Edge intelligence autonomous driving (EIAD) offers computing resources in autonomous vehicles for training deep neural networks. However, wireless channels between the edge server and the autonomous vehicles are time-varying due to the high-mobility of vehicles. Moreover, the required number of training samples for different data modalities, e.g., images, point-clouds, is diverse. Consequently, when collecting these datasets from vehicles to the edge server, the associated bandwidth and power allocation across all data frames is a large-scale multi-modal optimization problem. This article proposes a highly computationally efficient algorithm that directly maximizes the quality of training (QoT). The key ingredients include a data-driven model for quantifying the priority of data modality and two first-order methods termed accelerated gradient projection and dual decomposition for low-complexity resource allocation. Finally, high-fidelity simulations in Car Learning to Act (CARLA) show that the proposed algorithm reduces the perception error by $3\%$ and the computation time by $98\%$.
翻译:远程智能自主驾驶(EIAD)为培训深神经网络提供了自主车辆中的计算资源,但是,边缘服务器和自主车辆之间的无线通道由于车辆流动性高而时间变化不定,此外,不同数据模式(如图像、点球)所需的培训样本数量也各不相同,因此,从车辆到边缘服务器收集这些数据集时,所有数据框架的相关带宽和电力分配是一个大型的多模式优化问题。 本条提出一种计算效率高的算法,直接最大限度地提高培训质量(QoT)。关键要素包括数据驱动模型,以量化数据模式的优先度,以及两种第一级方法,即加速梯度投影和低兼容性资源分配的双重分解。最后,汽车学习到动作(CARLA)的高纤维模拟显示,拟议的算法将认知错误减少3 ⁇ 美元,计算时间减少98美元。