一种基于自抗扰控制的电子差速控制策略研究
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U469. 72 TH113. 2

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河北省自然科学基金(E2019202481)、天津市科委(18YFZBFX00030)项目资助


Research on an electronic differential control strategy based on active disturbance rejection control
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    摘要:

    电动车辆转向时,复杂路况及车况综合作用下,驱动轮承载更强扰动的负荷,驱动轮滑移运动所占比重不确定性增大, 影响行车稳定与安全。 为此,设计基于自抗扰控制(ADRC)的电子差速控制(EDC)策略,并利用混沌粒子群优化算法(CPSO) 设计控制器参数。 构建 7 自由度整车模型,以滑移率为控制量、驱动轮电机转矩为输出,设计基于 CPSO-ADRC 的电子差速控 制器,使转向过程中滑移率始终保持在目标值上;提出的 EDC 系统与配置有模糊 PID 控制器和滑模控制器( SMC)的 EDC 系统 进行了对比分析,在 Simulink / Carsim 平台和实车上进行不同路况的 EDC 实验。 结果表明,基于 CPSO-ADRC 的 EDC 策略具有 强抗干扰能力,其快速性相较其他两种策略提高了 20% 和 14. 4% ,横摆角速度的波幅均降低了约 50% ,增强了 EDC 的快速性和 鲁棒性,更有效保证电动车辆转向过程的行驶安全。

    Abstract:

    When the electric vehicle is steering, the driving wheel will bear more disturbing load under the combined actions of complex road conditions and vehicle conditions, and the proportion uncertainty of the sliding motion of the driving wheel increases, which will affect the driving stability and safety. Therefore, the active disturbance rejection control (ADRC) based electronic differential control (EDC) strategy is designed, and the Chaos Particle Swarm Optimization (CPSO) algorithm is used to design the controller parameters. A seven degree of freedom complete automobile model is constructed, and the electronic differential controller based on CPSO-ADRC is designed taking slip rate as the control quantity and driving wheel motor torque as the output, so that the slip rate is always kept at the target value in the steering process. The proposed EDC system is compared with the EDC systems equipped with fuzzy PID controller and sliding mode controller and analyzed, and the EDC experiments under different road conditions were carried out on Simulink / CarSim platform and real vehicles. The results show that the electronic differential control strategy based on CPSO-ADRC has strong antiinterference ability, its speediness is increased by 20% and 14. 4% , respectively compared with the other two strategies, the amplitude of yaw rate is reduced by about 50% , the speediness and robustness of EDC are enhanced, and the driving safety in electric vehicle steering process is more effectively guaranteed.

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姚 芳,赵晓鹏,吴正斌,林祥辉,郑 帅.一种基于自抗扰控制的电子差速控制策略研究[J].仪器仪表学报,2021,(3):177-191

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  • 在线发布日期: 2023-06-28
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