Autonomous Driving With Perception Uncertainties: Deep-Ensemble Based Adaptive Cruise Control

arXiv - CS - Systems and Control Pub Date : 2024-03-22 DOI:arxiv-2403.15577

Xiao Li, H. Eric Tseng, Anouck Girard, Ilya Kolmanovsky

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Abstract

Autonomous driving depends on perception systems to understand the environment and to inform downstream decision-making. While advanced perception systems utilizing black-box Deep Neural Networks (DNNs) demonstrate human-like comprehension, their unpredictable behavior and lack of interpretability may hinder their deployment in safety critical scenarios. In this paper, we develop an Ensemble of DNN regressors (Deep Ensemble) that generates predictions with quantification of prediction uncertainties. In the scenario of Adaptive Cruise Control (ACC), we employ the Deep Ensemble to estimate distance headway to the lead vehicle from RGB images and enable the downstream controller to account for the estimation uncertainty. We develop an adaptive cruise controller that utilizes Stochastic Model Predictive Control (MPC) with chance constraints to provide a probabilistic safety guarantee. We evaluate our ACC algorithm using a high-fidelity traffic simulator and a real-world traffic dataset and demonstrate the ability of the proposed approach to effect speed tracking and car following while maintaining a safe distance headway. The out-of-distribution scenarios are also examined.

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感知不确定性下的自动驾驶：基于深度集合的自适应巡航控制

自动驾驶依赖于感知系统来理解环境并为下游决策提供信息。虽然利用黑盒子深度神经网络（DNN）的先进感知系统具有类似人类的理解能力，但其不可预测的行为和缺乏可解释性可能会阻碍其在安全关键场景中的部署。在本文中，我们开发了一种 DNN 回归器集合（Deep Ensemble），它可以生成预测，并对预测的不确定性进行量化。在自适应巡航控制系统（ACC）的应用场景中，我们利用深度集合从 RGB 图像中估计领先车辆的前进距离，并使下游控制器能够考虑到估计的不确定性。我们开发了一种自适应巡航控制器，该控制器利用随机模型预测控制（MPC）和机会约束提供概率安全保证。我们使用高保真交通模拟器和真实交通数据集对自适应巡航控制器算法进行了评估，证明了所提出的方法能够在保持安全车距的同时实现速度跟踪和汽车跟随。此外，还研究了脱离分布的情况。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - CS - Systems and Control

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