Optimizing Autonomous Obstacle Avoidance with PON Architecture and SDN-Based Dynamic Scheduling

2026-99-0592

To be published on 07/10/2026

Authors
Abstract
Content
This study addresses the challenges of communication delays and system stability in autonomous obstacle avoidance (AOA) systems under next-generation vehicular electronic/electrical architectures. A centralized PON-based architecture is proposed, leveraging XGSPON technology to enhance bandwidth capacity and reduce electromagnetic interference, while rigorously analyzing worst-case in-vehicle communication (IVOC) delays. To mitigate latency impacts, a Software-Defined Networking (SDN)-driven dynamic scheduling strategy prioritizes safety-critical data streams (e.g., environmental perception, motion control) through adaptive resource allocation. Further integrated with a robust H-infinity LQR controller, the co-design framework ensures precise trajectory tracking and suppresses steering oscillations under communication uncertainties. Simulation tests validate the framework's efficacy, demonstrating significant reductions in loop delays and improved dynamic stability in complex scenarios. This work bridges communication efficiency and control robustness, offering a scalable solution for advancing safety-critical autonomous driving systems.
Meta TagsDetails
Citation
Wang, W., Han, M., and Cao, W., "Optimizing Autonomous Obstacle Avoidance with PON Architecture and SDN-Based Dynamic Scheduling," The 1st International Academic Conference on Intelligent Transportation and Low-Altitude Transport (ITLAT2025), Nantong, China, June 20, 2025, .
Additional Details
Publisher
Published
To be published on Jul 10, 2026
Product Code
2026-99-0592
Content Type
Technical Paper
Language
English