自动驾驶电动汽车动态测试1/10模型设计

Proceedings of the 2022 International Conference on Computer, Control, Informatics and Its Applications Pub Date : 2022-11-22 DOI:10.1145/3575882.3575898

Mochamad Adityo Rachmadi, Galuh Prihantoro, T. Nugroho, D. Cahya, Heru Taufiqurrohman, Zaid Cahya

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引用次数: 0

摘要

在自动驾驶电动汽车控制系统的设计中，一个代表实际系统的模型可以为研究对象提供方便，因为设计可以只关注需要研究的领域。然而，有必要了解比例模型的动态特性，这将作为自动驾驶汽车运动控制设计的参考，特别是在制动时。大多数研究人员使用低成本的数学模型来测试车辆在制动过程中的动态反应。然而，它可能不能完全显示现实世界的反应，所以使用比例模型有望解决这个问题。测试以1:10的比例在车辆模型上进行，重点是在制动过程中的稳定性。因此，在减速度值低于2.94 m/s2，停车时间大于1.3 s，停车距离不超过200 cm的情况下，获得了制动舒适性。这些结果可以作为自主电动汽车模型运动控制设计的指导。

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The Design of 1/10 Scale Model for Autonomous Electric Vehicle Dynamic Testing

In designing an autonomous electric vehicle control system, a model representing the actual system could provide convenience to the research object because the design can focus only on the area that needs to be researched. However, it is necessary to know the dynamic characteristics of the scaled model, which is used as a reference in designing motion control in autonomous vehicles, especially when braking. Most researchers use low-cost mathematical modelling to test the dynamic reaction of the vehicle during braking. However, it might not fully show real-world responses, so using scaled models is expected to bridge the problem. Testing was carried out on a vehicle model with a scale of 1:10, which focused on stability during its braking. As a result, braking comfort is obtained with a deceleration value below 2.94 m/s2, a stopping time of more than 1.3 s and a stopping distance not exceeding from 200 cm. These results can be adopted as a guideline for the motion control design in the autonomous electric vehicles model.

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Proceedings of the 2022 International Conference on Computer, Control, Informatics and Its Applications

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