TY - JOUR
T1 - Multiagent Sensor Integration and Knowledge Distillation System for Real-Time Autonomous Vehicle Navigation
AU - Hijji, Mohammad
AU - Ullah, Kaleem
AU - Alwakeel, Mohammed
AU - Alwakeel, Ahmed
AU - Aradah, Fahad
AU - Cheikh, Faouzi Alaya
AU - Sajjad, Muhammad
AU - Muhammad, Khan
N1 - Publisher Copyright:
© 2007-2012 IEEE.
PY - 2025
Y1 - 2025
N2 - This article introduces a comprehensive multiagent prototype system designed to enhance the autonomous navigation capabilities of vehicles by incorporating numerous sensors and components. The system includes features such as an ultrasonic sensor for precise distance measurement, a specially crafted “SonarSpinner” with a wide 160° field of view, a vision sensor for road sign detection and steering angle estimation, and an infrared obstacle avoidance sensor, operating with a predefined obstacle-halting threshold of 150 cm. Data collection for model training and evaluation is accomplished using a virtual reality-based self-driving car simulator, resulting in a diverse dataset. The proposed system harnesses knowledge distillation from teacher models, such as the Nvidia model, to create a lightweight student model optimized for real-time inference while retaining competitive accuracy. Additionally, a custom Haar cascade classifier enhances traffic sign detection capabilities. The distilled model is then converted to TensorFlow Lite for efficient deployment on edge devices within autonomous vehicles, ensuring a secure and efficient navigation system. This innovative approach combines optimized distillation methods with specialized classifiers to facilitate the development of robust and real-time self-driving car systems.
AB - This article introduces a comprehensive multiagent prototype system designed to enhance the autonomous navigation capabilities of vehicles by incorporating numerous sensors and components. The system includes features such as an ultrasonic sensor for precise distance measurement, a specially crafted “SonarSpinner” with a wide 160° field of view, a vision sensor for road sign detection and steering angle estimation, and an infrared obstacle avoidance sensor, operating with a predefined obstacle-halting threshold of 150 cm. Data collection for model training and evaluation is accomplished using a virtual reality-based self-driving car simulator, resulting in a diverse dataset. The proposed system harnesses knowledge distillation from teacher models, such as the Nvidia model, to create a lightweight student model optimized for real-time inference while retaining competitive accuracy. Additionally, a custom Haar cascade classifier enhances traffic sign detection capabilities. The distilled model is then converted to TensorFlow Lite for efficient deployment on edge devices within autonomous vehicles, ensuring a secure and efficient navigation system. This innovative approach combines optimized distillation methods with specialized classifiers to facilitate the development of robust and real-time self-driving car systems.
KW - Energy efficiency
KW - intelligent transportation systems
KW - knowledge distillation
KW - lightweight model
KW - multiagent
KW - resource constraint devices
KW - self-driving cars
KW - sonarspinner
UR - https://www.scopus.com/pages/publications/85216863668
U2 - 10.1109/JSYST.2024.3524025
DO - 10.1109/JSYST.2024.3524025
M3 - Article
AN - SCOPUS:85216863668
SN - 1932-8184
VL - 19
SP - 382
EP - 391
JO - IEEE Systems Journal
JF - IEEE Systems Journal
IS - 2
ER -
