Abstract
In this paper, a two-timescale radio access network (RAN) slicing and computing task offloading problem is investigated for a cloud-enabled autonomous vehicular network (C-AVN). We aim at jointly maximizing the communication and computing resource utilization with diverse quality-of-service (QoS) guarantee for autonomous driving tasks. Specifically, to capture the small-timescale network dynamics, a computing task scheduling problem is formulated as a stochastic optimization program, for maximizing the long-term network-wide computation load balancing with minimum task offloading variations. Due to the large problem size and unavailable network state transition probabilities, we employ cooperative multi-agent deep <italic xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">Q</i> -learning (MA-DQL) with fingerprint to solve the problem by learning the set of stationary task offloading policies with stabilized convergence. Given the task offloading decisions, we further study a RAN slicing problem in a large timescale, which is formulated as a convex optimization program. We focus on optimizing the radio resource slicing ratios among base stations, to maximize the aggregate network utility with statistical QoS provisioning for autonomous driving tasks. Based on the impact of radio resource slicing on computation load balancing, we propose a two-timescale hierarchical optimization framework to maximize both communication and computing resource utilization. Extensive simulation results are provided to demonstrate the effectiveness of the proposed framework in comparison with state-of-the-art schemes.
Highlights
F UTURE intelligent transportation systems are envisioned to have more and more autonomous driving vehicles (AVs) operated on the roads with increased levels of automation [2]
To explicitly characterize the impact of radio resource slicing on balancing the computation load such that both communication and computing resource utilization can be maximized, in this paper, we present a two-timescale radio access network (RAN) slicing and computing task scheduling framework for a cloud-enabled autonomous vehicular network (C-AVN)
A two-lane bidirectional road segment of 1.5 km is created using the Simulation of Urban MObility (SUMO) traffic simulator [37], with real vehicular traffic trace loaded from a provincial roadway in Xinjiang, China
Summary
F UTURE intelligent transportation systems are envisioned to have more and more autonomous driving vehicles (AVs) operated on the roads with increased levels of automation (e.g., levels 3-5) [2]. The development and commercialization of AVs are essential for intelligent navigation, efficient traffic management, and driving safety. In recent years, both automotive industry and research community have been investigating how to increase the AV automation levels by using advanced sensing technologies, such as vision-based cameras, light detection and ranging (LiDAR), and radio detection and ranging (RADAR) [2]–[4]. To execute different autonomous driving tasks (e.g., vehicle localization, object detection and tracking, and data fusion), the raw data sensed from the surrounding environment needs to be processed/computed, in form of computing tasks, to extract useful information for vehicles to perform responsive operations, such as lane changing, acceleration/deceleration, and route planning. With an increasing amount of sensed data, the computation demands can overwhelm the on-board processing capacity, leading to prolonged computation responsiveness and excessive power consumption.
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