recognize.py

# import the necessary packages
from imutils.video import VideoStream
import numpy as np
import imutils
import pickle
import time
import cv2
import os


#path to OpenCV's deep learning face detector
detector_path = './face_detection_model'

#path to OpenCV's deep learning face embedding model
embedding_model = './openface_nn4.small2.v1.t7'


#path to model trained to recognize faces
recognizer_path = './output/recognizer.pickle'

#path to label encoder
le_path = './output/le.pickle'

#minimum probability to filter weak detections
Confidence = 0.5




# load our serialized face detector from disk
print("[INFO] loading face detector...")
protoPath = os.path.sep.join([detector_path, "deploy.prototxt"])
modelPath = os.path.sep.join([detector_path,
	"res10_300x300_ssd_iter_140000.caffemodel"])
detector = cv2.dnn.readNetFromCaffe(protoPath, modelPath)

# load our serialized face embedding model from disk
print("[INFO] loading face recognizer...")
embedder = cv2.dnn.readNetFromTorch(embedding_model)

# load the actual face recognition model along with the label encoder
recognizer = pickle.loads(open(recognizer_path, "rb").read())
le = pickle.loads(open(le_path, "rb").read())

# initialize the video stream, then allow the camera sensor to warm up
print("[INFO] starting video stream...")
vs = VideoStream(src=0).start()
time.sleep(2.0)



# loop over frames from the video file stream
while True:
	# grab the frame from the threaded video stream
	frame = vs.read()

	# resize the frame to have a width of 600 pixels (while
	# maintaining the aspect ratio), and then grab the image
	# dimensions
	frame = imutils.resize(frame, width=600)
	(h, w) = frame.shape[:2]

	# construct a blob from the image
	imageBlob = cv2.dnn.blobFromImage(
		cv2.resize(frame, (300, 300)), 1.0, (300, 300),
		(104.0, 177.0, 123.0), swapRB=False, crop=False)

	# apply OpenCV's deep learning-based face detector to localize
	# faces in the input image
	detector.setInput(imageBlob)
	detections = detector.forward()

	# loop over the detections
	for i in range(0, detections.shape[2]):
		# extract the confidence (i.e., probability) associated with
		# the prediction
		confidence = detections[0, 0, i, 2]

		# filter out weak detections
		if confidence > Confidence:
			# compute the (x, y)-coordinates of the bounding box for
			# the face
			box = detections[0, 0, i, 3:7] * np.array([w, h, w, h])
			(startX, startY, endX, endY) = box.astype("int")

			# extract the face ROI
			face = frame[startY:endY, startX:endX]
			(fH, fW) = face.shape[:2]

			# ensure the face width and height are sufficiently large
			if fW < 20 or fH < 20:
				continue

			# construct a blob for the face ROI, then pass the blob
			# through our face embedding model to obtain the 128-d
			# quantification of the face
			faceBlob = cv2.dnn.blobFromImage(face, 1.0 / 255,
				(96, 96), (0, 0, 0), swapRB=True, crop=False)
			embedder.setInput(faceBlob)
			vec = embedder.forward()

			# perform classification to recognize the face
			preds = recognizer.predict_proba(vec)[0]
			j = np.argmax(preds)
			proba = preds[j]
			name = le.classes_[j]

			# draw the bounding box of the face along with the
			# associated probability
			text = "{}: {:.2f}%".format(name, proba * 100)
			y = startY - 10 if startY - 10 > 10 else startY + 10
			cv2.rectangle(frame, (startX, startY), (endX, endY),
				(0, 0, 255), 2)
			cv2.putText(frame, text, (startX, y),
				cv2.FONT_HERSHEY_SIMPLEX, 0.45, (0, 0, 255), 2)



	# show the output frame
	cv2.imshow("Frame", frame)
	key = cv2.waitKey(1) & 0xFF

	# if the `q` key was pressed, break from the loop
	if key == ord("q"):
		break


# do a bit of cleanup
cv2.destroyAllWindows()
vs.stop()