二维码(扫一下试试看!) | | 动力翼伞系统耦合补偿控制策略研究 | | Control Strategy of Power Parafoil System Based on Coupling Compensation | | 投稿时间:2018-07-08 | | DOI:10.15918/j.tbit1001-0645.2019.04.008 | | 中文关键词:强耦合动力翼伞系统扩张状态观测器耦合补偿横向轨迹跟踪 | | English Keywords:strong couplingpowered parafoil systemextended state observercoupling compensationlateral trajectory tracking | | 基金项目:国家自然科学基金资助项目(61273138);天津市重点基金资助项目(14JCZDJC39300);天津市教委科研计划资助项目(2017KJ044);天津市自然科学基金资助项目(17JCYBJC16800) | | | 摘要点击次数:675 | | 全文下载次数:283 | | 中文摘要: | | 动力翼伞系统是具有强非线性、强耦合特性的系统,其精确控制比较困难.动力翼伞系统具有两个控制通道,控制的难度在于纵向推力对下偏控制存在着非线性的强耦合作用,在受到风场干扰时会导致系统耦合加剧,从而在控制过程中引起较大偏差,甚至导致系统失速.本文提出了一种基于耦合补偿的自抗扰控制策略,并将该非线性耦合关系设计为扩张状态观测器中的已知扰动,从而提高了控制器的跟踪性能.在动态耦合补偿的基础上改进控制律,将非线性动力翼伞系统设计成易于控制的独立积分器,从而提高横向轨迹跟踪控制器的抗干扰性和控制跟踪性能.通过仿真实验可验证该控制策略优于传统的自抗扰控制(active disturbances rejection controller,ADRC)和PID控制. | | English Summary: | | Powered parafoil system is strongly nonlinear and contains complicated cross-coupling characteristic, which makes the system hard to control. Under the variable wind disturbance, this coupling influence will aggravate the control performance, probably resulting in large deviations or instability in the control process. An active disturbance rejection control (ADRC) strategy based on the coupling compensation was proposed. The dynamic cross-coupling relation of the longitudinal thrust on the lateral yaw control was designed as the known disturbance of extended state observer (ESO) to be compensated in the improved control law, so that the tracking ability of the controller could be enhanced. Moreover, under the cross-coupling compensation, a complex nonlinear powered parafoil system was constructed as integrators which could be easily controlled, such that the tracking precision and disturbance rejection capacity of the lateral controller were improved. Eventually, mathematical simulations demonstrate that the proposed control approach has better tracking performance and robustness compared with the conventional ADRC and PID. | | 查看全文查看/发表评论下载PDF阅读器 | |
江维,王杰,陈伟,余联庆,李红军,吴功平.半结构环境中电力作业机器人机械手鲁棒轨迹跟踪控制[J].北京理工大学学报(自然科学版),2019,39(4):391~398.JIANGWei,WANGJie,CHENWei,YULian-qing,LIHong-jun,WUGong-ping.Manipu ... 北京理工大学科研学术 本站小编 Free考研考试 2021-12-21上官文斌,梁土强,蒋开洪,唐文.集成式电液制动系统建模与压力控制方法研究[J].北京理工大学学报(自然科学版),2019,39(4):413~418.SHANGGUANWen-bin,LIANGTu-qiang,JIANGKai-hong,TANGWen.ModelingandPressureCon ... 北京理工大学科研学术 本站小编 Free考研考试 2021-12-21王延忠,赵维强,初晓孟,刘旸,苏国营.面齿轮车桥总成构型设计与动力学分析[J].北京理工大学学报(自然科学版),2019,39(5):486~490,496.WANGYan-zhong,ZHAOWei-qiang,CHUXiao-meng,LIUYang,SUGuo-ying.Configurati ... 北京理工大学科研学术 本站小编 Free考研考试 2021-12-21黄万友,王广灿,于明进,李彦桦,张吉诚.基于田口鲁棒优化的电动汽车驱动控制策略研究[J].北京理工大学学报(自然科学版),2019,39(5):497~501.HUANGWan-you,WANGGuang-can,YUMing-jin,LIYan-hua,ZHANGJi-cheng.Research ... 北京理工大学科研学术 本站小编 Free考研考试 2021-12-21江维,周志远,陈伟,余联庆,李红军,吴功平.高压电缆移动作业机器人机械手双闭环自主定位控制[J].北京理工大学学报(自然科学版),2019,39(6):589~596.JIANGWei,ZHOUZhi-yuan,CHENWei,YULian-qing,LIHong-jun,WUGong-Ping.M ... 北京理工大学科研学术 本站小编 Free考研考试 2021-12-21李梁,李剑飞,张大伟,王宁飞.自由漂浮空间双臂机器人动目标抓捕控制[J].北京理工大学学报(自然科学版),2019,39(6):615~623.LILiang,LIJian-fei,ZHANGDa-wei,WANGNing-fei.ControlofFree-FloatingSpaceDual-Ar ... 北京理工大学科研学术 本站小编 Free考研考试 2021-12-21陈德海,华铭,邹争明,任永昌.优化分级T-S模糊控制动态估计纯电动汽车电池健康状态[J].北京理工大学学报(自然科学版),2019,39(6):609~614.CHENDe-hai,HUAMing,ZOUZheng-ming,RENYong-chang.DynamicPredictionofPure ... 北京理工大学科研学术 本站小编 Free考研考试 2021-12-21张惠瑾,杨艳玲,李星,刘永旺,赵锂.银离子-热力复合冲击消毒对生活热水管壁生物膜的控制作用[J].北京理工大学学报(自然科学版),2019,39(6):655~660.ZHANGHui-jin,YANGYan-ling,LIXing,LIUYong-wang,ZHAOLi.TheControlEff ... 北京理工大学科研学术 本站小编 Free考研考试 2021-12-21姚国伟,张凤,曹建文,邓志均.基于有向图的运载火箭综合电子系统设计方法[J].北京理工大学学报(自然科学版),2019,39(6):650~654.YAOGuo-wei,ZHANGFeng,CAOJian-wen,DENGZhi-jun.LaunchVehicleIntegratedElectron ... 北京理工大学科研学术 本站小编 Free考研考试 2021-12-21李国正,谭南林,苏树强,张驰.混沌同步系统降噪方法及其在滚动轴承故障诊断中的应用[J].北京理工大学学报(自然科学版),2019,39(7):669~675.LIGuo-zheng,TANNan-lin,SUShu-qiang,ZHANGChi.NoiseReductionMethodBasedon ... 北京理工大学科研学术 本站小编 Free考研考试 2021-12-21
| |
