Adaptive differential steering strategy for distributed driving unmanned ground vehicle with variable configurations based on modified localized modelling sliding mode control

IF 6.3 2区 计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS
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引用次数: 0

Abstract

When performing complex tasks such as position transfer and material transportation, the distributed driving unmanned platform with variable configurations needs to address the challenge of multi-wheel cooperative torque distribution control to achieve high-performance differential steering and enhance vehicle dynamics. The configuration change will impact the dynamic performance of the unmanned platform, posing a challenge to the performance of the existing control strategy based on mathematical model development. In order to address the aforementioned issues, this paper analyzes the impact of changes in vehicle configuration on steering gain and proposes a hierarchical adaptive differential steering strategy based on variable vehicle configurations. Firstly, the response characteristics of the yaw angle relative to the active yaw moment under the influence of changes in wheelbase and tread are analyzed. Based on this analysis, two structural modes, maneuverable and balanced, are selected. Secondly, a localized-modelling sliding mode control method with an extended state observer is proposed to estimate the desired yaw moment in the upper controller, considering the motor's execution delay. Then, the lower controller optimizes the torque of each wheel in real-time using the whale optimization algorithm. It aims to optimize tire energy dissipation and tire load rate while ensuring driving stability and achieving differential steering. Finally, through co-simulation and experiments on a scaled prototype, the reliability of the dynamics theory and the superiority of the control algorithm are validated. This optimization has led to significant improvements in the tire dissipation energy index and tire load rate index.

基于改进型局部建模滑模控制的分布式驾驶无人地面车辆自适应差分转向策略
在执行位置转移和材料运输等复杂任务时,配置可变的分布式驾驶无人平台需要解决多轮协同扭矩分配控制的难题,以实现高性能差动转向并增强车辆动态性能。配置变化会影响无人平台的动态性能,对现有基于数学模型开发的控制策略的性能提出了挑战。针对上述问题,本文分析了车辆配置变化对转向增益的影响,并提出了一种基于可变车辆配置的分层自适应差分转向策略。首先,分析了轴距和胎面变化影响下偏航角相对于主动偏航力矩的响应特性。在此基础上,选择了机动和平衡两种结构模式。其次,考虑到电机的执行延迟,提出了一种带有扩展状态观测器的局部建模滑动模式控制方法,用于估计上部控制器中的期望偏航力矩。然后,下部控制器使用鲸鱼优化算法实时优化每个车轮的扭矩。其目的是在确保行驶稳定性和实现差速转向的同时,优化轮胎能量耗散和轮胎负载率。最后,通过联合仿真和比例原型实验,验证了动力学理论的可靠性和控制算法的优越性。通过优化,轮胎耗能指数和轮胎负载率指数得到了显著改善。
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
ISA transactions
ISA transactions 工程技术-工程:综合
CiteScore
11.70
自引率
12.30%
发文量
824
审稿时长
4.4 months
期刊介绍: ISA Transactions serves as a platform for showcasing advancements in measurement and automation, catering to both industrial practitioners and applied researchers. It covers a wide array of topics within measurement, including sensors, signal processing, data analysis, and fault detection, supported by techniques such as artificial intelligence and communication systems. Automation topics encompass control strategies, modelling, system reliability, and maintenance, alongside optimization and human-machine interaction. The journal targets research and development professionals in control systems, process instrumentation, and automation from academia and industry.
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