Using a deep learning-based object detection system
From: Incheon National University [in Korea]
December 12, 2022 -- Self-driving cars need to implement efficient, effective, and accurate detection systems to provide a safe and reliable experience to its users. To this end, an international research team has now developed an end-to-end neural network that, in conjunction with the Internet-of-Things technology, detects object with high accuracy (> 96%) in both 2D and 3D. The new method outperforms the current state-of-the-art methods and the way to new 2D and 3D detection systems for autonomous vehicles.
One of the largest
concerns around the popularization of autonomous vehicles is that of safety and
reliability. In order to ensure a safe driving experience for the user, it is
essential that an autonomous vehicle accurately, effectively, and efficiently
monitors and distinguishes its surroundings as well as potential threats to
passenger safety.
To this end, autonomous
vehicles employ high-tech sensors, such as Light Detection and Ranging (LiDaR),
radar, and RGB cameras that produce large amounts of data as RGB images and 3D
measurement points, known as a "point cloud." The quick and accurate
processing and interpretation of this collected information is critical for the
identification of pedestrians and other vehicles. This can be realized through
the integration of advanced computing methods and Internet-of-Things (IoT) into
these vehicles, which allows for fast, on-site data processing and navigation
of various environments and obstacles more efficiently.
In a recent study
published in the IEEE Transactions of Intelligent Transport Systems journal
on 17 October 2022, a group of international researchers, led by Professor
Gwanggil Jeon from Incheon National University, Korea have now developed a
smart IoT-enabled end-to-end system for 3D object detection in real time based
on deep learning and specialized for autonomous driving situations.
"For autonomous
vehicles, environment perception is critical to answer a core question, 'What
is around me?' It is essential that an autonomous vehicle can effectively and
accurately understand its surrounding conditions and environments in order to
perform a responsive action," explains Prof. Jeon. "We devised a
detection model based onYOLOv3, a well-known identification algorithm. The
model was first used for 2D object detection and then modified for 3D objects,"
he elaborates.
The team fed the
collected RGB images and point cloud data as input to YOLOv3, which, in turn,
output classification labels and bounding boxes with confidence scores. They
then tested its performance with the Lyft dataset. The early results revealed
that YOLOv3 achieved an extremely high accuracy of detection (>96%) for both
2D and 3D objects, outperforming other state-of-the-art detection models.
The method can be
applied to autonomous vehicles, autonomous parking, autonomous delivery, and
future autonomous robots as well as in applications where object and obstacle
detection, tracking, and visual localization is required. "At present,
autonomous driving is being performed through LiDAR-based image processing, but
it is predicted that a general camera will replace the role of LiDAR in the
future. As such, the technology used in autonomous vehicles is changing every
moment, and we are at the forefront," highlights Prof. Jeon. "Based
on the development of element technologies, autonomous vehicles with improved safety should
be available in the next 5-10 years," he concludes optimistically.
https://www.sciencedaily.com/releases/2022/12/221212140800.htm
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