cv2.RANSAC, 3.0)`
			`status = status.ravel() != 0`
			`if status.sum() < MIN_MATCH_COUNT:`
			`continue`
			`p0, p1 = p0[status], p1[status]`

			`x0, y0, x1, y1 = target.rect`
			`quad = np.float32([[x0, y0], [x1, y0], [x1, y1], [x0, y1]])`
			`quad = cv2.perspectiveTransform(quad.reshape(1, -1, 2), H).reshape(-1, 2)`

			`track = TrackedTarget(target=target, p0=p0, p1=p1, H=H, quad=quad)`
			`tracked.append(track)`
			`tracked.sort(key = lambda t: len(t.p0), reverse=True)`
			`return tracked`

			`def detect_features(self, frame):`
			`'''detect_features(self, frame) -> keypoints, descrs'''`
			`keypoints, descrs = self.detector.detectAndCompute(frame, None)`
			`if descrs is None: # detectAndCompute returns descs=None if not keypoints found`
			`descrs = []`
			`return keypoints, descrs`


			`class App:`
			`def __init__(self, src):`
			`self.cap = video.create_capture(src)`
			`self.frame = None`
			`self.paused = False`
			`self.tracker = PlaneTracker()`

			`cv2.namedWindow('plane')`
			`self.rect_sel = common.RectSelector('plane', self.on_rect)`

			`def on_rect(self, rect):`
			`self.tracker.add_target(self.frame, rect)`

			`def run(self):`
			`while True:`
			`playing = not self.paused and not self.rect_sel.dragging`
			`if playing or self.frame is None:`
			`ret, frame = self.cap.read()`
			`if not ret:`
			`break`
			`self.frame = frame.copy()`

			`vis = self.frame.copy()`
			`if playing:`
			`tracked = self.tracker.track(self.frame)`
			`for tr in tracked:`
			`cv2.polylines(vis, [np.int32(tr.quad)], True, (255, 255, 255), 2)`
			`for (x, y) in np.int32(tr.p1):`
			`cv2.circle(vis, (x, y), 2, (255, 255, 255))`

			`self.rect_sel.draw(vis)`
			`cv2.imshow('plane', vis)`
			`ch = cv2.waitKey(1)`
			`if ch == ord(' '):`
			`self.paused = not self.paused`
			`if ch == ord('c'):`
			`self.tracker.clear()`
			`if ch == 27:`
			`break`

			`if __name__ == '__main__':`
			`print __doc__`

			`import sys`
			`try: video_src = sys.argv[1]`
			`except: video_src = 0`
			`App(video_src).run()`