Optimal Design for Notch Filter of Aeroservoelastic Systems

被引：0

作者：

Pu L.-D. ^{[1
]}

Luo W.-K. ^{[1
]}

Yan Z.-Z. ^{[1
]}

机构：

[1] Aeroelastic Department, The First Aircraft Institute of AVIC, Xi'an, 710089, Shanxi

来源：

Pu, Li-Dong (pld5000@163.com) | 2018年 / Tsinghua University卷 / 35期

关键词：

Aeroservoelasticity; Controllability and stability; Genetic algorithms; Notch filter; Optimal design;

D O I：

10.6052/j.issn.1000-4750.2016.12.0971

中图分类号：

学科分类号：

摘要：

The interaction between an aeroelastic system and a flight control system (FCS), namely aeroservoelasticity, may result in aircraft instability, and the corresponding frequencies are lower and vary with aircraft weight configurations significantly. The traditional approach, adopting notch filter for suppressing aeroservoelastic interaction, may have adverse effects on the aircraft controllability and stability. A notch filter optimal design methodology, based on a multi-objective genetic algorithm, is developed with the function of minimizing adverse effects on the rigid fight dynamics. The objective is to minimize the elastic modal frequency response peaks of aeroservoelastic systems subjected to the constraints of the frequency response characteristics of rigid aircraft flight dynamics. Firstly, a penalty function is developed to correct individual fitness functions, and then the frequency and damping parameters of notch filters are optimized. The optimized results indicate that the aeroservoelastic dynamic responses are suppressed while rigid aircraft flight dynamics performance degradation is minimized. Thusly, the proposed method can make full use of high-gain control systems to improve flight performance. © 2018, Engineering Mechanics Press. All right reserved.

引用

页码：235 / 241

页数：6

共 17 条

[1] Zou C., Chen G., A new branch of aeroelasticity-aeroservoelasticity, Journal of Beijing University of Aeronautics and Astronautics, 21, 2, pp. 22-27, (1995)
[2] Peter M.T., David H.K., Aeroservoelastic predictive analysis capability, pp. 1-11, (2007)
[3] Zhang Z., An G., Liu B., Investigation of aeroservoelastic dynamic characteristics of elastic flight-wings, Engineering Mechanics, 31, 11, pp. 231-236, (2014)
[4] Peter Y.C., Timothy J.H., Automated procedures for aircraft aeroservoelastic compensation, pp. 1347-1351, (1992)
[5] Animesh C., Girish D., Vijay V.P., Et al., Design of notch filters for structural responses with multi-axis coupling, Journal of Guidance, Control and Dynamics, 22, 2, pp. 349-357, (1999)
[6] Ruxandra B., Iulian C., Alexandre D., Et al., Method validation for aeroservoelastic analysis, pp. 1-11, (2002)
[7] Jason L., Petros A.I., Maj D.M., Adaptive mode suppression scheme for an aeroelastic airbreathing hypersonic cruise vehicle, pp. 1-12, (2008)
[8] Nam C., Chen P.C., Liu D.D., Et al., Adaptive reconfigurable control based on a reduced order system identification for flutter and aeroservoelastic instability suppression, pp. 1-13, (2001)
[9] Chu L., Wu Z., Yang C., Et al., Design and simulation of adaptive structure filter for missiles, Acta Aeronautica et Astronautica Sinica, 32, 2, pp. 195-201, (2011)
[10] Paul J.K., Douglas G.M., Adaptive spatial filtering for aeroservoelastic response suppression, pp. 1-12, (2009)

← 1 2 →