IMPLEMENTATION OF YOLOV8-BASED OBJECT DETECTION ALGORITHM IN MINING AREA
The field of occupational safety and health (OSH) plays a pivotal role in the context of industrial operations, particularly within the mining sector, which is characterised by a heightened risk of occupational accidents and health hazards. The objective of OHS supervision is to prevent workplace...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/85229 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The field of occupational safety and health (OSH) plays a pivotal role in the context
of industrial operations, particularly within the mining sector, which is
characterised by a heightened risk of occupational accidents and health hazards.
The objective of OHS supervision is to prevent workplace accidents and to
safeguard the health of workers, who are a vital resource for the continued
operation of the company. In mining areas, the necessity for close and continuous
supervision is paramount in order to guarantee that all activities are conducted in
accordance with established safety standards, given the inherently complex and
high-risk nature of the work environment. PT X, a mining company in Indonesia,
employs the use of the Mining Eyes Analytics system, which is based on the use of
CCTV cameras and the YOLOv4 algorithm, for the purpose of detecting any
deviations or unsafe conditions that may arise within the mining area. The system
is designed to detect the presence of individuals, heavy-duty trucks (HD), and light
vehicles (LV). However, this surveillance system still exhibits limitations in terms
of detecting small objects, objects in poor lighting conditions, and the occurrence
of detection errors. This research employs YOLOv8-based object detection to
address these shortcomings. The YOLO models utilised are YOLOv8, a modified
version of YOLOv8 at the head to enhance multi-scale detection capability, and
BGF-YOLO, which incorporates multi-scale detection optimisation and the
application of an attention mechanism in the feature fusion process to improve
model focus. The data employed in this study comprises daytime mine area data
encompassing a range of mine environmental conditions, including poor lighting
and the presence of overlapping objects. The total number of data points utilized is
11,000.
The results of the evaluation demonstrate that the BGF-YOLO model exhibits
superior performance compared to other models. The BGF-YOLO model
demonstrated a precision of 94.9%, a recall of 91.1%, and a mean average
precision (mAP@50) of 86.5%. Although the optimised YOLOv8 model exhibits the
highest precision at 96.7%, its overall performance remains inferior to that of BGF-
YOLO and YOLOv8. This discrepancy can be attributed to the fact that the
introduction of the object head enables precise detection but simultaneously
diminishes the model's responsiveness to novel data. |
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