Limit cycle oscillations (LCOs) affect current fighter aircraft and are expected to be present on next generation fighter aircraft. Current efforts in control systems designed to suppress LCO behavior have either used a linear model, restricting the flight regime, require exact knowledge of the system dynamics, or require uncertainties in the system dynamics to be linear-in-the-parameters and only present in the torsional stiffness. Furthermore, the aerodynamic model used in prior research efforts neglects nonlinear effects. This paper presents the development of a controller consisting of a continuous robust integral of the sign of the error (RISE) feedback term with a neural network (NN) feedforward term to achieve asymptotic tracking of uncertainties that do not satisfy the linear-in-the-parameters assumption. Simulation results are presented to validate the performance of the developed controller.
Issue Section:
Technical Brief
References
1.
Beran
, P. S.
, Strganac
, T. W.
, Kim
, K.
, and Nichkawde
, C.
, 2004
, “Studies of Store-Induced Limit Cycle Oscillations Using a Model With Full System Nonlinearities
,” Nonlinear Dyn.
, 37
(4), pp. 323
–339
.10.1023/B:NODY.0000045544.96418.bf2.
Bunton
, R. W.
, and Denegri
, Jr., C. M.
, 2000
, “Limit Cycle Oscillation Characteristics of Fighter Aircraft
,” J. Aircraft
, 37
(5), pp. 916
–918
.10.2514/2.26903.
Block
, J. J.
, and Strganac
, T. W.
, 1999
, “Applied Active Control for a Nonlinear Aeroelastic Structure
,” AIAA J. Guid. Contr. Dynam.
, 21
(6), pp. 838
–845
.10.2514/2.43464.
Ko
, J.
, Strganac
, T. W.
, and Kurdila
, A.
, 1998
, “Stability and Control of a Structurally Nonlinear Aeroelastic System
,” AIAA J. Guid. Contr. Dynam.
, 21
(5), pp. 718
–725
.10.2514/2.43175.
Zhang
, W.
, and Ye
, Z.
, 2007
, “Control Law Design for Transonic Aeroservoelasticity
,” Aerospace Sci. Technol.
, 11
(2–3), pp. 136
–145
.10.1016/j.ast.2006.12.0046.
Danowsky
, B. P.
, Thompson
, P. M.
, Farhat
, C.
, Lieu
, T.
, Harris
, C.
, and Lechniak
, J.
, 2010
, “Incorporation of Feedback Control Into a High-Fidelity Aeroservoelastic Fighter Aircraft Model
,” J. Aircraft
, 47
(4), pp. 1274
–1282
.10.2514/1.471197.
Thompson
, P. M.
, Danowsky
, B. P.
, Farhat
, C.
, Lieu
, T.
, Lechniak
, J.
, and Harris
, C.
, 2011
, “High-Fidelity Aeroservoelastic Predictive Analysis Capability Incorporating Rigid Body Dynamics
,” AIAA
Paper No. 2011-6209.10.2514/6.2011-62098.
Cavagna
, L.
, Ricci
, S.
, and Scotti
, A.
, 2009
, “Active Aeroelastic Control Over a Four Control Surface Wing Model
,” Aerospace Sci. Technol.
, 13
(7), pp. 374
–382
.10.1016/j.ast.2009.06.0099.
Prime
, Z.
, Cazzolato
, B.
, Doolan
, C.
, and Strganac
, T.
, 2010
, “Linear-Parameter-Varying Control of an Improved Three-Degree-of-Freedom Aeroelastic Model
,” AIAA J. Guid. Contr. Dynam.
, 33
(2), pp. 615
–618
.10.2514/1.4565710.
Elhami
, M. R.
, and Narab
, M. F.
, 2012
, “Comparison of SDRE and SMC Control Approaches for Flutter Suppression in a Nonlinear Wing Section
,” Proceedings of American Control Conference
, Montreal, QC, Canada, pp. 6148
–6153
.11.
Ko
, J.
, Strganac
, T. W.
, and Kurdila
, A.
, 1999
, “Adaptive Feedback Linearization for the Control of a Typical Wing Section With Structural Nonlinearity
,” Nonlinear Dyn.
, 18
(3), pp. 289
–301
.10.1023/A:100832362906412.
Strganac
, T. W.
, Ko
, J.
, Thompson
, D. E.
, and Kurdila
, A.
, 2000
, “Identification and Control of Limit Cycle Oscillations in Aeroelastic Systems
,” AIAA J. Guid. Contr. Dynam.
, 23
(6), pp. 1127
–1133
.10.2514/2.466413.
Ko
, J.
, Strganac
, T. W.
, Junkins
, J. L.
, Akella
, M. R.
, and Kurdila
, A.
, 2002
, “Structured Model Reference Adaptive Control for a Wing Section With Structural Nonlinearity
,” J. Vib. Control
, 8
(5), pp. 553
–573
.10.1177/10775460202371014.
Platanitis
, G.
, and Strganac
, T. W.
, 2004
, “Control of a Nonlinear Wing Section Using Leading- and Trailing-Edge Surfaces
,” AIAA J. Guid. Contr. Dynam.
, 27
(1), pp. 52
–58
.10.2514/1.928415.
Bialy
, B. J.
, Pasiliao
, C. L.
, Dinh
, H. T.
, and Dixon
, W. E.
, 2012
, “Lyapunov-Based Tracking of Store-Induced Limit Cycle Oscillations in an Aeroelastic System
,” ASME
Paper No. DSCC2012-MOVIC2012-8662.10.1115/DSCC2012-MOVIC2012-866216.
Patre
, P. M.
, MacKunis
, W.
, Kaiser
, K.
, and Dixon
, W. E.
, 2008
, “Asymptotic Tracking for Uncertain Dynamic Systems Via a Multilayer Neural Network Feedforward and RISE Feedback Control Structure
,” IEEE Trans. Automat. Control
, 53
(9
), pp. 2180
–2185
.10.1109/TAC.2008.93020017.
Patre
, P.
, Mackunis
, W.
, Dupree
, K.
, and Dixon
, W. E.
, 2011
, “Modular Adaptive Control of Uncertain Euler-Lagrange Systems With Additive Disturbances
,” IEEE
Trans. Automat. Control, 56
(1
), pp. 155
–160
.10.1109/TAC.2010.208177018.
MacKunis
, W.
, Patre
, P.
, Kaiser
, M.
, and Dixon
, W. E.
, 2010
, “Asymptotic Tracking for Aircraft Via Robust and Adaptive Dynamic Inversion Methods
,” IEEE Trans. Control Syst. Technol.
, 18
(6
), pp. 1448
–1456
.10.1109/TCST.2009.203957219.
Bialy
, B.
, Andrews
, L.
, Curtis
, J. W.
, and Dixon
, W. E.
, 2014, “Saturated Tracking Control of Store-Induced Limit Cycle Oscillations
,” AIAA
J. Guid. Control Dyn. 37
(4), pp. 1316–1323.10.2514/1.G00032520.
Thompson
, Jr., D. E.
, and Strganac
, T. W.
, 2005
, “Nonlinear Analysis of Store-Induced Limit Cycle Oscillations
,” Nonlinear Dyn.
, 39
(1–2), pp. 159
–178
.10.1007/s11071-005-1924-y21.
Krstic
, M.
, Kokotovic
, P. V.
, and Kanellakopoulos
, I.
, 1995
, Nonlinear and Adaptive Control Design
, John Wiley & Sons
, New York.Copyright © 2014 by ASME
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