基于自适应模型预测控制的轮轨混合动力车集成控制

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-07-19 DOI:10.3390/machines12070485
Boyuan Li, Zhengyu Pan, Junhua Liu, Shiyu Zhou, Shaoxun Liu, Shouyuan Chen, Rongrong Wang
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引用次数: 0

摘要

轮履混合动力系统具有轮子和履带相结合的优势,因此得到了广泛的应用。然而,轮式和履带式机构之间的耦合影响给稳定高效的控制器设计和实施带来了挑战。本文的重点是在履带和车轮都与地面接触的情况下,对车辆进行横向动态控制。首先根据轮胎刷模型和线性化一般履带模型建立了车辆的动态模型。在动态模型的基础上,考虑到车轮和履带的耦合性和非线性,设计了一种新颖的自适应模型预测控制(AMPC)方法,以同时调节两个机构。与传统的模型预测控制方法相比,AMPC 控制器将侧滑角和滑移率作为约束条件,以防止车辆达到不稳定状态。仿真验证了该控制器的有效性,结果表明该控制器有能力优化目标的偏航率响应,同时保持车辆的横向稳定性,并通过施加约束防止打滑。
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Integrated Control of a Wheel–Track Hybrid Vehicle Based on Adaptive Model Predictive Control
Hybrid wheel–track systems have found extensive applications due to the advantages a combination of wheels and tracks. However, the coupling influence between the wheeled and tracked mechanisms poses a challenge to stable and efficient controller design and implementation. This paper focuses on the lateral dynamic control of a vehicle in scenarios where both tracks and wheels are in contact with the ground. A dynamic model of a vehicle is first established based on the tire brush model and linearized general track model. Based on the dynamic model, a novel adaptive model predictive control (AMPC) method is designed considering the coupling and nonlinearity of the wheels and tracks to simultaneously regulate both mechanisms. Compared with traditional model predictive control approaches, the AMPC controller takes the side-slip angle and slip ratio as constraints to prevent the vehicle from reaching unstable states. Simulations are conducted to validate the effectiveness of the controller, and the results indicate that the controller has the capacity to optimize the objective’s yaw-rate response while maintaining lateral vehicle stability and preventing slip by imposing constraints.
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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