Robust torque-observed control with safe input–output constraints for hydraulic in-wheel drive systems in mobile robots

IF 5.4 2区计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS

Control Engineering Practice Pub Date : 2025-07-02 DOI:10.1016/j.conengprac.2025.106459

Mehdi Heydari Shahna, Pauli Mustalahti, Jouni Mattila

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引用次数: 0

Abstract

Hydraulic-powered in-wheel drive (IWD) mechanisms enhance the maneuverability, traction, and maintenance efficiency of heavy-duty wheeled mobile robots (HWMRs) by enabling independent operation of each wheel. Sufficient motion in such HWMR systems relies on a multi-stage power transmission mechanism that integrates control valves, hydraulic motors, gearboxes, and, ultimately, nonlinear ground-interaction wheel dynamics on rough terrain. Deviations in each stage of these independently operated wheel systems—arising from modeling uncertainties and disturbances such as wheel slippage and uneven torque distribution on rough terrain—can disrupt motion balance between wheels and further amplify deviations. This can lead the robot to deviate from its course, oscillate, or lose traction, ultimately resulting in overall instability, which may pose a risk to the heavy-weight robot’s surrounding environment. To develop a synchronous control strategy for distributed HWMR systems to mitigate such challenges in uncertain environments, this paper proposes a novel robust torque-observer-based valve control (RTOVC) framework for IWD-actuated wheels, guaranteeing robustness and uniformly exponential stability of the entire system. As a foundation for this approach, a robust torque observer network based on an adaptive barrier Lyapunov function (BLF) is designed to obtain the required wheel/motor torques, ensuring that the actual velocities of IWD-actuated wheels align with the reference values in motion dynamic frames in the presence of wheel slippages. It eliminates the closed-loop dependency on fault-prone torque or pressure sensors in hydraulic actuation mechanisms. Building on this, an additional adaptive BLF-based control network in the valve-actuated hydraulic mechanism is employed to regulate fluid flow, generating the required torque in the first network for each wheel under system uncertainties. The RTOVC framework reduces fault risks in HWMRs by constraining key input–output signals—such as valve control signals, actual wheel velocities, tracking errors, and required motor/wheel torques—within logarithmic BLFs, ensuring safe operation. A comprehensive experimental analysis on a 6,500-kg hydraulic-powered IWD-actuated HWMR operating on rough terrain, where failures may arise due to severe slipping conditions and hydraulic system uncertainties, confirms the RTOVC’s robust performance compared with two other state-of-the-art control strategies.

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移动机器人液压轮毂驱动系统的安全输入输出约束鲁棒转矩观察控制

液压驱动轮内驱动（IWD）机构通过实现每个车轮的独立操作，提高了重型轮式移动机器人（HWMRs）的机动性、牵引力和维护效率。在这种HWMR系统中，充分的运动依赖于多级动力传输机构，该机构集成了控制阀、液压马达、齿轮箱，以及最终在崎岖地形上的非线性地面相互作用车轮动力学。这些独立运行的车轮系统在每个阶段的偏差——由建模的不确定性和干扰引起，如车轮打滑和粗糙地形上的不均匀扭矩分配——会破坏车轮之间的运动平衡，并进一步放大偏差。这可能导致机器人偏离其路线，振荡或失去牵引力，最终导致整体不稳定，这可能对重型机器人的周围环境构成风险。为了开发分布式HWMR系统的同步控制策略，以减轻不确定环境中的这些挑战，本文提出了一种新的基于扭矩观测器的鲁棒阀控制（RTOVC）框架，用于iwd驱动车轮，保证整个系统的鲁棒性和均匀指数稳定性。作为该方法的基础，设计了基于自适应障碍Lyapunov函数（BLF）的鲁棒扭矩观测器网络，以获得所需的车轮/电机扭矩，确保在存在车轮滑移的情况下，iwd驱动车轮的实际速度与运动动态框架中的参考值一致。它消除了闭环依赖于容易故障的扭矩或压力传感器在液压作动机构。在此基础上，在阀动液压机构中增加一个基于自适应blf的控制网络来调节流体流量，在系统不确定的情况下，在第一个网络中为每个车轮产生所需的扭矩。RTOVC框架通过将关键的输入输出信号（如阀门控制信号、实际车轮速度、跟踪误差和所需的电机/车轮扭矩）限制在对数blf内，从而降低了HWMRs的故障风险，确保了安全运行。一项对6500公斤液压驱动iwd驱动HWMR进行的综合实验分析表明，与其他两种最先进的控制策略相比，RTOVC具有强大的性能。该HWMR在崎岖地形上运行，由于严重的滑动条件和液压系统的不确定性，可能会出现故障。

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来源期刊

Control Engineering Practice 工程技术-工程：电子与电气

CiteScore

9.20

自引率

12.20%

发文量

183

审稿时长

44 days

期刊介绍： Control Engineering Practice strives to meet the needs of industrial practitioners and industrially related academics and researchers. It publishes papers which illustrate the direct application of control theory and its supporting tools in all possible areas of automation. As a result, the journal only contains papers which can be considered to have made significant contributions to the application of advanced control techniques. It is normally expected that practical results should be included, but where simulation only studies are available, it is necessary to demonstrate that the simulation model is representative of a genuine application. Strictly theoretical papers will find a more appropriate home in Control Engineering Practice''s sister publication, Automatica. It is also expected that papers are innovative with respect to the state of the art and are sufficiently detailed for a reader to be able to duplicate the main results of the paper (supplementary material, including datasets, tables, code and any relevant interactive material can be made available and downloaded from the website). The benefits of the presented methods must be made very clear and the new techniques must be compared and contrasted with results obtained using existing methods. Moreover, a thorough analysis of failures that may happen in the design process and implementation can also be part of the paper. The scope of Control Engineering Practice matches the activities of IFAC. Papers demonstrating the contribution of automation and control in improving the performance, quality, productivity, sustainability, resource and energy efficiency, and the manageability of systems and processes for the benefit of mankind and are relevant to industrial practitioners are most welcome.