基于快速控制原型的自适应前照灯系统开发

毛政; 周建鹏; 龚元明

doi:10.12299/jsues.24-0119

基于快速控制原型的自适应前照灯系统开发

doi: 10.12299/jsues.24-0119

上海工程技术大学机械与汽车工程学院, 上海 201620

详细信息

作者简介:
毛政：毛　政（2000 − ），男，硕士生，研究方向汽车电子。E-mail：17860369300@163.com

通讯作者:
龚元明（1964 − ），男，教授，博士，研究方向为汽车电子。E-mail：gongyuanming@tsinghua.org.cn

中图分类号: U463.65+1
计量
- 文章访问数: 15
- HTML全文浏览量: 8
- PDF下载量: 2
- 被引次数: 0
出版历程
- 收稿日期: 2024-04-24
- 网络出版日期: 2025-12-22
- 刊出日期: 2025-09-30

Development of adaptive front-light system based on rapid control prototype

School of Mechanical and Automotive Engineering, Shanghai University of Engineering Science, Shanghai 201620, China

摘要

摘要: 针对传统车灯系统开发效率低、迭代周期长、实车仿真成本高，且无法满足现代汽车智能化需求等问题，基于前照灯自适应控制逻辑，提出前照灯照明角度偏转计算公式，构建自适应前照灯系统（adaptive front-lighting system, AFS）模型。利用基于dSPACE的快速控制原型（rapid control prototype, RCP）技术，将AFS模型快速转化为可运行的实时系统，模拟多种复杂驾驶场景验证AFS控制逻辑和照明角度偏转的准确性和合理性。应用结果表明，此开发方法缩短了系统开发周期，提高了开发效率，所提出的AFS显著提高了驾驶的安全性和舒适性。
- 快速控制原型 /
- dSPACE平台 /
- 自适应前照灯系统 /
- 模块化设计
Abstract: Traditional vehicle lighting control system are characterized by low development efficiency, long iteration cycles, high costs of real-vehicle simulation, and an inability to meet the intelligent demands of modern automobiles. To address these issues, a calculation formula for the deflection of the headlamp's illumination angle was proposed based on the adaptive control logic of the headlamps, and a model of the adaptive front-lighting system (AFS) was constructed. Then, the AFS model was rapidly transformed intoan executable real-time system by utilizing the dSPACE-based rapid control prototyping (RCP) technology. Various complex driving scenarios were simulated to verify the accuracy and validity of the AFS control logic and the deflection of the illumination angle. The application results indicate that this development method shortens the system development cycle and improve development efficiency, and that the proposed AFS significantly enhances driving safety and comfort.
- rapid control prototype (RCP) /
- dSPACE platform /
- adaptive front-lighting system (AFS) /
- modular design

HTML全文

图 1 RCP系统硬件图

Figure 1. RCP system hardware

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图 2 传统RCP开发流程图

Figure 2. Traditional RCP development process

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图 3 0 × 187报文格式图

Figure 3. 0 × 187 message format

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图 4 报文控制模型图

Figure 4. Message control model

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图 5 AFS控制状态图

Figure 5. Partial AFS system state diagram

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图 6 车速与制动距离二次拟合图

Figure 6. Quadratic fitting diagram of vehicle speed and braking distance

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图 7 弯道几何关系图

Figure 7. Geometric relation of turning

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图 8 AFS系统水平角度调整示意图

Figure 8. Schematic diagram of horizontal angle adjustment of AFS system

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图 9 车身俯仰变化照明示意图

Figure 9. Geometric relation of turning

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图 10 前照灯配光示意图

Figure 10. Headlamp light distribution indication

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图 11 AFS角度偏转控制建模示意图

Figure 11. AFS angular deflection control modeling

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图 12 上位机与AutoBox连接流程图

Figure 12. Flow chart of connection between upper computer and AutoBox

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图 13 硬件总体布局图

1—汽车前照灯；2—上位机；3—CAN总线；4—网口；5—MicroAutoBox II；6—电源箱。

Figure 13. General layout of hardware

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图 14 仿真界面图

Figure 14. Simulation interface

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表 1 车速与制动距离

Table 1. Vehicle speed and braking distance

车速/(km·h⁻¹) 制动距离/m 车速/(km·h⁻¹) 制动距离/m

10 3.6 70 43.5

20 7.6 80 53.7

30 12.7 90 64.9

40 19.0 100 77.0

50 26.2 110 88.4

60 34.4 120 104.2

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