Task offloading in vehicular environments is essential for efficient computation and resource utilization among connected vehicles. However, traditional approaches e. g. , Deep Reinforcement Learning (DRL) and heuristic methods often struggle with dynamic adaptation, communication overhead, and scalability in dense, fast-changing scenarios. This paper proposes an edge-intelligent framework that leverages a Large Language Model (LLM) deployed at Roadside Unit (RSU) edge nodes to optimize dynamic, multi objective offloading decisions. The LLM is fine tuned on a structured dataset encoding real time vehicular states (mobility, CPU, bandwidth, battery), task characteristics, and historical offloading outcomes, enabling reasoning over multi-dimensional inputs to select vehicle-to-vehicle (V2V) or vehicle-to-edge (V2E) destinations. Experimental evaluation under high-density and highly dynamic conditions demonstrate that the proposed LLM-based scheme outperforms state-of-the-art DRL and Greedy baselines, achieving a 15. 3% average reduction in task latency and a 22. 1% improvement in energy efficiency over the best DRL baseline, while maintaining a 97. 5% task completion rate. Moreover, a fine tuned and quantized deployment reduces inference latency, yielding 1. 8 \ (\) faster decision making at the edge crucial for stringent vehicular deadlines. We discuss remaining challenges, including compute footprint at RSUs, end-to-end latency under bursty loads, and energy aware adaptation, and outline optimization opportunities for real world deployment. Collectively, these results establish LLM-driven offloading as a scalable, accurate, and responsive paradigm for next generation vehicular edge intelligence.
Trabelsi et al. (Sun,) studied this question.
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