自主车辆平面运动控制的动态规划方法

J. Silva, J. Sousa
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引用次数: 3

摘要

研究了自动驾驶车辆在对抗行为下的路径跟踪问题。目标是使参考路径的交叉轨迹误差保持在给定的公差范围内。对抗行为模型系统的不确定性和未知或估计不良的有界干扰。实现该目标的第一步是计算一个不变集,即车辆在确保交叉轨迹误差永远不会超过容差区间的情况下可能进入的最大状态集。这是通过动态规划完成的。然后考虑两种操作模式:当车辆在不变集合内时,目标是保持在不变集合内,同时最小化驱动努力和交叉轨迹误差的组合;否则,目标就变成在最短时间内达到不变集。每种模式对应一个独立处理的不同最优控制问题;因此,每种模式都有相应的控制律。我们讨论了在当前可用的计算系统上计算和实现这些控制律的有效方法。为了实现动态规划方法,将自动驾驶车辆建模为独轮车。以自主潜艇的六自由度非线性模型为例进行了仿真,验证了该控制策略的鲁棒性。
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A dynamic programming approach for the control of autonomous vehicles on planar motion
The problem of path following for autonomous vehicles under adversarial behavior is considered. The objective is to keep the cross-track error to the reference path inside a given tolerance interval. The adversarial behavior models system uncertainty and unknown or poorly estimated bounded disturbances. The first step to that objective is the computation of an invariant set, namely the maximal set of states that the vehicle may enter while ensuring that the cross-track error will never exceed the tolerance interval. This is done through dynamic programming. Two modes of operation are then considered: when the vehicle is inside the invariant set, the objective is to stay inside it while minimizing a combination of the actuation effort and cross-track error; otherwise, the objective becomes to reach the invariant set in minimum time. Each mode corresponds to a different optimal control problem which is dealt independently; thus, each mode has a corresponding control law. We discuss efficient ways of computing and implementing those control laws on currently available computational systems. For the purpose of the dynamic programming approach, the autonomous vehicles are modeled as an unicycle. Simulations with a six degree of freedom nonlinear model of an autonomous submarine are performed in order to illustrate the robustness of the control strategy.
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