Sliding mode control-based limit cycle oscillation suppression for UAVs using synthetic jet actuators

2015 International Workshop on Recent Advances in Sliding Modes (RASM) Pub Date : 2015-04-09 DOI:10.1109/RASM.2015.7154584

N. Ramos-Pedroza, W. MacKunis, M. Reyhanoglu

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引用次数: 3

Abstract

A sliding mode control (SMC) method is presented in this paper, which is proven to achieve asymptotic SJA-based LCO suppression without the use of adaptive laws or function approximators. In addition, the SMC-based control strategy presented here is shown to achieve suppression of both pitching and plunging displacements for a class of so-called dual-parallel underactuated systems, where a single scalar control signal simultaneously affects both states. The dual-parallel underactuated system cannot be expressed in a cascade or normal form, and hence, standard backstepping-based control approaches cannot be applied. In this paper, this difficulty is mitigated through novel algebraic manipulation in the error system development, along with innovative design of the sliding surface. A detailed model of the UAV dynamics is utilized along with a rigorous analysis to prove asymptotic regulation of the plunging displacement, and numerical simulation results are provided to demonstrate asymptotic suppression of the pitching and plunging displacements.

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基于滑模控制的合成射流作动器无人机极限环振荡抑制

本文提出了一种滑模控制(SMC)方法，证明了该方法在不使用自适应律或函数逼近器的情况下，可以实现基于s_的渐近LCO抑制。此外，本文提出的基于smc的控制策略可以实现对一类所谓的双并联欠驱动系统的俯仰和俯冲位移的抑制，其中单个标量控制信号同时影响两种状态。双并联欠驱动系统不能用级联或范式表示，因此，标准的基于后退的控制方法不能应用。在本文中，通过在误差系统开发中的新颖代数处理，以及滑动面的创新设计，减轻了这一困难。利用详细的无人机动力学模型和严格的分析，证明了俯仰位移和俯仰位移的渐近抑制，并提供了数值模拟结果。

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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2015 International Workshop on Recent Advances in Sliding Modes (RASM)

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