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教程博客_传送门链接------->单目测距和跟踪
原文链接:https://blog.csdn.net/ALiLiLiYa/article/details/131819630
教程博客_传送门链接------->目标跟踪
!
教程博客_传送门链接------->车道线识别+目标检测
看下本项目的效果:
教程博客_传送门链接------->语义分割
人
。
程博客_传送门链接------->:姿态识别https://blog.csdn.net/ALiLiLiYa/article/details/129482358
1.加载(处理)数据
2.网络搭建
3.损失函数(模型优化)
4 模型训练和保存
**教程博客_传送门链接--------->:图像分类
本
教程博客_传送门链接------->交通标志识别
。
教程博客_传送门链接------->表情识别
教程博客_传送门链接------->疲劳检测
链接:车牌识别
大致的UI界面如下,点击输入图片,右侧即可出现结果!
额外说明:算法代码只有500行,测试中发现,车牌定位算法的参数受图像分辨率、色偏、车距影响。
--->qq 1309399183----------<代码交流
def from_pic(self):
self.thread_run = False
self.pic_path = askopenfilename(title="选择识别图片", filetypes=[("jpg图片", "*.jpg")])
if self.pic_path:
img_bgr = predict.imreadex(self.pic_path)
self.imgtk = self.get_imgtk(img_bgr)
self.image_ctl.configure(image=self.imgtk)
resize_rates = (1, 0.9, 0.8, 0.7, 0.6, 0.5, 0.4)
for resize_rate in resize_rates:
print("resize_rate:", resize_rate)
r, roi, color = self.predictor.predict(img_bgr, resize_rate)
if r:
break
#r, roi, color = self.predictor.predict(img_bgr, 1)
self.show_roi(r, roi, color)
for path, img, im0s, vid_cap in dataset:
img = torch.from_numpy(img).to(device)
img = img.half() if half else img.float() # uint8 to fp16/32
img /= 255.0 # 0 - 255 to 0.0 - 1.0
if img.ndimension() == 3:
img = img.unsqueeze(0)
# Warmup
if device.type != 'cpu' and (old_img_b != img.shape[0] or old_img_h != img.shape[2] or old_img_w != img.shape[3]):
old_img_b = img.shape[0]
old_img_h = img.shape[2]
old_img_w = img.shape[3]
for i in range(3):
model(img, augment=opt.augment)[0]
# Inference
t1 = time_synchronized()
with torch.no_grad(): # Calculating gradients would cause a GPU memory leak
pred = model(img, augment=opt.augment)[0]
t2 = time_synchronized()
distance=object_point_world_position(u, v, h, w, out_mat, in_mat):
本节针对越野场景路径规划问题,采用栅格法建立障碍物、威胁物和越野道路模型,模拟真实的越野环境场景。
引入方向变化惩罚和局部区域复杂度惩罚来优化A算法,使算法规划出的路径更平滑,算法效率更高效。
采用改进 Floyd 算法对路径进行双向平滑,并且进行了防碰撞处理,来确保规划出路径的安全可靠性。
仿真结果表明,所改进的 A算法与传统算法相比较,效率提高了 30%,拐点数减少了4
倍,所提算法能够在越野环境多重因素综合影响以及不同车辆性能和任务的要求下快速的规划出安全的路径。
传送门链接---------------->:A star
###############创建A-Star类############
class AStar:
# 描述AStar算法中的节点数据
class Node:
#初始化
def __init__(self, point, startPoint,endPoint, g=0,w=1,p=1):
self.point = point # 自己的坐标
self.father = None # 父节点
self.g = g # g值,g值在用到的时候会重新算
# 计算h值,采用曼哈顿距离
#self.h = (abs(endPoint.x - point.x) + abs(endPoint.y - point.y)) * 10
#采用欧几里得距离
#self.h = math.pow((math.pow((endPoint.x - point.x),2) + math.pow((endPoint.y - point.y),2)),0.5)*10
#采用对角距离
pp=(1-p)+0.2*math.exp((math.pow((math.pow((endPoint.x - point.x),2) + math.pow((endPoint.y - point.y),2)),0.5))/(math.pow((math.pow((endPoint.x - startPoint.x),2) + math.pow((endPoint.y - startPoint.y),2)),0.5)))
Diagonal_step = min((endPoint.x - point.x),(endPoint.y - point.y))
straight_step = (abs(endPoint.x - point.x) + abs(endPoint.y - point.y)) - 2*Diagonal_step
self.h =(straight_step + math.pow(2,0.5)*Diagonal_step)*10*pp
#print(pp)
#初始化A-start
def __init__(self, map2d, startPoint, endPoint, passTag=1.0):#map2d地图信息,startPoint起点, endPoint终点, passTag=1.0为不可行驶区域
# 开启表
self.openList = []
# 关闭表
self.closeList = []
# 寻路地图
self.map2d = map2d
# 起点终点
if isinstance(startPoint, Point) and isinstance(endPoint, Point):
self.startPoint = startPoint
self.endPoint = endPoint
else:
self.startPoint = Point(*startPoint)
self.endPoint = Point(*endPoint)
# 不可行走标记
self.passTag = passTag
def getMinNode(self):
"""
获得openlist中F值最小的节点
:return: Node
"""
currentNode = self.openList[0]
for node in self.openList:
if node.g + node.h < currentNode.g + currentNode.h:
currentNode = node
return currentNode#返回最小代价的点
链接:停车位检测
#全部代码可加qq1309399183
def train():
#parses command line args
args = parse_args()
#parses args from file
if args.config_file is not None:
cfg_from_file(args.config_file)
if (args.FIX_MODEL_CHECKPOINT):
args.FIX_MODEL_CHECKPOINT = args.FIX_MODEL_CHECKPOINT.replace(" ", "")
args.FIX_MODEL_CHECKPOINT = args.FIX_MODEL_CHECKPOINT.replace("=", "")
cfg.RESUME_CHECKPOINT = args.FIX_MODEL_CHECKPOINT
cfg.CHECK_PREVIOUS = False
if (os.path.exists(cfg.RESUME_CHECKPOINT) == False):
print('Exiting the process as asked model for resuming is not found')
exit()
if (args.RESUME_CHECKPOINT):
cfg.RESUME_CHECKPOINT = args.RESUME_CHECKPOINT
if (args.LOG_DIR):
cfg.EXP_DIR = args.LOG_DIR
cfg.LOG_DIR = cfg.EXP_DIR
if (args.PHASE):
cfg.PHASE = []
cfg.PHASE.append(args.PHASE)
if (args.EVAL_METHOD):
cfg.DATASET.EVAL_METHOD = args.EVAL_METHOD
#for backward compatibility
if cfg.DATASET.DATASET == 'psd':
cfg.DATASET.DATASET = 'tiod'
if cfg.DATASET.BGR_OR_RGB == True:
#cfg.DATASET.PIXEL_MEANS = (123.68, 116.78, 103.94)
#cfg.DATASET.PIXEL_MEANS = (123, 117, 104)
cfg.DATASET.PIXEL_MEANS = (128.0, 128.0, 128.0) # simpler mean subtraction to keep data in int8 after mean subtraction
print("cfg: ", cfg)
for phase in cfg.PHASE:
cfg_dir = cfg.LOG_DIR + '/' + phase + '_cfg/'
os.makedirs(os.path.dirname(cfg_dir), exist_ok=True)
shutil.copy(args.config_file, cfg_dir)
# to making every run consistent # TII
np.random.seed(100)
torch.manual_seed(100)
torch.cuda.manual_seed(100)
random.seed(100)
torch.cuda.manual_seed_all(999)
torch.backends.cudnn.enabled = False
train_model()
if __name__ == '__main__':
train()
下图展现了雾天处理后的结果
图第一列为雾霾图像,第二列为没有加入图像处理的目标检测结果图,第三列为去雾后的目标检测结果图。
。
传送门链接-------------->:无人机检测
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