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comments | description | keywords |
---|---|---|
true | Speed Estimation Using Ultralytics YOLOv8 | Ultralytics, YOLOv8, Object Detection, Speed Estimation, Object Tracking, Notebook, IPython Kernel, CLI, Python SDK |
Speed Estimation using Ultralytics YOLOv8 🚀
What is Speed Estimation?
Speed estimation is the process of calculating the rate of movement of an object within a given context, often employed in computer vision applications. Using Ultralytics YOLOv8 you can now calculate the speed of object using object tracking alongside distance and time data, crucial for tasks like traffic and surveillance. The accuracy of speed estimation directly influences the efficiency and reliability of various applications, making it a key component in the advancement of intelligent systems and real-time decision-making processes.
Advantages of Speed Estimation?
- Efficient Traffic Control: Accurate speed estimation aids in managing traffic flow, enhancing safety, and reducing congestion on roadways.
- Precise Autonomous Navigation: In autonomous systems like self-driving cars, reliable speed estimation ensures safe and accurate vehicle navigation.
- Enhanced Surveillance Security: Speed estimation in surveillance analytics helps identify unusual behaviors or potential threats, improving the effectiveness of security measures.
Real World Applications
Transportation | Transportation |
---|---|
Speed Estimation on Road using Ultralytics YOLOv8 | Speed Estimation on Bridge using Ultralytics YOLOv8 |
!!! Example "Speed Estimation using YOLOv8 Example"
=== "Speed Estimation"
```python
from ultralytics import YOLO
from ultralytics.solutions import speed_estimation
import cv2
model = YOLO("yolov8n.pt")
names = model.model.names
cap = cv2.VideoCapture("path/to/video/file.mp4")
assert cap.isOpened(), "Error reading video file"
w, h, fps = (int(cap.get(x)) for x in (cv2.CAP_PROP_FRAME_WIDTH, cv2.CAP_PROP_FRAME_HEIGHT, cv2.CAP_PROP_FPS))
# Video writer
video_writer = cv2.VideoWriter("speed_estimation.avi",
cv2.VideoWriter_fourcc(*'mp4v'),
fps,
(w, h))
line_pts = [(0, 360), (1280, 360)]
# Init speed-estimation obj
speed_obj = speed_estimation.SpeedEstimator()
speed_obj.set_args(reg_pts=line_pts,
names=names,
view_img=True)
while cap.isOpened():
success, im0 = cap.read()
if not success:
print("Video frame is empty or video processing has been successfully completed.")
break
tracks = model.track(im0, persist=True, show=False)
im0 = speed_obj.estimate_speed(im0, tracks)
video_writer.write(im0)
cap.release()
video_writer.release()
cv2.destroyAllWindows()
```
???+ warning "Speed is Estimate"
Speed will be an estimate and may not be completely accurate. Additionally, the estimation can vary depending on GPU speed.
Optional Arguments set_args
Name | Type | Default | Description |
---|---|---|---|
reg_pts |
list |
[(20, 400), (1260, 400)] |
Points defining the Region Area |
names |
dict |
None |
Classes names |
view_img |
bool |
False |
Display frames with counts |
line_thickness |
int |
2 |
Increase bounding boxes thickness |
region_thickness |
int |
5 |
Thickness for object counter region or line |
spdl_dist_thresh |
int |
10 |
Euclidean Distance threshold for speed check line |
Arguments model.track
Name | Type | Default | Description |
---|---|---|---|
source |
im0 |
None |
source directory for images or videos |
persist |
bool |
False |
persisting tracks between frames |
tracker |
str |
botsort.yaml |
Tracking method 'bytetrack' or 'botsort' |
conf |
float |
0.3 |
Confidence Threshold |
iou |
float |
0.5 |
IOU Threshold |
classes |
list |
None |
filter results by class, i.e. classes=0, or classes=[0,2,3] |
verbose |
bool |
True |
Display the object tracking results |