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zed_v11.py
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zed_v11.py
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#!/usr/bin/env python3
#DJ HAKAN KELES STYLE
import os
import sys
import time
import logging
import random
from random import randint
import math
import statistics
import getopt
from ctypes import *
import numpy as np
import cv2
import pyzed.sl as sl
import joblib
import matplotlib.pyplot as plt
from skimage.feature import hog
from PIL import Image as PImage
import rospy
from std_msgs.msg import Float32
from cv_bridge import CvBridge
from sensor_msgs.msg import Image, LaserScan
from geometry_msgs.msg import Point
from nav_msgs.msg import Odometry
from std_msgs.msg import String
from keras.models import load_model
from cv_bridge import CvBridge, CvBridgeError
# Get the top-level logger object
log = logging.getLogger(__name__)
logging.basicConfig(level=logging.INFO)
def adjust_gamma(image, gamma=1.0):
# build a lookup table mapping the pixel values [0, 255] to
# their adjusted gamma values
invGamma = 1.0 / gamma
table = np.array([((i / 255.0) ** invGamma) * 255
for i in np.arange(0, 256)]).astype("uint8")
# apply gamma correction using the lookup table
return cv2.LUT(image, table)
def sample(probs):
s = sum(probs)
probs = [a/s for a in probs]
r = random.uniform(0, 1)
for i in range(len(probs)):
r = r - probs[i]
if r <= 0:
return i
return len(probs)-1
def c_array(ctype, values):
arr = (ctype*len(values))()
arr[:] = values
return arr
class BOX(Structure):
_fields_ = [("x", c_float),
("y", c_float),
("w", c_float),
("h", c_float)]
class DETECTION(Structure):
_fields_ = [("bbox", BOX),
("classes", c_int),
("prob", POINTER(c_float)),
("mask", POINTER(c_float)),
("objectness", c_float),
("sort_class", c_int),
("uc", POINTER(c_float)),
("points", c_int),
("embeddings", POINTER(c_float)),
("embedding_size", c_int),
("sim", c_float),
("track_id", c_int)]
class IMAGE(Structure):
_fields_ = [("w", c_int),
("h", c_int),
("c", c_int),
("data", POINTER(c_float))]
class METADATA(Structure):
_fields_ = [("classes", c_int),
("names", POINTER(c_char_p))]
#lib = CDLL("/home/pjreddie/documents/darknet/libdarknet.so", RTLD_GLOBAL)
#lib = CDLL("darknet.so", RTLD_GLOBAL)
hasGPU = True
if os.name == "nt":
cwd = os.path.dirname(__file__)
os.environ['PATH'] = cwd + ';' + os.environ['PATH']
winGPUdll = os.path.join(cwd, "yolo_cpp_dll.dll")
winNoGPUdll = os.path.join(cwd, "yolo_cpp_dll_nogpu.dll")
envKeys = list()
for k, v in os.environ.items():
envKeys.append(k)
try:
try:
tmp = os.environ["FORCE_CPU"].lower()
if tmp in ["1", "true", "yes", "on"]:
raise ValueError("ForceCPU")
else:
log.info("Flag value '"+tmp+"' not forcing CPU mode")
except KeyError:
# We never set the flag
if 'CUDA_VISIBLE_DEVICES' in envKeys:
if int(os.environ['CUDA_VISIBLE_DEVICES']) < 0:
raise ValueError("ForceCPU")
try:
global DARKNET_FORCE_CPU
if DARKNET_FORCE_CPU:
raise ValueError("ForceCPU")
except NameError:
pass
# log.info(os.environ.keys())
# log.warning("FORCE_CPU flag undefined, proceeding with GPU")
if not os.path.exists(winGPUdll):
raise ValueError("NoDLL")
lib = CDLL(winGPUdll, RTLD_GLOBAL)
except (KeyError, ValueError):
hasGPU = False
if os.path.exists(winNoGPUdll):
lib = CDLL(winNoGPUdll, RTLD_GLOBAL)
log.warning("Notice: CPU-only mode")
else:
# Try the other way, in case no_gpu was
# compile but not renamed
lib = CDLL(winGPUdll, RTLD_GLOBAL)
log.warning("Environment variables indicated a CPU run, but we didn't find `" +
winNoGPUdll+"`. Trying a GPU run anyway.")
else:
lib = CDLL("/home/ismet/otonom_ws/src/zed_package/src/zed-yolo/libdarknet/libdarknet.so", RTLD_GLOBAL)
lib.network_width.argtypes = [c_void_p]
lib.network_width.restype = c_int
lib.network_height.argtypes = [c_void_p]
lib.network_height.restype = c_int
predict = lib.network_predict
predict.argtypes = [c_void_p, POINTER(c_float)]
predict.restype = POINTER(c_float)
if hasGPU:
set_gpu = lib.cuda_set_device
set_gpu.argtypes = [c_int]
make_image = lib.make_image
make_image.argtypes = [c_int, c_int, c_int]
make_image.restype = IMAGE
get_network_boxes = lib.get_network_boxes
get_network_boxes.argtypes = [c_void_p, c_int, c_int, c_float, c_float, POINTER(
c_int), c_int, POINTER(c_int), c_int]
get_network_boxes.restype = POINTER(DETECTION)
make_network_boxes = lib.make_network_boxes
make_network_boxes.argtypes = [c_void_p]
make_network_boxes.restype = POINTER(DETECTION)
free_detections = lib.free_detections
free_detections.argtypes = [POINTER(DETECTION), c_int]
free_ptrs = lib.free_ptrs
free_ptrs.argtypes = [POINTER(c_void_p), c_int]
network_predict = lib.network_predict
network_predict.argtypes = [c_void_p, POINTER(c_float)]
reset_rnn = lib.reset_rnn
reset_rnn.argtypes = [c_void_p]
load_net = lib.load_network
load_net.argtypes = [c_char_p, c_char_p, c_int]
load_net.restype = c_void_p
load_net_custom = lib.load_network_custom
load_net_custom.argtypes = [c_char_p, c_char_p, c_int, c_int]
load_net_custom.restype = c_void_p
do_nms_obj = lib.do_nms_obj
do_nms_obj.argtypes = [POINTER(DETECTION), c_int, c_int, c_float]
do_nms_sort = lib.do_nms_sort
do_nms_sort.argtypes = [POINTER(DETECTION), c_int, c_int, c_float]
free_image = lib.free_image
free_image.argtypes = [IMAGE]
letterbox_image = lib.letterbox_image
letterbox_image.argtypes = [IMAGE, c_int, c_int]
letterbox_image.restype = IMAGE
load_meta = lib.get_metadata
lib.get_metadata.argtypes = [c_char_p]
lib.get_metadata.restype = METADATA
load_image = lib.load_image_color
load_image.argtypes = [c_char_p, c_int, c_int]
load_image.restype = IMAGE
rgbgr_image = lib.rgbgr_image
rgbgr_image.argtypes = [IMAGE]
predict_image = lib.network_predict_image
predict_image.argtypes = [c_void_p, IMAGE]
predict_image.restype = POINTER(c_float)
def array_to_image(arr):
import numpy as np
# need to return old values to avoid python freeing memory
arr = arr.transpose(2, 0, 1)
c = arr.shape[0]
h = arr.shape[1]
w = arr.shape[2]
arr = np.ascontiguousarray(arr.flat, dtype=np.float32) / 255.0
data = arr.ctypes.data_as(POINTER(c_float))
im = IMAGE(w, h, c, data)
return im, arr
def classify(net, meta, im):
out = predict_image(net, im)
res = []
for i in range(meta.classes):
if altNames is None:
name_tag = meta.names[i]
else:
name_tag = altNames[i]
res.append((name_tag, out[i]))
res = sorted(res, key=lambda x: -x[1])
return res
def detect(net, meta, image, thresh=.8, hier_thresh=.8, nms=.45, debug=False):
"""
Performs the detection
"""
custom_image = cv2.cvtColor(image, cv2.COLOR_BGR2RGB)
custom_image = cv2.resize(custom_image, (lib.network_width(
net), lib.network_height(net)), interpolation=cv2.INTER_LINEAR)
im, arr = array_to_image(custom_image)
num = c_int(0)
pnum = pointer(num)
predict_image(net, im)
dets = get_network_boxes(
net, image.shape[1], image.shape[0], thresh, hier_thresh, None, 0, pnum, 0)
num = pnum[0]
if nms:
do_nms_sort(dets, num, meta.classes, nms)
res = []
if debug:
log.debug("about to range")
for j in range(num):
for i in range(meta.classes):
if dets[j].prob[i] > 0:
b = dets[j].bbox
if altNames is None:
name_tag = meta.names[i]
else:
name_tag = altNames[i]
res.append((name_tag, dets[j].prob[i], (b.x, b.y, b.w, b.h), i))
res = sorted(res, key=lambda x: -x[1])
free_detections(dets, num)
return res
netMain = None
metaMain = None
altNames = None
def get_object_depth(depth, bounds, label):
'''
Calculates the median x, y, z position of top slice(area_div) of point cloud
in camera frame.
Arguments:
depth: Point cloud data of whole frame.
bounds: Bounding box for object in pixels.
bounds[0]: x-center
bounds[1]: y-center
bounds[2]: width of bounding box.
bounds[3]: height of bounding box.
Return:
x, y, z: Location of object in meters.
'''
if(label == "Park Yeri"):
area_div = 2
x_vect = []
y_vect = []
z_vect = []
for j in range(int(bounds[0] - area_div), int(bounds[0] + area_div)):
for i in range(int(bounds[1] - area_div), int(bounds[1] + area_div)):
z = depth[i, j, 2]
if not np.isnan(z) and not np.isinf(z):
x_vect.append(depth[i, j, 0])
y_vect.append(depth[i, j, 1])
z_vect.append(z)
try:
x_median = statistics.median(x_vect)
y_median = statistics.median(y_vect)
z_median = statistics.median(z_vect)
except Exception:
x_median = -1
y_median = -1
z_median = -1
pass
else:
area_div = 10
x_vect = []
y_vect = []
z_vect = []
if(int(bounds[0]) > 1700 or int(bounds[0]) < 220 or int(bounds[1]) > 960 or int(bounds[1]) < 121):
x_median = -1
y_median = -1
z_median = -1
else:
for j in range(int(bounds[0] - area_div), int(bounds[0] + area_div)):
for i in range(int(bounds[1] - area_div), int(bounds[1] + area_div)):
z = depth[i, j, 2]
if not np.isnan(z) and not np.isinf(z):
x_vect.append(depth[i, j, 0])
y_vect.append(depth[i, j, 1])
z_vect.append(z)
try:
x_median = statistics.median(x_vect)
y_median = statistics.median(y_vect)
z_median = statistics.median(z_vect)
except Exception:
x_median = -1
y_median = -1
z_median = -1
pass
return x_median, y_median, z_median
cam = sl.Camera()
runtime = sl.RuntimeParameters()
mat = sl.Mat()
point_cloud_mat = sl.Mat()
thresh = 0.6
color_array = 0
left_right_model = joblib.load('/home/ismet/otonom_ws/src/zed_package/src/zed-yolo/zed_python_sample/yolo_data/hattori.npy')
park_durak_model = joblib.load('/home/ismet/otonom_ws/src/zed_package/src/zed-yolo/zed_python_sample/yolo_data/durak_park.npy')
traffic_light_model = load_model('/home/ismet/otonom_ws/src/zed_package/src/zed-yolo/zed_python_sample/yolo_data/traffic_light_model.h5')
must_lr_model = joblib.load('/home/ismet/otonom_ws/src/zed_package/src/zed-yolo/zed_python_sample/yolo_data/must_r_l.npy')
orientations = 9
pixels_per_cell = (8, 8)
cells_per_block = (2, 2)
threshold = .6
runtime = 0
zed_pose = 0
zed_sensors = 0
def left_right_judgement(img,x_min,x_max,y_min,y_max):
#tespit edilen levhayi ikiye bolduk ama ise yaramadi
#cropped_img_left = img[y_min:y_max, x_min:int(x_min+(box_width)/2)]
#cropped_img_right = img[y_min:y_max, x_min+int(box_width/2):x_max]
cropped_img = img[y_min:y_max, x_min:x_max]
#cropped_img = img
if not all(cropped_img.shape):
return 0
img = PImage.fromarray(cropped_img)
img = img.resize((128,128))
gray= img.convert('L')
# Now we calculate the HOG for negative features
fd = hog(gray, orientations, pixels_per_cell, cells_per_block, block_norm='L2', feature_vector=True)
fd = fd.reshape(1,8100)
sonuc = left_right_model.predict(fd)
return sonuc
def park_durak_judgement(img,x_min,x_max,y_min,y_max):
cropped_img = img[y_min:y_max, x_min:x_max]
#cropped_img = img
if not all(cropped_img.shape):
return 0
img = PImage.fromarray(cropped_img)
img = img.resize((128,128))
gray= img.convert('L')
# Now we calculate the HOG for negative features
fd = hog(gray, orientations, pixels_per_cell, cells_per_block, block_norm='L2', feature_vector=True)
fd = fd.reshape(1,8100)
sonuc = park_durak_model.predict(fd)
return sonuc
def traffic_light_judgement(img, x_min,x_max,y_min,y_max):
if not all(img.shape):
return 0
img = img[y_min:y_max, x_min:x_max]
desired_dim=(32,32)
try:
img_resized = cv2.resize(img, desired_dim, interpolation=cv2.INTER_LINEAR)
except:
file.write(str(np.array(img).shape) + "\n")
img_ = np.expand_dims(np.array(img_resized), axis=0)
predicted_state =np.argmax(traffic_light_model.predict(img_), axis=-1)
return predicted_state
def must_left_right_judgement(img, x_min,x_max,y_min,y_max):
cropped_img = img[y_min:y_max, x_min:x_max]
#cropped_img = img
if not all(cropped_img.shape):
return 0
img = PImage.fromarray(cropped_img)
img = img.resize((128,128))
gray= img.convert('L')
# Now we calculate the HOG for negative features
fd = hog(gray, orientations, pixels_per_cell, cells_per_block, block_norm='L2', feature_vector=True)
fd = fd.reshape(1,8100)
sonuc = must_lr_model.predict(fd)
return sonuc
def main():
global color_array
global cam
global runtime
global mat
global point_cloud_mat
global thresh
global runtime
global zed_pose
global zed_sensors
darknet_path="/home/ismet/otonom_ws/src/zed_package/src/zed-yolo/libdarknet/"
config_path = "/home/ismet/otonom_ws/src/zed_package/src/zed-yolo/zed_python_sample/yolo_data/ismet_yolov3_v2.cfg"
weight_path = "/home/ismet/otonom_ws/src/zed_package/src/zed-yolo/zed_python_sample/yolo_data/ismet_yolov3_v2_10000.weights"
meta_path = "/home/ismet/otonom_ws/src/zed_package/src/zed-yolo/zed_python_sample/yolo_data/coco.data"
svo_path = None
zed_id = 0
help_str = 'darknet_zed.py -c <config> -w <weight> -m <meta> -t <threshold> -s <svo_file> -z <zed_id>'
try:
opts, args = getopt.getopt(
[], "hc:w:m:t:s:z:", ["config=", "weight=", "meta=", "threshold=", "svo_file=", "zed_id="])
except getopt.GetoptError:
log.exception(help_str)
sys.exit(2)
for opt, arg in opts:
if opt == '-h':
log.info(help_str)
sys.exit()
elif opt in ("-c", "--config"):
config_path = arg
elif opt in ("-w", "--weight"):
weight_path = arg
elif opt in ("-m", "--meta"):
meta_path = arg
elif opt in ("-t", "--threshold"):
thresh = float(arg)
elif opt in ("-s", "--svo_file"):
svo_path = arg
elif opt in ("-z", "--zed_id"):
zed_id = int(arg)
input_type = sl.InputType()
if svo_path is not None:
log.info("SVO file : " + svo_path)
input_type.set_from_svo_file(svo_path)
else:
# Launch camera by id
input_type.set_from_camera_id(zed_id)
init = sl.InitParameters()
init.camera_resolution = sl.RESOLUTION.HD1080
init.camera_fps = 15 # Use HD720 video mode (default fps: 60)
init.coordinate_system = sl.COORDINATE_SYSTEM.RIGHT_HANDED_Y_UP
init.coordinate_units = sl.UNIT.METER # Set units in meters
init.depth_mode = sl.DEPTH_MODE.ULTRA
#cam.enable_streaming()
if not cam.is_opened():
log.info("Opening ZED Camera...")
status = cam.open(init)
if status != sl.ERROR_CODE.SUCCESS:
log.error(repr(status))
exit()
py_transform = sl.Transform() # First create a Transform object for TrackingParameters object
tracking_parameters = sl.PositionalTrackingParameters(_init_pos=py_transform)
err = cam.enable_positional_tracking(tracking_parameters)
if err != sl.ERROR_CODE.SUCCESS:
exit(1)
# Track the camera position during 1000 frames
zed_pose = sl.Pose()
zed_sensors = sl.SensorsData()
runtime = sl.RuntimeParameters()
# Use STANDARD sensing mode
runtime.sensing_mode = sl.SENSING_MODE.STANDARD
mat = sl.Mat()
point_cloud_mat = sl.Mat()
# Import the global variables. This lets us instance Darknet once,
# then just call performDetect() again without instancing again
global metaMain, netMain, altNames # pylint: disable=W0603
assert 0 < thresh < 1, "Threshold should be a float between zero and one (non-inclusive)"
if not os.path.exists(config_path):
raise ValueError("Invalid config path `" +
os.path.abspath(config_path)+"`")
if not os.path.exists(weight_path):
raise ValueError("Invalid weight path `" +
os.path.abspath(weight_path)+"`")
if not os.path.exists(meta_path):
raise ValueError("Invalid data file path `" +
os.path.abspath(meta_path)+"`")
if netMain is None:
netMain = load_net_custom(config_path.encode(
"ascii"), weight_path.encode("ascii"), 0, 1) # batch size = 1
if metaMain is None:
metaMain = load_meta(meta_path.encode("ascii"))
if altNames is None:
# In thon 3, the metafile default access craps out on Windows (but not Linux)
# Read the names file and create a list to feed to detect
try:
with open(meta_path) as meta_fh:
meta_contents = meta_fh.read()
import re
match = re.search("names *= *(.*)$", meta_contents,
re.IGNORECASE | re.MULTILINE)
if match:
result = match.group(1)
else:
result = None
try:
if os.path.exists(result):
with open(result) as names_fh:
names_list = names_fh.read().strip().split("\n")
altNames = [x.strip() for x in names_list]
except TypeError:
pass
except Exception:
pass
log.info("Running...")
key = ''
x_orta = 0
y_orta = 0
SOLA_DONULMEZ = "sola donulmez"
SOLA_DONULMEZ_CTR = 0
SAGA_DONULMEZ = "saga donulmez"
SAGA_DONULMEZ_CTR = 0
GIRILMEZ = "girilmez"
GIRILMEZ_CTR = 0
ILERIDEN_SAGA_MECBURI_YON = "ileriden sola mecburi yon"
ILERIDEN_SAGA_MECBURI_YON_CTR = 0
ILERIDEN_SOLA_MECBURI_YON = "ileriden saga mecburi yon"
ILERIDEN_SOLA_MECBURI_YON_CTR = 0
ILERI_VE_SAGA_MECBURI_YON = "ileri Ve saga mecburi yon"
ILERI_VE_SAGA_MECBURI_YON_CTR = 0
ILERI_VE_SOLA_MECBURI_YON = "ileri Ve sola mecburi yon"
ILERI_VE_SOLA_MECBURI_YON_CTR = 0
DURAK = "Durak"
DURAK_CTR = 0
PARK_YERI = "Park Yeri"
PARK_YERI_CTR = 0
PARK_YASAK = "Park Yasak"
PARK_YASAK_CTR = 0
KIRMIZI_ISIK = "kirmizi isik"
KIRMIZI_ISIK_CTR = 0
YESIL_ISIK = "yesil isik"
YESIL_ISIK_CTR = 0
def SEBASTIAN_VETTEL():
global x_orta
global y_orta
global SOLA_DONULMEZ
global SOLA_DONULMEZ_CTR
global SAGA_DONULMEZ
global SAGA_DONULMEZ_CTR
global GIRILMEZ
global GIRILMEZ_CTR
global ILERIDEN_SAGA_MECBURI_YON
global ILERIDEN_SAGA_MECBURI_YON_CTR
global ILERIDEN_SOLA_MECBURI_YON
global ILERIDEN_SOLA_MECBURI_YON_CTR
global ILERI_VE_SAGA_MECBURI_YON
global ILERI_VE_SAGA_MECBURI_YON_CTR
global ILERI_VE_SOLA_MECBURI_YON
global ILERI_VE_SOLA_MECBURI_YON_CTR
global DURAK
global DURAK_CTR
global PARK_YERI
global PARK_YERI_CTR
global PARK_YASAK
global PARK_YASAK_CTR
global KIRMIZI_ISIK
global KIRMIZI_ISIK_CTR
global YESIL_ISIK
global YESIL_ISIK_CTR
LIMIT = 3
SANIYE = 7
states = ['red', 'yellow', 'green', 'off']
label = ''
start_time = time.time() # start time of the loop
err = cam.grab(runtime)
distance = 0
if err == sl.ERROR_CODE.SUCCESS:
cam.retrieve_image(mat, sl.VIEW.LEFT)
image = mat.get_data()
raw_image = image.copy()
image = adjust_gamma(image, 2)
cam.retrieve_measure(
point_cloud_mat, sl.MEASURE.XYZRGBA)
depth = point_cloud_mat.get_data()
park_yeri = []
park_yeri_distance = []
# Do the detection
detections = detect(netMain, metaMain, image, thresh)
log.info(chr(27) + "[2J"+"**** " + str(len(detections)) + " Results ****")
detected_objects = ""
for detection in detections:
label = detection[0]
label = str(label)
confidence = detection[1]
bounds = detection[2]
y_extent = int(bounds[3])
x_extent = int(bounds[2])
# Coordinates are around the center
x_coord = int(bounds[0] - bounds[2]/2)
y_coord = int(bounds[1] - bounds[3]/2)
#boundingBox = [[x_coord, y_coord], [x_coord, y_coord + y_extent], [x_coord + x_extent, y_coord + y_extent], [x_coord + x_extent, y_coord]]
thickness = 1
x, y, z = get_object_depth(depth, bounds, label)
if((label=='sola donulmez') or (label=='saga donulmez')):
#cv2.imshow("result",image)
result = left_right_judgement(image,x_coord ,x_coord + x_extent,y_coord,y_coord + y_extent)
if(result):
label = "sola donulmez"
else:
label = "saga donulmez"
if((label == 'Durak') or (label == "Park Yeri")):
result = park_durak_judgement(image,x_coord ,x_coord + x_extent,y_coord,y_coord + y_extent)
if(result):
label = "Park Yeri"
else:
label = "Durak"
if((label == 'ileriden sola mecburi yon') or (label == "ileriden saga mecburi yon") or (label == "Sola Mecburi Yon") or (label == "Saga Mecburi Yon")):
result = must_left_right_judgement(image,x_coord ,x_coord + x_extent,y_coord,y_coord + y_extent)
if(result):
label = "ileriden sola mecburi yon"
else:
label = "ileriden saga mecburi yon"
"""if((label == 'yesil isik') or (label == "kirmizi isik") or (label == "sari isik") or (label == "Trafik Lambasi")):
image = cv2.cvtColor(image, cv2.COLOR_RGBA2RGB)
result = traffic_light_judgement(image,x_coord ,x_coord + x_extent,y_coord,y_coord + y_extent)
for idx in result:
result = (states[idx])
if(result == "green"):
label = "yesil isik"
elif(result == "red"):
label == "kirmizi isik"""
pstring = label+": "+ str(np.rint(100 * confidence))+"%"
log.info(pstring)
distance = math.sqrt(x * x + y * y + z * z)
if(label == "Park Yeri"):
x_orta = x_coord + x_extent / 2
y_orta = y_coord + y_extent / 2
park_yeri.append(int(x_orta))
park_yeri_distance.append(distance)
sign_coord.x = x
sign_coord.y = y
sign_coord.z = z
distance = "{:.2f}".format(distance)
cv2.rectangle(image, (x_coord - thickness, y_coord - thickness),
(x_coord + x_extent + thickness, y_coord + (18 + thickness*4)),
(37,66,0), -1)
cv2.putText(image, label + " " + (str(distance) + " m"),
(x_coord + (thickness * 4), y_coord + (10 + thickness * 4)),
cv2.FONT_HERSHEY_SIMPLEX, 0.5, (255, 255, 255), 2)
cv2.rectangle(image, (x_coord - thickness, y_coord - thickness),
(x_coord + x_extent + thickness, y_coord + y_extent + thickness),
(37,66,0), int(thickness*2))
if(label == SOLA_DONULMEZ):
SOLA_DONULMEZ_CTR += 1
if(SOLA_DONULMEZ_CTR >= LIMIT):
if(x == -1 and y == -1 and z == -1):
pass
elif (distance == '1.73'):
pass
else:
detected_objects += label + "," + str(x)[0:4]+ ","+ str(y)[0:4] + "," + str(z)[0:4] + ","+ str(distance) + ";"
SOLA_DONULMEZ_CTR = 0
elif(label == SAGA_DONULMEZ):
SAGA_DONULMEZ_CTR += 1
if(SAGA_DONULMEZ_CTR >= LIMIT):
if(x == -1 and y == -1 and z == -1):
pass
elif (distance == '1.73'):
pass
else:
detected_objects += label + "," + str(x)[0:4]+ ","+ str(y)[0:4] + "," + str(z)[0:4] + ","+ str(distance) + ";"
SAGA_DONULMEZ_CTR = 0
elif(label == ILERIDEN_SAGA_MECBURI_YON):
ILERIDEN_SAGA_MECBURI_YON_CTR += 1
if(ILERIDEN_SAGA_MECBURI_YON_CTR >= LIMIT):
if(x == -1 and y == -1 and z == -1):
pass
elif (distance == '1.73'):
pass
else:
detected_objects += label + "," + str(x)[0:4]+ ","+ str(y)[0:4] + "," + str(z)[0:4] + ","+ str(distance) + ";"
ILERIDEN_SAGA_MECBURI_YON_CTR = 0
elif(label == ILERIDEN_SOLA_MECBURI_YON):
ILERIDEN_SOLA_MECBURI_YON_CTR += 1
if(ILERIDEN_SOLA_MECBURI_YON_CTR >= LIMIT):
if(x == -1 and y == -1 and z == -1):
pass
elif (distance == '1.73'):
pass
else:
detected_objects += label + "," + str(x)[0:4]+ ","+ str(y)[0:4] + "," + str(z)[0:4] + ","+ str(distance) + ";"
ILERIDEN_SOLA_MECBURI_YON_CTR = 0
elif(label == GIRILMEZ):
GIRILMEZ_CTR += 1
if(GIRILMEZ_CTR >= LIMIT):
if(x == -1 and y == -1 and z == -1):
pass
elif (distance == '1.73'):
pass
else:
detected_objects += label + "," + str(x)[0:4]+ ","+ str(y)[0:4] + "," + str(z)[0:4] + ","+ str(distance) + ";"
GIRILMEZ_CTR = 0
elif(label == DURAK):
DURAK_CTR += 1
if(DURAK_CTR >= LIMIT):
if(x == -1 and y == -1 and z == -1):
pass
elif (distance == '1.73'):
pass
else:
detected_objects += label + "," + str(x)[0:4]+ ","+ str(y)[0:4] + "," + str(z)[0:4] + ","+ str(distance) + ";"
#DURAK_CTR = 0
elif(label == PARK_YASAK):
PARK_YASAK_CTR += 1
if(PARK_YASAK_CTR >= LIMIT):
if(x == -1 and y == -1 and z == -1):
pass
elif (distance == '1.73'):
pass
else:
detected_objects += label + "," + str(x)[0:4]+ ","+ str(y)[0:4] + "," + str(z)[0:4] + ","+ str(distance) + ";"
#PARK_YASAK_CTR = 0
elif(label == PARK_YERI):
PARK_YERI_CTR += 1
if(PARK_YERI_CTR >= LIMIT):
if(x == -1 and y == -1 and z == -1):
pass
elif (distance == '1.73'):
pass
else:
detected_objects += label + "," + str(x)[0:4]+ ","+ str(y)[0:4] + "," + str(z)[0:4] + ","+ str(distance) + ";"
#PARK_YASAK_CTR = 0
elif(label == ILERI_VE_SAGA_MECBURI_YON):
ILERI_VE_SAGA_MECBURI_YON_CTR += 1
if(ILERI_VE_SAGA_MECBURI_YON_CTR >= LIMIT):
if(x == -1 and y == -1 and z == -1):
pass
elif (distance == '1.73'):
pass
else:
detected_objects += label + "," + str(x)[0:4]+ ","+ str(y)[0:4] + "," + str(z)[0:4] + ","+ str(distance) + ";"
ILERI_VE_SAGA_MECBURI_YON_CTR = 0
elif(label == ILERI_VE_SOLA_MECBURI_YON):
ILERI_VE_SOLA_MECBURI_YON_CTR += 1
if(ILERI_VE_SOLA_MECBURI_YON_CTR >= LIMIT):
if(x == -1 and y == -1 and z == -1):
pass
elif (distance == '1.73'):
pass
else:
detected_objects += label + "," + str(x)[0:4]+ ","+ str(y)[0:4] + "," + str(z)[0:4] + ","+ str(distance) + ";"
ILERI_VE_SOLA_MECBURI_YON_CTR = 0
elif(label == KIRMIZI_ISIK):
KIRMIZI_ISIK_CTR += 1
if(KIRMIZI_ISIK_CTR >= 0):
if(x == -1 and y == -1 and z == -1):
pass
elif (distance == '1.73'):
pass
else:
detected_objects += label + "," + str(x)[0:4]+ ","+ str(y)[0:4] + "," + str(z)[0:4] + ","+ str(distance) + ";"
#KIRMIZI_ISIK_CTR = 0
elif(label == YESIL_ISIK):
YESIL_ISIK_CTR += 1
if(YESIL_ISIK_CTR >= LIMIT):
if(x == -1 and y == -1 and z == -1):
pass
elif (distance == '1.73'):
pass
else:
detected_objects += label + "," + str(x)[0:4]+ ","+ str(y)[0:4] + "," + str(z)[0:4] + ","+ str(distance) + ";"
#YESIL_ISIK_CTR = 0
if(x == -1 and y == -1 and z == -1):
pass
elif (distance == '1.73'):
pass
elif len(detected_objects) < 3:
pass
else:
detected_objects += label + "," + str(x)[0:4]+ ","+ str(y)[0:4] + "," + str(z)[0:4] + ","+ str(distance) + ";"
cv2.imshow("ZED", image)
key = cv2.waitKey(5)
log.info("FPS: {}".format(1.0 / (time.time() - start_time)))
else:
key = cv2.waitKey(5)
if len(park_yeri) > 0:
park_yeri_pixel = max(park_yeri)
else:
park_yeri_pixel = 0
if len(park_yeri_distance) > 0:
park_yeri_uzaklik= min(park_yeri_distance)
else:
park_yeri_uzaklik = 0
label_and_distance = label + ' ' +str(distance)
return raw_image, label_and_distance, sign_coord, detected_objects, park_yeri_pixel, park_yeri_uzaklik
s_time = time.time()
zed_odom_speed = None
previous_pos = np.array([0, 0, 0], dtype=np.float32)
def SAINZ():
global s_time
global zed_odom_speed
global previous_pos
global runtime
global zed_pose
global cam
global zed_sensors
if cam.grab(runtime) == sl.ERROR_CODE.SUCCESS:
# Get the pose of the left eye of the camera with reference to the world frame
cam.get_position(zed_pose, sl.REFERENCE_FRAME.WORLD)
cam.get_sensors_data(zed_sensors, sl.TIME_REFERENCE.IMAGE)
zed_imu = zed_sensors.get_imu_data()
# Display the translation and timestamp
py_translation = sl.Translation()
tx = round(zed_pose.get_translation(py_translation).get()[0], 3)
ty = round(zed_pose.get_translation(py_translation).get()[1], 3)
tz = round(zed_pose.get_translation(py_translation).get()[2], 3)
#print("Translation: Tx: {0}, Ty: {1}, Tz {2}, Timestamp: {3}\n".format(tx, ty, tz, zed_pose.timestamp.get_milliseconds()))
pose_msg.x = odometry_msg.pose.pose.position.x = tx
pose_msg.y = odometry_msg.pose.pose.position.y = ty
pose_msg.z = odometry_msg.pose.pose.position.z = tz
initial_time = time.time()
diff = s_time - initial_time
odometry_msg.twist.twist.linear.z = round((previous_pos[0]-pose_msg.z) / diff, 3)
odometry_msg.twist.twist.linear.x = round((previous_pos[1]-pose_msg.x) / diff, 3)
odometry_msg.twist.twist.linear.y = round((previous_pos[2]-pose_msg.y) / diff, 3)
previous_pos[0] = pose_msg.z
previous_pos[1] = pose_msg.x
previous_pos[2] = pose_msg.y
""" zed_odom_speed = math.sqrt(pow(previous_pos[0]-pose_msg.x , 2)+
pow(previous_pos[1]-pose_msg.y , 2))
zed_odom_speed /= diff
previous_pos[0] = momentary_x
previous_pos[1] = momentary_y """
s_time = initial_time
# Display the orientation quaternion
py_orientation = sl.Orientation()
odometry_msg.pose.pose.orientation.x = ox = round(zed_pose.get_orientation(py_orientation).get()[0], 3)
odometry_msg.pose.pose.orientation.y = oy = round(zed_pose.get_orientation(py_orientation).get()[1], 3)
odometry_msg.pose.pose.orientation.z = oz = round(zed_pose.get_orientation(py_orientation).get()[2], 3)
odometry_msg.pose.pose.orientation.w = ow = round(zed_pose.get_orientation(py_orientation).get()[3], 3)
#print("Orientation: Ox: {0}, Oy: {1}, Oz {2}, Ow: {3}\n".format(ox, oy, oz, ow))
#Display the IMU acceleratoin
acceleration = [0,0,0]
zed_imu.get_linear_acceleration(acceleration)
ax = round(acceleration[0], 3)
ay = round(acceleration[1], 3)
az = round(acceleration[2], 3)
#print("IMU Acceleration: Ax: {0}, Ay: {1}, Az {2}\n".format(ax, ay, az))
#Display the IMU angular velocity
a_velocity = [0,0,0]
zed_imu.get_angular_velocity(a_velocity)
odometry_msg.twist.twist.angular.x = vx = round(a_velocity[0], 3)
odometry_msg.twist.twist.angular.y = vy = round(a_velocity[1], 3)
odometry_msg.twist.twist.angular.z = vz = round(a_velocity[2], 3)
#print("IMU Angular Velocity: Vx: {0}, Vy: {1}, Vz {2}\n".format(vx, vy, vz))
# Display the IMU orientation quaternion
zed_imu_pose = sl.Transform()
ox = round(zed_imu.get_pose(zed_imu_pose).get_orientation().get()[0], 3)
oy = round(zed_imu.get_pose(zed_imu_pose).get_orientation().get()[1], 3)
oz = round(zed_imu.get_pose(zed_imu_pose).get_orientation().get()[2], 3)
ow = round(zed_imu.get_pose(zed_imu_pose).get_orientation().get()[3], 3)
#print("IMU Orientation: Ox: {0}, Oy: {1}, Oz {2}, Ow: {3}\n".format(ox, oy, oz, ow))
return pose_msg, odometry_msg