Integrated Flight/Structural Mode Control for Very Flexible Aircraft Using L1 Adaptive Output Feedback Controller

This paper explores application of adaptive control architecture to a light, high-aspect ratio, flexible aircraft configuration that exhibits strong rigid body/flexible mode coupling. Specifically, an L(sub 1) adaptive output feedback controller is developed for a semi-span wind tunnel model capable of motion. The wind tunnel mount allows the semi-span model to translate vertically and pitch at the wing root, resulting in better simulation of an aircraft s rigid body motion. The control objective is to design a pitch control with altitude hold while suppressing body freedom flutter. The controller is an output feedback nominal controller (LQG) augmented by an L(sub 1) adaptive loop. A modification to the L(sub 1) output feedback is proposed to make it more suitable for flexible structures. The new control law relaxes the required bounds on the unmatched uncertainty and allows dependence on the state as well as time, i.e. a more general unmatched nonlinearity. The paper presents controller development and simulated performance responses. Simulation is conducted by using full state flexible wing models derived from test data at 10 different dynamic pressure conditions. An L(sub 1) adaptive output feedback controller is designed for a single test point and is then applied to all the test cases. The simulation results show that the L(sub 1) augmented controller can stabilize and meet the performance requirements for all 10 test conditions ranging from 30 psf to 130 psf dynamic pressure.

[1]  Richard A. Wahls,et al.  NASA's Fundamental Aeronautics Subsonic Fixed Wing Project: Generation N+3 Technology Portfolio , 2011 .

[2]  L. Valavani Review of "L1 Adaptive Control Theory: Guaranteed Robustness with Fast Adaptation" , 2011 .

[3]  Naira Hovakimyan,et al.  L1 Adaptive Control Theory - Guaranteed Robustness with Fast Adaptation , 2010, Advances in design and control.

[4]  Naira Hovakimyan,et al.  Comparison of Several Adaptive Controllers According to Their Robustness Metrics , 2010 .

[5]  Irene M. Gregory,et al.  Flight Test of an L(sub 1) Adaptive Controller on the NASA AirSTAR Flight Test Vehicle , 2010 .

[6]  Chengyu Cao,et al.  Stability Margins of ${\cal L}_{1}$ Adaptive Control Architecture , 2010, IEEE Transactions on Automatic Control.

[7]  Naira Hovakimyan,et al.  L1 Adaptive Output-Feedback Controller for Non-Strictly-Positive-Real Reference Systems: Missile Longitudinal Autopilot Design , 2009 .

[8]  Chengyu Cao,et al.  L1 adaptive controller for a class of systems with unknown nonlinearities: Part I , 2008, 2008 American Control Conference.

[9]  Chengyu Cao,et al.  L1 adaptive controller for nonlinear systems in the presence of unmodelled dynamics: Part II , 2008, 2008 American Control Conference.

[10]  Naira Hovakimyan,et al.  adaptive controller for systems with unknown time-varying parameters and disturbances in the presence of non-zero trajectory initialization error , 2008, Int. J. Control.

[11]  Chengyu Cao,et al.  Stability Margins of L1 Adaptive Controller: Part II , 2007, 2007 American Control Conference.

[12]  N. Hovakimyan,et al.  Design and Analysis of a Novel ${\cal L}_1$ Adaptive Control Architecture With Guaranteed Transient Performance , 2006, IEEE Transactions on Automatic Control.

[13]  Irene M. Gregory,et al.  Adaptive control laws for flexible semi-span wind tunnel model of high-aspect ratio flying wing , 2007 .