期刊文献+
共找到5篇文章
< 1 >
每页显示 20 50 100
小型无人直升机控制及稳定性分析
1
作者 樊世伟 薛东彬 《现代电子技术》 2014年第13期36-38,42,共4页
本文介绍了线性和非线性控制法则两种控制律设计方法在小型直升机上的应用,采用双时域衡量分析方法来分析直升机系统动力学特性。紧子系统和慢子系统分别用于分析直升机转动和平动动力学特性,紧子系统的稳定性是由李亚普诺夫方程保证,... 本文介绍了线性和非线性控制法则两种控制律设计方法在小型直升机上的应用,采用双时域衡量分析方法来分析直升机系统动力学特性。紧子系统和慢子系统分别用于分析直升机转动和平动动力学特性,紧子系统的稳定性是由李亚普诺夫方程保证,同时采用反馈线性化方法稳定控制内回路。此外,在给出线性控制律缺点的同时给出了改进后的非线性控制律,该控制律可以在无人直升机执行大角度、快速度飞行运动科目时更稳定可靠的控制直升机。 展开更多
关键词 无人直升机控制 稳定性分析 双时域衡量分析 李亚普诺夫稳定性 反馈线性化 非线性控制
下载PDF
小型无人直升机控制及稳定性分析
2
作者 樊世伟 薛东彬 《电光系统》 2014年第1期32-35,共4页
文章介绍了线性和非线性控制法则两种控制律设计方法在小型直升机上的应用,采用双时域衡量分析方法来分析直升机系统动力学特性。紧子系统和慢子系统分别用于分析直升机转动和平动动力学特性,紧子系统的稳定性是由李亚普诺夫方程保证... 文章介绍了线性和非线性控制法则两种控制律设计方法在小型直升机上的应用,采用双时域衡量分析方法来分析直升机系统动力学特性。紧子系统和慢子系统分别用于分析直升机转动和平动动力学特性,紧子系统的稳定性是由李亚普诺夫方程保证,同时采用反馈线性化方法稳定控制内回路。此外,在给出线性控制律缺点的同时给出了改进后的非线性控制律,该控制律可以在无人直升机执行大角度、快速度飞行运动科目时更稳定可靠的控制直升机。 展开更多
关键词 无人直升机控制 稳定性分析 双时域衡量分析 李亚普诺夫稳定性 反馈线性化 非线性控制
下载PDF
一种小型无人直升机航模的结构设计
3
作者 钱海燕 《科技风》 2017年第22期1-1,共1页
设计了一种低成本、具备一定自主飞行能力的无人直升机飞行控制系统,针对主要模块进行功能设计,使该控制系统的运行效率最大化。
关键词 自动控制无人直升机传感器
下载PDF
Robust Anti⁃swing Control for Unmanned Helicopter Slung⁃Load System with Prescribed Performance
4
作者 SHAO Shuyi LIU Nan +1 位作者 LI Chunru CHEN Mou 《Transactions of Nanjing University of Aeronautics and Astronautics》 EI CSCD 2021年第2期193-205,共13页
A robust anti-swing control method based on the error transformation function is proposed,and the problem is handled for the unmanned helicopter slung-load system(HSLS)deviating from the equilibrium state due to the d... A robust anti-swing control method based on the error transformation function is proposed,and the problem is handled for the unmanned helicopter slung-load system(HSLS)deviating from the equilibrium state due to the disturbances in the lifting process.First,the nonlinear model of unmanned HSLS is established.Second,the errors of swing angles are constructed by using the two ideal swing angle values and the actual swing angle values for the unmanned HSLS under flat flight,and the error transformation functions are investigated to guarantee that the errors of swing angles satisfy the prescribed performance.Third,the nonlinear disturbance observers are introduced to estimate the bounded disturbances,and the robust controllers of the unmanned HSLS,the velocity and the attitude subsystems are designed based on the prescribed performance method,the output of disturbance observer and the sliding mode backstepping strategy,respectively.Fourth,the Lyapunov function is developed to prove the stability of the closed-loop system.Finally,the simulation studies are shown to demonstrate the effectiveness of the control strategy. 展开更多
关键词 unmanned helicopter slung-load system prescribed performance anti-swing control disturbance observer sliding mode controller
下载PDF
Research on the Unmanned Aerial Vehicle Adaptive Control System based on Fuzzy Control and Chaos Mechanics
5
作者 Jianqiong Xu 《International Journal of Technology Management》 2016年第8期52-54,共3页
In this paper, we conduct research on the unmanned aerial vehicle adaptive control system based on fuzzy control and chaosmechanics. Four rotor aircraft is a kind of nonlinear systems with underactuated, strong coupli... In this paper, we conduct research on the unmanned aerial vehicle adaptive control system based on fuzzy control and chaosmechanics. Four rotor aircraft is a kind of nonlinear systems with underactuated, strong coupling characteristic. Although in existing research,through the design of the control algorithm effectively inhibits both for fl ight control effect, but not fundamentally eliminate the effect of aircraft.Dynamic model of unmanned helicopter fl ight control system design is very approximate, need to gradually improve the modeling accuracy, soas to get the exact autonomous fl ight control, so you need to practice constantly required to modeling in the fl ight information, so the unmannedhelicopter fl ight control system to have the ability to retrieve information modeling. This paper proposes the new idea on the issues that will bemeaningful. 展开更多
关键词 Unmanned Aerial Vehicle Adaptive Control SYSTEM Fuzzy Control Chaos Mechanics.
下载PDF
上一页 1 下一页 到第
使用帮助 返回顶部