制导弹药折叠翼系统:LQR、LQI、SMC和SOSMC的机构设计、制造和实时结果分析

A. Sayıl, F. Erden, A. Tüzün, B. Baykara, M. Aydemir
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引用次数: 0

摘要

本文研究了一种可折叠机翼系统(FWS),使制导弹药在滑翔和俯冲两阶段均可调整后掠角。与之前的设计不同,FWS没有任何固定机构或制动元件,它提供折叠功能,以减少终端阶段的阻力。我们进行了机构设计,制造了FWS,进行了系统辨识,并设计了各种控制器,包括线性二次调节器(LQR),线性二次积分器(LQI),滑模控制(SMC)和二阶滑模控制(SOSMC),以调整和保持所需的后掠角。然后,在有气动载荷和无气动载荷两种不同的飞行场景下,对FWS的性能进行了实验测试。在没有气动载荷的情况下,所有控制器的稳态误差(SSE)几乎为零,而考虑到SSE、延迟、抖振和能耗,SOSMC是气动载荷下最有效的控制器。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A folding wing system for guided ammunitions: mechanism design, manufacturing and real-time results with LQR, LQI, SMC and SOSMC
In the present work, a folding wing system (FWS) was developed for guided ammunitions, so that the swept-back angle could be adjusted during both gliding and diving phases. Unlike previous designs, the FWS does not have any fixing mechanisms or brake elements, and it provides folding functionality to reduce the drag force during the terminal phase. We conducted mechanism design, manufactured the FWS, performed system identification and designed various controllers including linear quadratic regulator (LQR), linear quadratic integrator (LQI), sliding mode control (SMC) and second-order sliding mode control (SOSMC) to adjust and hold the desired swept-back angles. Then, the performance of the FWS was tested experimentally under two different flight scenarios, with and without aerodynamic loads. While all controllers operated with almost zero steady-state error (SSE) in the absence of aerodynamic loads, the SOSMC was the most effective controller under aerodynamic loads, considering SSE, delay, chattering, and energy consumption.
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