Leveraging on non-causal reasoning techniques for enhancing the cognitive management of highly automated vehicles

Ilias Panagiotopoulos, George Dimitrakopoulos
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引用次数: 0

Abstract

Highly Automated Vehicles (HAVs) are expected to improve the performance of terrestrial transportations by providing safe and efficient travel experience to drivers and passengers. As HAVs will be equipped with different driving automation levels, they should be capable to dynamically adapt their Level of Autonomy (LoA), in order to tackle sudden and recurrent changes in their environment (i.e., inclement weather, complex terrain, unexpected on-road obstacles, etc.). In this respect, HAVs should be able to respond not only on causal reasoning effects, which depend on present and past inputs from the external driving environment, but also on non-causal reasoning situations depending on future states associated with the external driving scene. On the other hand, driver’s personal preferences and profile characteristics should be assessed and managed properly, in order to enhance travel experience. In the light of the above, the present paper aims to tackle these challenges on how cognitive computing enables HAVs to operate each time in the best available LoA by responding quickly to changing environment situations and driver’s preferences. On this basis, an in-vehicle cognitive functionality is introduced, which collects data from various sources (sensor and driver layers), intelligently processing it to the decision-making layer, and finally, selecting the optimal LoA by integrating previous knowledge and experience. The overall approach includes the identification and utilization of a hybrid (data-driven and event-driven) algorithmic process towards reaching intelligent and proactive decisions. An indicative discrete event simulation analysis showcases the efficiency of the developed approach in proactively adapting the vehicle’s LoA.

利用非因果推理技术增强高度自动化车辆的认知管理
高度自动驾驶汽车(HAVs)有望为驾驶员和乘客提供安全高效的出行体验,从而改善地面交通的性能。由于无人驾驶汽车将配备不同的自动驾驶级别,因此它们应能够动态调整其自动驾驶级别(LoA),以应对环境的突然和反复变化(如恶劣天气、复杂地形、意外道路障碍等)。在这方面,无人驾驶汽车不仅应能根据外部驾驶环境当前和过去的输入做出因果推理响应,还应能根据与外部驾驶场景相关的未来状态做出非因果推理响应。另一方面,应适当评估和管理驾驶员的个人偏好和个人特征,以提升旅行体验。有鉴于此,本文旨在解决这些挑战,即认知计算如何通过快速响应不断变化的环境状况和驾驶员的偏好,使无人驾驶汽车每次都能在最佳可用LoA中运行。在此基础上,本文引入了车载认知功能,该功能可收集来自不同来源(传感器层和驾驶员层)的数据,并将其智能地处理到决策层,最后通过整合以往的知识和经验选择最佳 LoA。整体方法包括识别和利用混合(数据驱动和事件驱动)算法流程,以实现智能和主动决策。一项指示性离散事件模拟分析展示了所开发方法在主动调整车辆 LoA 方面的效率。
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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