コード例 #1
0
ファイル: main.py プロジェクト: parkhojun/KMUADC_2019
from std_msgs.msg import String
from sensor_msgs.msg import Image
from obstacle_detector.msg import Obstacles
from cv_bridge import CvBridge, CvBridgeError

from ackermann_msgs.msg import AckermannDriveStamped
from datetime import datetime # for record

from Stop_Counter import Stop_Counter
from CurveDetector import CurveDetector
from ObstacleDetector import ObstacleDetector, Position

x_location_old = None

warper = Warper()
slidewindow  = SlideWindow()
pidcal = PidCal()

q1 = que.Queue()
bridge = CvBridge()

now = datetime.now() # for record

cv_image = None
obstacles = None
ack_publisher = None
car_run_speed = 0.5

OBSTACLE_NUM = 3

コード例 #2
0
ファイル: inference_unet.py プロジェクト: yxw027/ISCC_2020
def main():
    os.environ["CUDA_VISIBLE_DEVICES"] = '0'
    #cudnn.benchmark = True

    opt = opts.parse()
    warper = Warper()
    slidewindow  = SlideWindow()
    pidcal = PidCal()

    print(("device id: {}".format(torch.cuda.current_device())))
    print("torch.version",torch.__version__)
    print("cuda_version",torch.version.cuda)


    models = importlib.import_module('models.init')
    # print(models)
    criterions = importlib.import_module('criterions.init')
    checkpoints = importlib.import_module('checkpoints')
    Trainer = importlib.import_module('models.' + opt.netType + '-train')

    # Data loading
    print('=> Setting up data loader')
    #trainLoader, valLoader = DataLoader.create(opt)
    #print('opt',opt)

    # Load previous checkpoint, if it exists
    print('=> Checking checkpoints')
    checkpoint = checkpoints.load(opt)

    # Create model
    model, optimState = models.setup(opt, checkpoint)
    model.cuda()

    criterion = criterions.setup(opt, checkpoint, model)

    ##################################################################################
    model.eval()

    cap = cv2.VideoCapture(0)

    if cap.isOpened():
        print("width : {}, height : {}".format(cap.get(3), cap.get(4)))

    video_width = int(cap.get(3))
    video_height = int(cap.get(4))

    fourcc = cv2.VideoWriter_fourcc(*'DIVX')
    video_name = time.time()
    out = cv2.VideoWriter('output_video/{}.avi'.format(video_name), fourcc, 25.0, (video_width,video_height),0)

    prev_time = 0

    fps_list = []


    while True:
        ret, frame = cap.read()

        if ret:
            cur_time = time.time()
            frame = cv2.resize(frame, (480,360))

            input_img = frame / 255.
            input_img = preprocess_img(input_img)

            # array to tensor
            input_img = torch.from_numpy(input_img).float()

            with torch.no_grad():
                inputData_var = Variable(input_img).unsqueeze(0).cuda()

                # inference
                output = model.forward(inputData_var)

                print("output.shape : ", output.shape)

                # gpu -> cpu,  tensor -> numpy
                output = output.detach().cpu().numpy()

                output = output[0]

                output = postprocess_img(output)
                output *= 255
                output = np.clip(output, 0, 255)
                output = np.uint8(output)

                # resize
                output = cv2.resize(output, (640, 480))

                # threshold
                ret, thr_img = cv2.threshold(output, 180, 255, 0)
                # warp
                output, warp_img = warper.warp(output, thr_img)
                img, x_location = slidewindow.slidewindow(warp_img)

                if x_location != None:
                    pid = round(pidcal.pid_control(int(x_location)), 6)
                    print("pid rate : ", pid)
                    auto_drive(pid, x_location)
                else:
                    pid = pidcal.pid_control(320)
                    print("pid rate : ", pid)
                    auto_drive(pid)


                end_time = time.time()
                sec = end_time - cur_time

                fps = 1/sec
                fps_list.append(fps)

                print("Estimated fps {0} " . format(fps))

                out.write(output)

                cv2.imshow("src", frame)


                cv2.imshow("output", output)
                cv2.imshow("thre", img)

                key = cv2.waitKey(1) & 0xFF
                if key == 27: break
                elif key == ord('p'):
                    cv2.waitKey(-1)
コード例 #3
0
def main():
    os.environ["CUDA_VISIBLE_DEVICES"] = '0'
    #cudnn.benchmark = True
    pidcal = PidCal()
    opt = opts.parse()
    warper = Warper()
    slidewindow = SlideWindow()

    print(("device id: {}".format(torch.cuda.current_device())))
    print("torch.version", torch.__version__)
    print("cuda_version", torch.version.cuda)

    models = importlib.import_module('models.init')
    # print(models)
    criterions = importlib.import_module('criterions.init')
    checkpoints = importlib.import_module('checkpoints')
    Trainer = importlib.import_module('models.' + opt.netType + '-train')

    # Data loading
    print('=> Setting up data loader')

    # Load previous checkpoint, if it exists
    print('=> Checking checkpoints')
    checkpoint = checkpoints.load(opt)

    # Create model
    model, optimState = models.setup(opt, checkpoint)
    model.cuda()

    criterion = criterions.setup(opt, checkpoint, model)

    ##################################################################################

    model.eval()

    cap = cv2.VideoCapture("input_video/test.avi")

    if cap.isOpened():
        print("width : {}, height : {}".format(cap.get(3), cap.get(4)))

    video_width = int(cap.get(3))
    video_height = int(cap.get(4))

    fourcc = cv2.VideoWriter_fourcc('M', 'J', 'P', 'G')
    # out = cv2.VideoWriter('output_video/TEST_1.avi', fourcc, 20.0, (1280,480),0)

    prev_time = 0

    fps_list = []

    # fourcc =cv2.VideoWriter_fourcc(*'MJPG')
    out = cv2.VideoWriter('input_video/processed_video.avi', fourcc, 40.0,
                          (480, 320), 0)

    steer_list = list()
    lpf_list = list()

    while True:
        ret, frame = cap.read()

        if ret:
            cur_time = time.time()
            frame_new = cv2.resize(frame, (320, 180))

            input_img = frame_new / 255.
            input_img = preprocess_img(input_img)

            # array to tensor
            input_img = torch.from_numpy(input_img).float()

            with torch.no_grad():
                inputData_var = Variable(input_img).unsqueeze(0).cuda()

                # inference
                output = model.forward(inputData_var)
                output = torch.sigmoid(output)
                #output = F.softmax(output, dim=1)

                # gpu -> cpu,  tensor -> numpy
                output = output.detach().cpu().numpy()

                output = output[0]

                output = postprocess_img(output)
                output = np.clip(output, 0, 1)
                output *= 255
                output = np.uint8(output)

                output = cv2.resize(output, (640, 360))
                output[output > 80] = 255
                output[output <= 80] = 0

                warper_img, point_img = warper.warp(output)
                ret, left_start_x, right_start_x, cf_img = slidewindow.w_slidewindow(
                    warper_img)

                if ret:
                    left_x_current, right_x_current, sliding_img, steer_theta = slidewindow.h_slidewindow(
                        warper_img, left_start_x, right_start_x)
                    cv2.imshow('sliding_img', sliding_img)
                    steer_list.append(steer_theta)
                    lpf_result = lpf(steer_theta, 0.5)
                    lpf_list.append(lpf_result)
                    print("steer theta:", steer_theta)
                    if steer_theta < -28 or steer_theta > 28:
                        continue
                    else:
                        pid = round(pidcal.pid_control(int(50 * steer_theta)),
                                    6)
                        print("pid :", pid)
                        '''
                        auto_drive(pid)
                        '''
                else:
                    pidcal.error_sum = 0

                end_time = time.time()
                sec = end_time - cur_time

                fps = 1 / sec
                fps_list.append(fps)

                print("Estimated fps {0} ".format(fps))

                # out.write(add_img)

                cv2.imshow("frame", frame)
                out.write(warper_img)
                # cv2.imshow("src", warper_img)
                # cv2.imshow("out_img", output)
                cv2.imshow("cf_img", cf_img)

                key = cv2.waitKey(1) & 0xFF
                if key == 27: break
                elif key == ord('p'):
                    cv2.waitKey(-1)
    plt.figure(1)
    plt.plot(steer_list)
    plt.figure(2)
    plt.plot(lpf_list)
    plt.show()
コード例 #4
0
def main():
    os.environ["CUDA_VISIBLE_DEVICES"] = '0'
    #cudnn.benchmark = True
    pidcal = PidCal()
    opt = opts.parse()
    warper = Warper()
    slidewindow = SlideWindow()

    print(("device id: {}".format(torch.cuda.current_device())))
    print("torch.version", torch.__version__)
    print("cuda_version", torch.version.cuda)

    models = importlib.import_module('models.init')
    # print(models)
    criterions = importlib.import_module('criterions.init')
    checkpoints = importlib.import_module('checkpoints')
    Trainer = importlib.import_module('models.' + opt.netType + '-train')

    # Data loading
    print('=> Setting up data loader')

    # Load previous checkpoint, if it exists
    print('=> Checking checkpoints')
    checkpoint = checkpoints.load(opt)

    # Create model
    model, optimState = models.setup(opt, checkpoint)
    model.cuda()

    criterion = criterions.setup(opt, checkpoint, model)

    ##################################################################################

    model.eval()

    cap = None

    if opt.video_idx is 0:
        cap = cv2.VideoCapture("input_video/720p.mp4")
    elif opt.video_idx is 1:
        cap = cv2.VideoCapture("input_video/straight.avi")
    elif opt.video_idx is 2:
        cap = cv2.VideoCapture("input_video/test.avi")
    elif opt.video_idx is 3:
        cap = cv2.VideoCapture("input_video/track.avi")
    elif opt.video_idx is 4:
        cap = cv2.VideoCapture("output_video/field.avi")
    else:
        cap = cv2.VideoCapture(0)
        # video test
        cap.set(3, 1280)
        cap.set(4, 720)

    if cap.isOpened():
        print("width : {}, height : {}".format(cap.get(3), cap.get(4)))

    video_width = int(cap.get(3))
    video_height = int(cap.get(4))

    #fourcc = cv2.VideoWriter_fourcc('M','J','P','G')
    # out = cv2.VideoWriter('output_video/TEST_1.avi', fourcc, 20.0, (1280,480),0)

    prev_time = 0

    fps_list = []

    now = datetime.datetime.now()

    fourcc = None
    out = None

    if opt.video_idx > 2:
        fourcc = cv2.VideoWriter_fourcc(*'MJPG')
        # fourcc =cv2.VideoWriter_fourcc(*'MP4V')
        out = cv2.VideoWriter('output_warper_video/' + str(now) + '.avi',
                              fourcc, 30.0, (480, 320))

    pid_list = list()
    steer_list = list()
    lpf_list = list()

    pid_old = None
    steer_theta = 0
    i = 0
    x_location = 440

    while True:
        ret, frame = cap.read()
        if frame is None:
            break
        frame_height, frame_width, frame_channels = frame.shape

        print("Frame Info : (Height, Width, Channels) : ({}, {}, {})".format(
            frame_height, frame_width, frame_channels))

        # record_frame = cv2.resize(frame, (1280,720))
        # record_frame = cv2.resize(frame, (1280,720))

        if ret:
            cur_time = time.time()
            frame_new = cv2.resize(frame, (320, 180))

            input_img = frame_new / 255.
            input_img = preprocess_img(input_img)

            # array to tensor
            input_img = torch.from_numpy(input_img).float()

            with torch.no_grad():
                inputData_var = Variable(input_img).unsqueeze(0).cuda()

                # inference
                output = model.forward(inputData_var)
                output = torch.sigmoid(output)
                #output = F.softmax(output, dim=1)

                # gpu -> cpu,  tensor -> numpy
                output = output.detach().cpu().numpy()

                output = output[0]

                output = postprocess_img(output)
                output = np.clip(output, 0, 1)
                output *= 255
                output = np.uint8(output)

                output = cv2.resize(output, (640, 360))
                output[output > 80] = 255
                output[output <= 80] = 0
                cv2.circle(output, (output.shape[1] / 2, output.shape[0]), 9,
                           (255, 255, 0), -1)
                cv2.imshow("output_img", output)
                print("shape_info", output.shape)
                # cv2.circle(output, (output.shape[0]/2, output.shape[1]/2), 9, (0,255,0), -1)
                #warper_img = warper.warp(output)
                warper_img = warper.warp_test(output)
                cv2.imshow("warp_img", warper_img)
                if opt.video_idx > 2:
                    print("frame.shape : {}".format(frame.shape))
                    tmp = cv2.cvtColor(warper_img, cv2.COLOR_GRAY2RGB)
                    # print("warper_img.shape : {}".format(warper_img.shape))
                    out.write(tmp)
                # warper_img_test = warper.warp_test(output)
                # cv2.imshow("warp_img_test",warper_img_test)
                ret, left_start_x, right_start_x, cf_img = slidewindow.w_slidewindow(
                    warper_img, 180)

                if ret:
                    i += 1
                    left_x_current, right_x_current, sliding_img, steer_theta = slidewindow.h_slidewindow(
                        warper_img, left_start_x, right_start_x)
                    cv2.imshow('sliding_img', sliding_img)
                    steer_list.append(steer_theta)

                    x_location = (left_x_current + right_x_current) / 2

                    # low pass filter
                    lpf_result = lpf(x_location, 0.3)
                    lpf_list.append(lpf_result)

                    # steer theta : Degree
                    print("steer theta:", steer_theta)

                    if steer_theta < -28.0 or steer_theta > 28.0:
                        # auto_drive(pid_old)
                        auto_drive(steer_theta)

                    else:
                        # degree angle
                        pid = round(pidcal.pid_control(lpf_result), 6)
                        pid_list.append(pid)
                        print("pid :", pid)
                        pid_old = pid
                        auto_drive(steer_theta)

                        # auto_drive(pid)
                else:
                    auto_drive(steer_theta)

                    # auto_drive(pid)
                    pidcal.error_sum = 0
                    pidcal.error_old = 0

                end_time = time.time()
                sec = end_time - cur_time

                fps = 1 / sec
                fps_list.append(fps)

                print("Estimated fps {0} ".format(fps))

                # out.write(add_img)

                cv2.imshow("frame", frame)

                # cv2.imshow("src", warper_img)
                # cv2.imshow("out_img", output)
                cv2.imshow("cf_img", cf_img)

                key = cv2.waitKey(1) & 0xFF
                if key == 27: break
                elif key == ord('p'):
                    cv2.waitKey(-1)

    cap.release()
    cv2.destroyAllWindows()