#!/usr/bin/env python3 from pathlib import Path import sys import cv2 import depthai as dai import numpy as np # Get argument first nnPath = str((Path(__file__).parent / Path('../models/mobilenet-ssd_openvino_2021.4_5shave.blob')).resolve().absolute()) if len(sys.argv) > 1: nnPath = sys.argv[1] if not Path(nnPath).exists(): import sys raise FileNotFoundError(f'Required file/s not found, please run "{sys.executable} install_requirements.py"') # MobilenetSSD label texts labelMap = ["background", "aeroplane", "bicycle", "bird", "boat", "bottle", "bus", "car", "cat", "chair", "cow", "diningtable", "dog", "horse", "motorbike", "person", "pottedplant", "sheep", "sofa", "train", "tvmonitor"] # Create pipeline pipeline = dai.Pipeline() # Define sources and outputs camRgb = pipeline.create(dai.node.ColorCamera) nn = pipeline.create(dai.node.MobileNetDetectionNetwork) xoutVideo = pipeline.create(dai.node.XLinkOut) xoutPreview = pipeline.create(dai.node.XLinkOut) nnOut = pipeline.create(dai.node.XLinkOut) xoutVideo.setStreamName("video") xoutPreview.setStreamName("preview") nnOut.setStreamName("nn") # Properties camRgb.setPreviewSize(300, 300) # NN input camRgb.setResolution(dai.ColorCameraProperties.SensorResolution.THE_4_K) camRgb.setInterleaved(False) camRgb.setPreviewKeepAspectRatio(False) # Define a neural network that will make predictions based on the source frames nn.setConfidenceThreshold(0.5) nn.setBlobPath(nnPath) nn.setNumInferenceThreads(2) nn.input.setBlocking(False) # Linking camRgb.video.link(xoutVideo.input) camRgb.preview.link(xoutPreview.input) camRgb.preview.link(nn.input) nn.out.link(nnOut.input) # Connect to device and start pipeline with dai.Device(pipeline) as device: # Output queues will be used to get the frames and nn data from the outputs defined above qVideo = device.getOutputQueue(name="video", maxSize=4, blocking=False) qPreview = device.getOutputQueue(name="preview", maxSize=4, blocking=False) qDet = device.getOutputQueue(name="nn", maxSize=4, blocking=False) previewFrame = None videoFrame = None detections = [] # nn data, being the bounding box locations, are in <0..1> range - they need to be normalized with frame width/height def frameNorm(frame, bbox): normVals = np.full(len(bbox), frame.shape[0]) normVals[::2] = frame.shape[1] return (np.clip(np.array(bbox), 0, 1) * normVals).astype(int) def displayFrame(name, frame): color = (255, 0, 0) for detection in detections: bbox = frameNorm(frame, (detection.xmin, detection.ymin, detection.xmax, detection.ymax)) cv2.putText(frame, labelMap[detection.label], (bbox[0] + 10, bbox[1] + 20), cv2.FONT_HERSHEY_TRIPLEX, 0.5, color) cv2.putText(frame, f"{int(detection.confidence * 100)}%", (bbox[0] + 10, bbox[1] + 40), cv2.FONT_HERSHEY_TRIPLEX, 0.5, color) cv2.rectangle(frame, (bbox[0], bbox[1]), (bbox[2], bbox[3]), color, 2) # Show the frame cv2.imshow(name, frame) cv2.namedWindow("video", cv2.WINDOW_NORMAL) cv2.resizeWindow("video", 1280, 720) print("Resize video window with mouse drag!") while True: # Instead of get (blocking), we use tryGet (non-blocking) which will return the available data or None otherwise inVideo = qVideo.tryGet() inPreview = qPreview.tryGet() inDet = qDet.tryGet() if inVideo is not None: videoFrame = inVideo.getCvFrame() if inPreview is not None: previewFrame = inPreview.getCvFrame() if inDet is not None: detections = inDet.detections if videoFrame is not None: displayFrame("video", videoFrame) if previewFrame is not None: displayFrame("preview", previewFrame) if cv2.waitKey(1) == ord('q'): break