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# Ultralytics YOLO 🚀, AGPL-3.0 license
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import copy
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import cv2
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import numpy as np
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from ultralytics.utils import LOGGER
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class GMC:
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"""
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Generalized Motion Compensation (GMC) class for tracking and object detection in video frames.
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This class provides methods for tracking and detecting objects based on several tracking algorithms including ORB,
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SIFT, ECC, and Sparse Optical Flow. It also supports downscaling of frames for computational efficiency.
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Attributes:
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method (str): The method used for tracking. Options include 'orb', 'sift', 'ecc', 'sparseOptFlow', 'none'.
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downscale (int): Factor by which to downscale the frames for processing.
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prevFrame (np.array): Stores the previous frame for tracking.
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prevKeyPoints (list): Stores the keypoints from the previous frame.
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prevDescriptors (np.array): Stores the descriptors from the previous frame.
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initializedFirstFrame (bool): Flag to indicate if the first frame has been processed.
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Methods:
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__init__(self, method='sparseOptFlow', downscale=2): Initializes a GMC object with the specified method
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and downscale factor.
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apply(self, raw_frame, detections=None): Applies the chosen method to a raw frame and optionally uses
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provided detections.
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applyEcc(self, raw_frame, detections=None): Applies the ECC algorithm to a raw frame.
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applyFeatures(self, raw_frame, detections=None): Applies feature-based methods like ORB or SIFT to a raw frame.
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applySparseOptFlow(self, raw_frame, detections=None): Applies the Sparse Optical Flow method to a raw frame.
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"""
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def __init__(self, method: str = 'sparseOptFlow', downscale: int = 2) -> None:
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"""
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Initialize a video tracker with specified parameters.
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Args:
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method (str): The method used for tracking. Options include 'orb', 'sift', 'ecc', 'sparseOptFlow', 'none'.
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downscale (int): Downscale factor for processing frames.
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"""
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super().__init__()
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self.method = method
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self.downscale = max(1, int(downscale))
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if self.method == 'orb':
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self.detector = cv2.FastFeatureDetector_create(20)
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self.extractor = cv2.ORB_create()
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self.matcher = cv2.BFMatcher(cv2.NORM_HAMMING)
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elif self.method == 'sift':
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self.detector = cv2.SIFT_create(nOctaveLayers=3, contrastThreshold=0.02, edgeThreshold=20)
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self.extractor = cv2.SIFT_create(nOctaveLayers=3, contrastThreshold=0.02, edgeThreshold=20)
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self.matcher = cv2.BFMatcher(cv2.NORM_L2)
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elif self.method == 'ecc':
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number_of_iterations = 5000
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termination_eps = 1e-6
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self.warp_mode = cv2.MOTION_EUCLIDEAN
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self.criteria = (cv2.TERM_CRITERIA_EPS | cv2.TERM_CRITERIA_COUNT, number_of_iterations, termination_eps)
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elif self.method == 'sparseOptFlow':
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self.feature_params = dict(maxCorners=1000,
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qualityLevel=0.01,
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minDistance=1,
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blockSize=3,
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useHarrisDetector=False,
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k=0.04)
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elif self.method in ['none', 'None', None]:
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self.method = None
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else:
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raise ValueError(f'Error: Unknown GMC method:{method}')
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self.prevFrame = None
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self.prevKeyPoints = None
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self.prevDescriptors = None
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self.initializedFirstFrame = False
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def apply(self, raw_frame: np.array, detections: list = None) -> np.array:
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"""
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Apply object detection on a raw frame using specified method.
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Args:
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raw_frame (np.array): The raw frame to be processed.
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detections (list): List of detections to be used in the processing.
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Returns:
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(np.array): Processed frame.
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Examples:
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>>> gmc = GMC()
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>>> gmc.apply(np.array([[1, 2, 3], [4, 5, 6]]))
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array([[1, 2, 3],
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[4, 5, 6]])
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"""
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if self.method in ['orb', 'sift']:
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return self.applyFeatures(raw_frame, detections)
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elif self.method == 'ecc':
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return self.applyEcc(raw_frame, detections)
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elif self.method == 'sparseOptFlow':
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return self.applySparseOptFlow(raw_frame, detections)
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else:
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return np.eye(2, 3)
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def applyEcc(self, raw_frame: np.array, detections: list = None) -> np.array:
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"""
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Apply ECC algorithm to a raw frame.
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Args:
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raw_frame (np.array): The raw frame to be processed.
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detections (list): List of detections to be used in the processing.
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Returns:
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(np.array): Processed frame.
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Examples:
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>>> gmc = GMC()
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>>> gmc.applyEcc(np.array([[1, 2, 3], [4, 5, 6]]))
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array([[1, 2, 3],
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[4, 5, 6]])
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"""
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height, width, _ = raw_frame.shape
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frame = cv2.cvtColor(raw_frame, cv2.COLOR_BGR2GRAY)
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H = np.eye(2, 3, dtype=np.float32)
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# Downscale image
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if self.downscale > 1.0:
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frame = cv2.GaussianBlur(frame, (3, 3), 1.5)
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frame = cv2.resize(frame, (width // self.downscale, height // self.downscale))
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width = width // self.downscale
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height = height // self.downscale
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# Handle first frame
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if not self.initializedFirstFrame:
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# Initialize data
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self.prevFrame = frame.copy()
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# Initialization done
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self.initializedFirstFrame = True
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return H
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# Run the ECC algorithm. The results are stored in warp_matrix.
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# (cc, H) = cv2.findTransformECC(self.prevFrame, frame, H, self.warp_mode, self.criteria)
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try:
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(cc, H) = cv2.findTransformECC(self.prevFrame, frame, H, self.warp_mode, self.criteria, None, 1)
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except Exception as e:
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LOGGER.warning(f'WARNING: find transform failed. Set warp as identity {e}')
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return H
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def applyFeatures(self, raw_frame: np.array, detections: list = None) -> np.array:
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"""
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Apply feature-based methods like ORB or SIFT to a raw frame.
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Args:
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raw_frame (np.array): The raw frame to be processed.
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detections (list): List of detections to be used in the processing.
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Returns:
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(np.array): Processed frame.
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Examples:
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>>> gmc = GMC()
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>>> gmc.applyFeatures(np.array([[1, 2, 3], [4, 5, 6]]))
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array([[1, 2, 3],
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[4, 5, 6]])
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"""
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height, width, _ = raw_frame.shape
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frame = cv2.cvtColor(raw_frame, cv2.COLOR_BGR2GRAY)
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H = np.eye(2, 3)
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# Downscale image
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if self.downscale > 1.0:
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frame = cv2.resize(frame, (width // self.downscale, height // self.downscale))
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width = width // self.downscale
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height = height // self.downscale
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# Find the keypoints
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mask = np.zeros_like(frame)
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mask[int(0.02 * height):int(0.98 * height), int(0.02 * width):int(0.98 * width)] = 255
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if detections is not None:
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for det in detections:
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tlbr = (det[:4] / self.downscale).astype(np.int_)
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mask[tlbr[1]:tlbr[3], tlbr[0]:tlbr[2]] = 0
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keypoints = self.detector.detect(frame, mask)
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# Compute the descriptors
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keypoints, descriptors = self.extractor.compute(frame, keypoints)
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# Handle first frame
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if not self.initializedFirstFrame:
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# Initialize data
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self.prevFrame = frame.copy()
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self.prevKeyPoints = copy.copy(keypoints)
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self.prevDescriptors = copy.copy(descriptors)
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# Initialization done
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self.initializedFirstFrame = True
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return H
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# Match descriptors
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knnMatches = self.matcher.knnMatch(self.prevDescriptors, descriptors, 2)
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# Filter matches based on smallest spatial distance
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matches = []
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spatialDistances = []
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maxSpatialDistance = 0.25 * np.array([width, height])
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# Handle empty matches case
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if len(knnMatches) == 0:
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# Store to next iteration
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self.prevFrame = frame.copy()
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self.prevKeyPoints = copy.copy(keypoints)
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self.prevDescriptors = copy.copy(descriptors)
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return H
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for m, n in knnMatches:
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if m.distance < 0.9 * n.distance:
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prevKeyPointLocation = self.prevKeyPoints[m.queryIdx].pt
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currKeyPointLocation = keypoints[m.trainIdx].pt
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spatialDistance = (prevKeyPointLocation[0] - currKeyPointLocation[0],
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prevKeyPointLocation[1] - currKeyPointLocation[1])
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if (np.abs(spatialDistance[0]) < maxSpatialDistance[0]) and \
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(np.abs(spatialDistance[1]) < maxSpatialDistance[1]):
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spatialDistances.append(spatialDistance)
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matches.append(m)
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meanSpatialDistances = np.mean(spatialDistances, 0)
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stdSpatialDistances = np.std(spatialDistances, 0)
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inliers = (spatialDistances - meanSpatialDistances) < 2.5 * stdSpatialDistances
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goodMatches = []
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prevPoints = []
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currPoints = []
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for i in range(len(matches)):
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if inliers[i, 0] and inliers[i, 1]:
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goodMatches.append(matches[i])
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prevPoints.append(self.prevKeyPoints[matches[i].queryIdx].pt)
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currPoints.append(keypoints[matches[i].trainIdx].pt)
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prevPoints = np.array(prevPoints)
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currPoints = np.array(currPoints)
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# Draw the keypoint matches on the output image
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# if False:
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# import matplotlib.pyplot as plt
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# matches_img = np.hstack((self.prevFrame, frame))
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# matches_img = cv2.cvtColor(matches_img, cv2.COLOR_GRAY2BGR)
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# W = np.size(self.prevFrame, 1)
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# for m in goodMatches:
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# prev_pt = np.array(self.prevKeyPoints[m.queryIdx].pt, dtype=np.int_)
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# curr_pt = np.array(keypoints[m.trainIdx].pt, dtype=np.int_)
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# curr_pt[0] += W
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# color = np.random.randint(0, 255, 3)
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# color = (int(color[0]), int(color[1]), int(color[2]))
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#
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# matches_img = cv2.line(matches_img, prev_pt, curr_pt, tuple(color), 1, cv2.LINE_AA)
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# matches_img = cv2.circle(matches_img, prev_pt, 2, tuple(color), -1)
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# matches_img = cv2.circle(matches_img, curr_pt, 2, tuple(color), -1)
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#
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# plt.figure()
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# plt.imshow(matches_img)
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# plt.show()
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# Find rigid matrix
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if (np.size(prevPoints, 0) > 4) and (np.size(prevPoints, 0) == np.size(prevPoints, 0)):
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H, inliers = cv2.estimateAffinePartial2D(prevPoints, currPoints, cv2.RANSAC)
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# Handle downscale
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if self.downscale > 1.0:
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H[0, 2] *= self.downscale
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H[1, 2] *= self.downscale
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else:
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LOGGER.warning('WARNING: not enough matching points')
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# Store to next iteration
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self.prevFrame = frame.copy()
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self.prevKeyPoints = copy.copy(keypoints)
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self.prevDescriptors = copy.copy(descriptors)
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return H
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def applySparseOptFlow(self, raw_frame: np.array, detections: list = None) -> np.array:
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"""
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Apply Sparse Optical Flow method to a raw frame.
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Args:
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raw_frame (np.array): The raw frame to be processed.
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detections (list): List of detections to be used in the processing.
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Returns:
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(np.array): Processed frame.
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Examples:
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>>> gmc = GMC()
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>>> gmc.applySparseOptFlow(np.array([[1, 2, 3], [4, 5, 6]]))
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array([[1, 2, 3],
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[4, 5, 6]])
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"""
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height, width, _ = raw_frame.shape
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frame = cv2.cvtColor(raw_frame, cv2.COLOR_BGR2GRAY)
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H = np.eye(2, 3)
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# Downscale image
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if self.downscale > 1.0:
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frame = cv2.resize(frame, (width // self.downscale, height // self.downscale))
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# Find the keypoints
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keypoints = cv2.goodFeaturesToTrack(frame, mask=None, **self.feature_params)
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# Handle first frame
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if not self.initializedFirstFrame:
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self.prevFrame = frame.copy()
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self.prevKeyPoints = copy.copy(keypoints)
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self.initializedFirstFrame = True
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return H
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# Find correspondences
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matchedKeypoints, status, err = cv2.calcOpticalFlowPyrLK(self.prevFrame, frame, self.prevKeyPoints, None)
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# Leave good correspondences only
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prevPoints = []
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currPoints = []
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for i in range(len(status)):
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if status[i]:
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prevPoints.append(self.prevKeyPoints[i])
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currPoints.append(matchedKeypoints[i])
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prevPoints = np.array(prevPoints)
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currPoints = np.array(currPoints)
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# Find rigid matrix
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if np.size(prevPoints, 0) > 4 and np.size(prevPoints, 0) == np.size(prevPoints, 0):
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H, inliers = cv2.estimateAffinePartial2D(prevPoints, currPoints, cv2.RANSAC)
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if self.downscale > 1.0:
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H[0, 2] *= self.downscale
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H[1, 2] *= self.downscale
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else:
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LOGGER.warning('WARNING: not enough matching points')
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self.prevFrame = frame.copy()
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|
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self.prevKeyPoints = copy.copy(keypoints)
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|
|
|
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return H
|
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|
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|
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def reset_params(self) -> None:
|
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|
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"""Reset parameters."""
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|
|
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self.prevFrame = None
|
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|
|
self.prevKeyPoints = None
|
|
|
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self.prevDescriptors = None
|
|
|
|
self.initializedFirstFrame = False
|