High-Performance Perception: A camera-based approach for smart autonomous electric vehicles in smart cities

IF 2.5 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Electrification Magazine Pub Date : 2023-06-01 DOI:10.1109/MELE.2023.3264920

Julian Stähler, C. Markgraf, Mathias Pechinger, D. Gao

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引用次数: 0

Abstract

Mobility is fundamental for the wealth and health of the world’s population, and it has a significant influence on our daily life. However, with the increasing complexity of traffic, the need to transport goods, and growing urbanization, improving the quality of mobility in terms of time, space, and air becomes more challenging. An autonomous electric vehicle offers technology and potential for new mobility concepts in smart cities. Today, many vehicles have been developed with automated driving capabilities. A safety driver is still required to intervene in most cases if the autonomous electric vehicle is not able to handle a situation in a safe and, at the same time, reliable way. One important aspect to achieve safety and reliability goals is a robust and efficient perception of the vehicle’s environment. The tragic accident involving an Uber self-driving car killing a pedestrian in 2018 highlighted the importance of perception in autonomous driving. In its investigation, the U.S. National Transportation Safety Board found that the Uber self-driving car and its safety driver involved in the accident failed to detect the pedestrian at the same time. Since this accident, the autonomous vehicle industry has been working to improve perception systems through the use of advanced sensors, machine learning algorithms, and other technologies. A variety of sensor technologies are used in vehicles to detect objects and perceive the vehicles’ surroundings. Cameras and radars are among the widely used technologies for sensing systems, as they are cheap and reliable, and as these sensors are operating at different wavelengths, they are not susceptible to common errors. While some companies solely use cameras and radars, others also use lidars in their sensing systems. These sensors are widely used in the industry, and the technology itself is continuously enhanced, leading to new developments, such as 4D lidar, which are capable of measuring not only the distance of an object but also its velocity by evaluating the phase shift of the returned light. Various methods for the perception of the environment exist and rely on different kinds of sensors. Machine learning-based methods have evolved rapidly in recent years and are currently leading the field in perception, particularly in the tasks of object detection and classification.

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高性能感知:智能城市中智能自动驾驶电动汽车的基于摄像头的方法

流动性对世界人口的财富和健康至关重要，它对我们的日常生活产生重大影响。然而，随着交通的日益复杂，货物运输的需要，以及城市化的发展，从时间、空间和空气方面提高交通质量变得更具挑战性。自动驾驶电动汽车为智慧城市的新移动概念提供了技术和潜力。如今，许多车辆都具有自动驾驶功能。在大多数情况下，如果自动驾驶电动汽车无法以安全和可靠的方式处理情况，仍然需要安全驾驶员进行干预。实现安全和可靠性目标的一个重要方面是对车辆环境的稳健和有效感知。2018年，优步自动驾驶汽车撞死一名行人的悲惨事故凸显了感知在自动驾驶中的重要性。美国国家运输安全委员会在调查中发现，发生事故的优步自动驾驶汽车和安全驾驶员未能同时发现行人。自这次事故以来，自动驾驶汽车行业一直在努力通过使用先进的传感器、机器学习算法和其他技术来改进感知系统。各种传感器技术用于车辆检测物体和感知车辆周围环境。相机和雷达是传感系统中广泛使用的技术，因为它们便宜可靠，而且由于这些传感器在不同的波长上工作，它们不容易受到常见错误的影响。虽然有些公司只使用摄像头和雷达，但其他公司也在其传感系统中使用激光雷达。这些传感器在工业上得到了广泛的应用，而且技术本身也在不断增强，导致了新的发展，例如4D激光雷达，它不仅能够通过评估返回光的相移来测量物体的距离，还能够测量物体的速度。存在各种感知环境的方法，并依赖于不同类型的传感器。基于机器学习的方法近年来发展迅速，目前在感知领域处于领先地位，特别是在物体检测和分类任务中。

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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来源期刊

IEEE Electrification Magazine ENGINEERING, ELECTRICAL & ELECTRONIC-

CiteScore

5.80

自引率

0.00%

发文量

期刊介绍： IEEE Electrification Magazine is dedicated to disseminating information on all matters related to microgrids onboard electric vehicles, ships, trains, planes, and off-grid applications. Microgrids refer to an electric network in a car, a ship, a plane or an electric train, which has a limited number of sources and multiple loads. Off-grid applications include small scale electricity supply in areas away from high voltage power networks. Feature articles focus on advanced concepts, technologies, and practices associated with all aspects of electrification in the transportation and off-grid sectors from a technical perspective in synergy with nontechnical areas such as business, environmental, and social concerns.