论文信息 - Stochastic optimal control of flexible aircraft taxiing at constant or variable velocity

Stochastic optimal control of flexible aircraft taxiing at constant or variable velocity

Active control landing gears are used to alleviate vibration during aircraft taxiing. A nonlinear stochastic dynamics model is established, considering the aircraft body pitch movement and elastic vibration excited by the random runway. The equivalent linearization method is adopted to ensure the model linearity near the balance point, and the Gaussian random process of the runway is generated from the Gaussian white noise using a shape filter. Based on the stochastic optimal control theory, the LQG controller is designed along with weighted quadratic performance index for a better ride comfort, shock absorption, road holding and least energy expenditure. The algebraic Riccati and Lyapunov equations are solved to obtain stationary response while taxiing aircraft at a constant velocity and the differential Riccati and Lyapunov equations are solved to obtain the nonstationary response while taxiing aircraft at a variable velocity. The aircraft dynamic responses are obtained through the runway random process modeled by Monte Carlo method. Simulation results show that active control landing gear can give a better ride comfort, shock absorption and road holding performance no matter whether taxiing is at constant or variable velocity.

Nie Hong | Zhang Ming | Zhu Rupeng

[1] J. Dormand,et al. A family of embedded Runge-Kutta formulae , 1980 .

[2] Jia Yu. TAXIING PERFORMANCE ANALYSIS OF ACTIVE CONTROL OF LANDING GEAR , 1999 .

[3] J. R. Mcgehee,et al. Improved aircraft dynamic response and fatigue life during ground operations using an active control landing gear system , 1978 .

[4] A. Laub,et al. Generalized eigenproblem algorithms and software for algebraic Riccati equations , 1984, Proceedings of the IEEE.

[5] Richard H. Bartels,et al. Algorithm 432 [C2]: Solution of the matrix equation AX + XB = C [F4] , 1972, Commun. ACM.

[6] S. Senthil,et al. STOCHASTIC OPTIMAL ACTIVE CONTROL OF A 2-DOF QUARTER CAR MODEL WITH NON-LINEAR PASSIVE SUSPENSION ELEMENTS , 1998 .

[7] Aleksander Hać. Stochastic Optimal Control of Vehicles With Elastic Body and Active Suspension , 1986 .

[8] Lucas G. Horta,et al. Modeling and Validation of a Navy A6-Intruder Actively Controlled Landing Gear System , 1999 .

[9] James N. Daniels,et al. A method for landing gear modeling and simulation with experimental validation , 1996 .

[10] C. S. Lu. Solution of the matrix equation AX+XB = C , 1971 .

[11] I. Ross. An electronic control for an electrohydraulic active control landing gear for the F-4 aircraft , 1982 .

[12] P. Spanos,et al. Random vibration and statistical linearization , 1990 .

[13] Liu Ying,et al. Improvement of taxing performance for civil airliner by active control , 2003 .