Modeling and Multivariable Control of an Earthmoving Vehicle Powertrain

Proceedings of the ASME Dynamic Systems and Control Conference. ASME Dynamic Systems and Control Conference Pub Date : 2001-11-11 DOI:10.1115/imece2001/dsc-24564

Rong Zhang, Eko Prasetiawan, A. Alleyne

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引用次数: 2

Abstract

Coordination of the power distribution in a Multi-Input Multi-Output (MIMO) electrohydraulic transmission is investigated for the case of an earthmoving vehicle powertrain. A generalized model of a representative system is presented along with the development of both H2 and H∞ MIMO controller designs. The controllers are developed based on a linearized model of the system about some nominal operating point Multiple inputs are coordinated to control multiple load outputs simultaneously. Since typical MIMO electrohydraulic transmission systems have significant nonlinear dynamics that vary with system operating conditions, a robust controller design is paramount The increased robustness of the H∞ controller over the H2 scheme is demonstrated qualitatively in the time domain through both disturbance rejection and trajectory tracking comparisons. A frequency domain criterion quantitatively provides quantifiable comparisons between the two methods. Hardware-in-the-Loop experiments validate the modeling and control performance on an Earthmoving Vehicle Powertrain Simulator (EVPS).

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土方车辆动力系统建模与多变量控制

以土方车辆动力系统为例，研究了多输入多输出(MIMO)电液传动系统的功率分配协调问题。随着H2和H∞MIMO控制器设计的发展，提出了代表性系统的广义模型。该控制器是基于系统关于某个标称工作点的线性化模型开发的，多个输入协调以同时控制多个负载输出。由于典型的MIMO电液传动系统具有随系统运行条件而变化的显著非线性动力学，因此鲁棒控制器设计至关重要。通过干扰抑制和轨迹跟踪比较，在时域定性地证明了H∞控制器在H2方案上的鲁棒性增加。频域判据定量地提供了两种方法之间的可量化比较。硬件在环实验验证了在土方车辆动力系统模拟器(EVPS)上的建模和控制性能。

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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Proceedings of the ASME Dynamic Systems and Control Conference. ASME Dynamic Systems and Control Conference

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