作　　者： ; ; ; ; ;

机构地区： 空军工程大学航空航天工程学院

出　　处： 《推进技术》 2013年第6期836-842,共7页

摘　　要： 为减小不确定性对航空发动机分布式控制系统性能的影响,针对具有参数摄动、不确定时延、执行机构动态故障、外部噪声干扰四种不确定性的航空发动机分布式控制系统,提出了一种基于鲁棒H∞理论的容错控制方法。首先对系统不确定性进行数学描述,将不确定时延视为服从齐次Markov链分布的随机变量,将执行机构故障等效为存在均值和方差约束的随机变量,并在此基础上建立整个闭环系统的增广模型;其次证明了该增广模型保持均方渐进稳定且具备H∞性能的充分条件;最后利用线性矩阵不等式(LMI)理论给出闭环系统鲁棒H∞容错控制器的设计方法。仿真结果表明该方法能够保证控制系统均方渐进稳定,并对以上四种不确定因素具有鲁棒性,同时对于飞行包线其他各点具有较好的动态响应。 To reduce the effects of uncertainty on aero-engine distributed control system （DCS） , a ro- bust H fault-tolerant controller was proposed for uncertain aero-engine DCS with parameter perturbation, uncertain time-delay, external disturbance and dynamic fault of actuators. Assume that the time-delays o- beyed a homogenous Markov distribution. The actuator fault was regarded as random parameter with mean and variance constraints. Based on the assumption a closed-loop augmented model was established and a sufficient condition was derived for the augmented system. Under this condition the augmented system will be mean-square asymptotically stable and fulfill H disturbance restraint. Finally, the design approach of robust fault-tolerant controller was proposed by means of linear matrix inequality （LMI）. Simulation results show that the controller is robust to the above four uncertainties. The controller also ensures closed-loop system to be mean-square asymptotically stable. Besides, the controller has a favorable dynamic response at other flight conditions.

关 键 词： 航空发动机 分布式控制系统 不确定性 容错控制 马尔可夫时延

领　　域： [航空宇航科学与技术] [航空宇航科学技术]