受时空分离影响的虚拟耦合列车组控制:带紧急制动配置的分布式经济 MPC 方法

Xiaolin Luo , Tao Tang , Le Wang , Hongjie Liu
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引用次数: 0

摘要

新兴的虚拟耦合技术旨在以最小但安全的距离运行虚拟耦合列车组(VCTS)中的多个列车单元。为确保避免碰撞,安全距离的计算应采用最先进的时空分离原理,即在整个紧急制动(EB)过程中分离两个连续单元的紧急制动(EB)轨迹。在这种情况下,最小安全距离通常是通过数值计算得出的,不需要进行分析计算。因此,受约束的 VCTS 控制问题很难通过时空分离来解决,这在现有文献中仍是一个空白。为解决这一问题,我们提出了一种具有计算效率和理论保证的分布式经济模型预测控制(DEMPC)方法。具体来说,为了减轻计算负担,我们将隐式安全约束转化为显式线性约束,这样 DEMPC 中的最优控制问题就是一个可以高效求解的二次编程问题。在理论分析方面,我们利用兼容性约束、管子技术和终端成分调整,得出了保证 DEMPC 递归可行性和稳定性的充分条件。此外,我们还扩展了全局最优和分布式在线 EB 配置方法,以缩短 VCTS 之间的最小距离。最后,实验结果证明了所提方法的性能和优势。
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Virtually coupled train set control subject to space-time separation: A distributed economic MPC approach with emergency braking configuration
The emerging virtual coupling technology aims to operate multiple train units in a Virtually Coupled Train Set (VCTS) at a minimal but safe distance. To guarantee collision avoidance, the safety distance should be calculated using the state-of-the-art space-time separation principle that separates the Emergency Braking (EB) trajectories of two successive units during the whole EB process. In this case, the minimal safety distance is usually numerically calculated without an analytic formulation. Thus, the constrained VCTS control problem is hard to address with space-time separation, which is still a gap in the existing literature. To solve this problem, we propose a Distributed Economic Model Predictive Control (DEMPC) approach with computation efficiency and theoretical guarantee. Specifically, to alleviate the computation burden, we transform implicit safety constraints into explicitly linear ones, such that the optimal control problem in DEMPC is a quadratic programming problem that can be solved efficiently. For theoretical analysis, sufficient conditions are derived to guarantee the recursive feasibility and stability of DEMPC, employing compatibility constraints, tube techniques and terminal ingredient tuning. Moreover, we extend our approach with globally optimal and distributed online EB configuration methods to shorten the minimal distance among VCTS. Finally, experimental results demonstrate the performance and advantages of the proposed approaches.
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