Optimization of Rulebooks via Asymptotically Representing Lexicographic Hierarchies for Autonomous Vehicles

arXiv - CS - Robotics Pub Date : 2024-09-17 DOI:arxiv-2409.11199

Matteo Penlington, Alessandro Zanardi, Emilio Frazzoli

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Abstract

A key challenge in autonomous driving is that Autonomous Vehicles (AVs) must contend with multiple, often conflicting, planning requirements. These requirements naturally form in a hierarchy -- e.g., avoiding a collision is more important than maintaining lane. While the exact structure of this hierarchy remains unknown, to progress towards ensuring that AVs satisfy pre-determined behavior specifications, it is crucial to develop approaches that systematically account for it. Motivated by lexicographic behavior specification in AVs, this work addresses a lexicographic multi-objective motion planning problem, where each objective is incomparably more important than the next -- consider that avoiding a collision is incomparably more important than a lane change violation. This work ties together two elements. Firstly, a multi-objective candidate function that asymptotically represents lexicographic orders is introduced. Unlike existing multi-objective cost function formulations, this approach assures that returned solutions asymptotically align with the lexicographic behavior specification. Secondly, inspired by continuation methods, we propose two algorithms that asymptotically approach minimum rank decisions -- i.e., decisions that satisfy the highest number of important rules possible. Through a couple practical examples, we showcase that the proposed candidate function asymptotically represents the lexicographic hierarchy, and that both proposed algorithms return minimum rank decisions, even when other approaches do not.

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通过渐近表示自动驾驶汽车的词典层次优化规则手册

自动驾驶面临的一个主要挑战是，自动驾驶汽车（AV）必须满足多种规划要求，这些要求往往相互冲突。这些要求自然形成了一个层次结构--例如，避免碰撞比保持车道更重要。虽然这一层次结构的确切结构仍是未知数，但为了确保无人驾驶汽车满足预先确定的行为规范，开发出系统地考虑这一层次结构的方法至关重要。受自动驾驶汽车词典行为规范的启发，这项研究解决了一个词典多目标运动规划问题，在这个问题中，每个目标都比下一个目标重要得多--考虑到避免碰撞比违反变道规定重要得多。首先，我们引入了一种可渐近地表示反射阶次的多目标候选函数。与现有的多目标成本函数公式不同，这种方法能确保返回的解决方案渐近地符合词典行为规范。其次，受延续方法的启发，我们提出了两种渐近最小等级决策的算法，即满足尽可能多重要规则的决策。通过几个实际例子，我们证明了所提出的候选函数渐近地代表了lexicographic层次结构，而且所提出的两种算法都能返回最小等级决策，即使其他方法不能做到这一点。

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 - Robotics

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