Design and simulation of automotive radar for autonomous vehicles

Q3 Engineering
H. Ha, Santosh R. Patil, S. Shirguppikar, Shrikant Pawar, Tu Ngoc Do, P. Nguyen, Thanh Thi Phuong Le, L. Nguyen, Tam Chi Nguyen
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引用次数: 0

Abstract

Modern automobile technology is pushing towards maximizing road safety, connected vehicles, autonomous vehicles, etc. Automotive RADAR is core sensor technology used for ADAS (Advanced Driver Assistance Technology), ACC (Adaptive Cruise Control), AEB (Automatic Emergency Braking System), traffic assistance, parking aid, and obstacle/pedestrian detection. Despite being inexpensive, RADAR technology provides robust results in harsh conditions such as harsh weather, extreme temperature, darkness, etc. However, the performance of these systems depends on the position of the RADAR and its characteristics like frequency, beamwidth, and bandwidths. Moreover, the characterization of varied materials like layers of paint, polish, primer, or layer of rainwater needs to be analyzed. This performance can be predicted through real-time simulation using advanced FEM software like Altair FEKO&WinProp. These simulations can provide valuable insight into the performance of the system, allowing engineers to optimize the system for specific use cases. For example, simulation can be used to determine the optimal parameters of the RADAR system for a given application. This information can then be used to design and build a physical model or prototype that is optimized for the desired performance. These simulations play a prominent role in determining appropriate data collection and sensor fusion, which reduces the cost and time required for the development of a physical model or prototype. The continued growth and demand for advanced safety features in vehicles further highlight the importance of RADAR technology in modern automobile technology. By accurately characterizing the environment and simulating the system's behavior in real time, engineers can optimize RADAR systems for specific use cases, contributing to safer and more efficient driving experiences
自动驾驶汽车雷达的设计与仿真
现代汽车技术正朝着最大化道路安全、联网汽车、自动驾驶汽车等方向发展。汽车雷达是用于ADAS(高级驾驶辅助技术)、ACC(自适应巡航控制)、AEB(自动紧急制动系统)、交通辅助、停车辅助和障碍物/行人检测的核心传感器技术。尽管价格低廉,但雷达技术在恶劣天气、极端温度、黑暗等恶劣条件下仍能提供可靠的检测结果。然而,这些系统的性能取决于雷达的位置及其特性,如频率、波束宽度和带宽。此外,还需要分析各种材料的特性,如油漆层、抛光层、底漆层或雨水层。这种性能可以通过使用先进的有限元软件如Altair FEKO&WinProp进行实时仿真来预测。这些模拟可以为系统性能提供有价值的见解,使工程师能够针对特定用例优化系统。例如,模拟可用于确定给定应用的雷达系统的最佳参数。然后,这些信息可用于设计和构建针对所需性能进行优化的物理模型或原型。这些模拟在确定适当的数据收集和传感器融合方面发挥着重要作用,从而减少了开发物理模型或原型所需的成本和时间。对车辆先进安全功能的持续增长和需求进一步凸显了雷达技术在现代汽车技术中的重要性。通过准确描述环境特征并实时模拟系统行为,工程师可以针对特定用例优化雷达系统,从而提供更安全、更高效的驾驶体验
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
EUREKA: Physics and Engineering
EUREKA: Physics and Engineering Engineering-Engineering (all)
CiteScore
1.90
自引率
0.00%
发文量
78
审稿时长
12 weeks
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