紧急情况下自动驾驶汽车的应急运行策略和运动规划方法。

IF 5.7 1区 工程技术 Q1 ERGONOMICS
Tianyang Gong , Xiumin Yu , Qunli Zhang , Zilin Feng , Shichun Yang , Yaoguang Cao , Jingyun Xu , Xinjie Feng , Zhaowen Pang , Yu Wang , Peng Wang
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引用次数: 0

摘要

确保紧急情况下的驾驶操作安全是自动驾驶车辆防止事故发生的首要任务,尤其是当车辆运动完全依赖于自动驾驶系统时。在为危急情况设计紧急避撞策略时,必须评估众多因素,如轨迹可行性、车辆运动稳定性和驾驶员舒适度。因此,本研究提出了一种紧急操作框架,利用无碰撞区域计算为机动决策提供信息,促进避撞轨迹规划,防止车辆碰撞。在发生危险时,紧急机动决策模块会评估安全等级,并在生成轨迹之前通过考虑预先指定的候选机动集群来选择安全终端状态。这一过程可避免不可行的轨迹,并在可行的情况下选择能让驾驶员更舒适的操纵。随后,动态轨迹规划模块将无碰撞区域转换为混合整数约束,利用时变非线性模型预测控制(NMPC)进行轨迹规划,并通过在整个运动规划过程中整合动态和无碰撞约束来确保车辆运动的稳定性。最终,模拟和现场测试验证了该框架的有效性,在紧急情况下,该框架能够迅速、安全地减少碰撞。该框架可独立于智能驾驶系统自主运行,仅在风险事件发生时介入,并在事件发生后将控制权交还给驾驶员或智能系统。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An emergency operation strategy and motion planning method for autonomous vehicle in emergency scenarios
Ensuring driving operational safety in emergency scenarios is paramount for autonomous vehicles to prevent accidents, particularly when vehicle motion completely depends on autonomous systems. Numerous factors must be evaluated when designing emergency collision avoidance strategies for critical situations, such as trajectory feasibility, vehicle motion stability, and driver comfort. Therefore, this study proposes a framework for emergency operation that uses collision-free area calculations to inform maneuver decisions and facilitate collision avoidance trajectory planning, preventing vehicle collisions. In case of danger, the emergency maneuver decision module evaluates the safety level and selects safety terminal state by considering a pre-specified cluster of candidate maneuvers before generating trajectories. This process avoids infeasible trajectories and selects maneuvers for greater driver comfort when available. Subsequently, the dynamic trajectory planning module converts the collision-free area into mixed-integer constraints, utilizing time-varying Nonlinear Model Predictive Control (NMPC) for trajectory planning and ensuring vehicle motion stability by integrating dynamic and collision-free constraints throughout the motion planning process. Eventually, simulations and field testing validate the framework’s effectiveness, mitigating collisions in emergency scenarios with prompt and safe operations. The framework is designed to function autonomously, independent of the intelligent driving system, engaging only during risk events and restoring control to the driver or the intelligent system after the event.
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来源期刊
CiteScore
11.90
自引率
16.90%
发文量
264
审稿时长
48 days
期刊介绍: Accident Analysis & Prevention provides wide coverage of the general areas relating to accidental injury and damage, including the pre-injury and immediate post-injury phases. Published papers deal with medical, legal, economic, educational, behavioral, theoretical or empirical aspects of transportation accidents, as well as with accidents at other sites. Selected topics within the scope of the Journal may include: studies of human, environmental and vehicular factors influencing the occurrence, type and severity of accidents and injury; the design, implementation and evaluation of countermeasures; biomechanics of impact and human tolerance limits to injury; modelling and statistical analysis of accident data; policy, planning and decision-making in safety.
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