jetson NanoCamera(使用)
jetson NanoCamera(USB摄像头连接)上篇文章简单的分析了,使用USB摄像头捕获视频流的内部过程。今天这篇文章算是最后的一篇使用文,会从现在拥有的功能,安装,使用等方面描述一下.
OpenCV已经准备好了。可以使用OpenCV imshow直接调用图像文件
获得图像文件是一个NumPy RGB数组。
支持不同的相机翻转模式(逆时针,旋转180度,顺时针-90度,水平翻转,垂直翻转)
可以与多台摄像机一起使用。
支持帧速率执行。*仅适用于USB,RTSP和IP / MJPEG相机。
帧速率强制使用GStreamer视频速率插件确保摄像机以给定的帧速率工作
它基于加速的GStreamer插件
应与其他Jetson板卡(如Jetson TX1,TX2等)配合使用(未测试)
同时支持硬件和CPU加速。
轻松读取图像作为
numpy数组image = camera.read()支持线程读取-适用于所有类型的相机。要启用快速线程读取,您将启用implement_fps:
enforce_fps = True使用
isReady()功能初始化后,请检查摄像机的状态。True如果准备就绪,False否则返回。提供调试支持。添加了错误代码和可选的异常处理。如果出现问题,可以重新启动摄像头;如果摄像头出现故障,则可以发送使用者通知。
使用
device_id参数支持多个CSI摄像机。
以上内容为支持的功能,而且一部分功能需要opencv的帮助:
pip3 install opencv-python 安装一下
pip3 install nanocamera pip安装
git clone https://github.com/thehapyone/NanoCameracd NanoCamerasudo python3 setup.py install源码安装。
接下来讲解使用过程:
CSI摄像头的使用
import nanocamera as nano# Create the Camera instance for 640 by 480camera = nano.Camera()需要设置为camera_type = 0.默认是FPS 30,大小为640x480,而且不旋转
flip = 0.
自定义高度,宽度
import nanocamera as nano# Create the Camera instance for No rotation (flip=0) with size of 1280 by 800camera = nano.Camera(flip=0, width=1280, height=800, fps=30)多个CSI摄像头的使用:
import nanocamera as nano# Create the Camera instance for No rotation (flip=0) with size of 1280 by 800# Connect to CSI camera with ID 0 (Default)camera_1 = nano.Camera(device_id=0, flip=0, width=1280, height=800, fps=30)# Connect to another CSI camera on the board with ID 1camera_2 = nano.Camera(device_id=1, flip=0, width=1280, height=800, fps=30)用camera_id来指定。
使用USB摄像头:
import nanocamera as nano# Create the Camera instance for No rotation (flip=0) with size of 640 by 480camera = nano.Camera(camera_type=1, device_id=1, width=640, height=480, fps=30)相机种类为1,设备的id也得填入。
ls /dev/video*在linux系统下执行这个命令看自己的摄像头名字。
RTSP的摄像头使用下面的代码来设置:
# a location for the rtsp stream. Stream location without "rtsp://"rtsp_location = "192.168.1.26:8554/stream"# Create the Camera instancecamera = nano.Camera(camera_type=2, source=rtsp_location, width=640, height=480, fps=30)
种类为2,而且要设置source
rtsp_location = "192.168.1.26:8554/stream"还有一种摄像头是IP、MJPMG的摄像头或者照片:
# a location for the camera stream. Stream location without "http://"camera_stream = "192.168.1.26:80/stream"# Create the Camera instancecamera = nano.Camera(camera_type=3, source=camera_stream, width=640, height=480, fps=30)
记得把相机的种类设置为3,流媒体的source也要打开
camera_stream = "192.168.1.26:80/stream"特别要需要知道自己的相机的位置所在。
这个代码可以让你的相机强制一个速率来获得帧
import nanocamera as nano# enforce the capture frame rate with the enforce_fps=Truecamera = nano.Camera(camera_type=1, device_id=1, width=640, height=480, fps=30, enforce_fps=True)读取视频流的代码:
frame = camera.read()获得的格式是numpy.ndarray(),格式为BGR,这个转换写过很多了,自己感兴趣的可以看看
在这么多传输的流程里面,一定要一直确保相机的正常使用,所以有保证相机运行正常的代码
status = camera.isReady()接下来会给出SCI相机的连接代码:
import cv2#from nanocamera.NanoCam import Cameraimport nanocamera as nano
if __name__ == '__main__': # Create the Camera instance camera = nano.Camera(flip=0, width=640, height=480, fps=30) print('CSI Camera ready? - ', camera.isReady()) while camera.isReady(): try: # read the camera image frame = camera.read() # display the frame cv2.imshow("Video Frame", frame) if cv2.waitKey(25) & 0xFF == ord('q'): break except KeyboardInterrupt: break
# close the camera instance camera.release()
# remove camera object del camera
IP/MPJEG的代码:
import cv2# from nanocamera.NanoCam import Cameraimport nanocamera as nanoif __name__ == '__main__': # requires the Camera streaming url. Something like this: http://localhost:80/stream # For IP/MJPEG camera, the camera_type=3. # This works with only camera steaming MJPEG format and not H.264 codec for now # a location for the camera stream camera_stream = "192.168.1.26:80" # Create the Camera instance camera = nano.Camera(camera_type=3, source=camera_stream, width=640, height=480, fps=30) print('MJPEG/IP Camera is now ready') while camera.isReady(): try: # read the camera image frame = camera.read() # display the frame cv2.imshow("Video Frame", frame) if cv2.waitKey(25) & 0xFF == ord('q'): break except KeyboardInterrupt: break # close the camera instance camera.release() # remove camera object del camera
其实这些代码都没哟什么好说的,都是建立一个对象,按规则初始化,然后就是CV2接管来进行渲染输出等。
这个库最好的地方在于它的可调试性,不是说它的调试功能多强大,而是夸它的实现。
如果你在代码中使用了:
camere.hasError()这个代码,会在所有的有错误的地方打印错误的代码的列表和布尔值
# status holds a list.status = camera.hasError()print (status)>> ([0, 3], True)print ("错误代码列表 : ", status[0])>> Error codes list : [0, 3]print ("Error State : ", status[1])>> Error State: True
错误的代码是:
'''-1 = Unknown error0 = No error1 = Error: Could not initialize camera.2 = Thread Error: Could not read image from camera3 = Error: Could not read image from camera4 = Error: Could not release camera'''
在写一个例子:
error_status = camera.hasError()if error_status[1] == False: # means no error detected so far # read the camera image frame = camera.read() # print the current error codes print (error_status[0]) # display the frame cv2.imshow("Video Frame", frame) if cv2.waitKey(25) & 0xFF == ord('q'): breakelse: # an error has occured. print ("An error with the camera. Error code : ", error_status[0])
debug开关先使能,一般来说其实是调试多线程的应用。
接下来的例子是一个开发时的样板例子:
if __name__ == '__main__': # with debug=True. An Exception will be raised if something goes wrong. # Create the Camera instance try: # Create the Camera instance print("camera stream") camera = nano.Camera(camera_type=1, device_id=0, fps=30, debug=True) except Exception as e: # handle the exception from opening camera session else: print('USB Camera ready? - ', camera.isReady()) while True: try: # read the camera image frame = camera.read() # do something with frame like: send_to_cloud(frame) except KeyboardInterrupt: break except Exception as e: # handle the exception from reading break print("done here") try: # close the camera instance camera.release() except Exception as e: # handle the exception from releasing the camera 自定义了错误的等级:
The except cause might catch the following exceptions:>> Exception Type - Error: Could not initialize USB Camera>> Exception Type - An error as occurred. Error Value: [0, 3]>> Exception Type - Unknown Error has occurred>> Exception Type - Error: Could not release camera这个就是抛出的东西,可以看到到底是哪里出了毛病。
大概就是这么多了,接下来的话,就是去机器上面运行了~