Advances in the control of mechatronic suspension systems

Wajdi S. Aboud, S. M. Haris, Yuzita Yaacob
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引用次数: 21

Abstract

The suspension system is a key element in motor vehicles. Advancements in electronics and microprocessor technology have led to the realization of mechatronic suspensions. Since its introduction in some production motorcars in the 1980s, it has remained an area which sees active research and development, and this will likely continue for many years to come. With the aim of identifying current trends and future focus areas, this paper presents a review on the state-of-the-art of mechatronic suspensions. First, some commonly used classifications of mechatronic suspensions are presented. This is followed by a discussion on some of the actuating mechanisms used to provide control action. A survey is then reported on the many types of control approaches, including look-ahead preview, predictive, fuzzy logic, proportional-integral-derivative (PID), optimal, robust, adaptive, robust adaptive, and switching control. In conclusion, hydraulic actuators are most commonly used, but they impose high power requirements, limiting practical realizations of active suspensions. Electromagnetic actuators are seen to hold the promise of lower power requirements, and rigorous research and development should be conducted to make them commercially usable. Current focus on control methods that are robust to suspension parameter variations also seems to produce limited performance improvements, and future control approaches should be adaptive to the changeable driving conditions.
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机电悬架系统控制研究进展
悬架系统是机动车辆的关键部件。电子技术和微处理器技术的进步使机电悬架得以实现。自20世纪80年代在一些生产汽车中引入以来,它一直是一个积极研究和发展的领域,这可能会持续许多年。为了确定当前的趋势和未来的重点领域,本文介绍了机电悬架的最新进展。首先,介绍了机电悬架的几种常用分类。接下来将讨论一些用于提供控制动作的致动机构。然后调查报告了许多类型的控制方法,包括前瞻性预览,预测,模糊逻辑,比例积分导数(PID),最优,鲁棒,自适应,鲁棒自适应和切换控制。总之,液压执行器是最常用的,但它们对功率要求很高,限制了主动悬架的实际实现。电磁执行器被认为具有较低功耗要求的前景,应该进行严格的研究和开发,使其在商业上可用。目前对悬架参数变化的鲁棒控制方法的关注似乎也产生了有限的性能改进,未来的控制方法应该适应不断变化的驾驶条件。
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