Add to ORKGDesign of a control law for simultaneously suppressing the symmetric and antisymmetric flutter modes of a string mounted fixed-in-roll aeroelastic wind tunnel model is described. The flutter suppression control law was designed using linear quadratic Gaussian theory and involved control law order reduction, a gain root-locus study, and the use of previous experimental results. A 23 percent increase in open-loop flutter dynamic pressure was demonstrated during the wind tunnel test. Rapid roll maneuvers at 11 percent above the symmetric flutter boundary were also performed when the model was in a free-to-roll configuration
This paper describes the development of a new state-of-the-art large wind tunnel model for active fl...
The design of the flutter suppression system for a remotely-piloted research vehicle is described. T...
Nominal roll control laws were designed, implemented, and tested on an aeroelastically-scaled free-t...
Active flutter suppression control laws were designed, implemented, and tested on an aeroelastically...
The process is described of analysis, design, digital implementation, and subsonic testing of an act...
The synthesis and experimental validation of a control law for13; an actiqe flutter suppression syst...
The synthesis, implementation, and wind tunnel test of two flutter suppression control laws for an a...
Flutter suppression (FS) is one of the active control concepts being investigated by the AFW program...
Three control law design techniques for flutter suppression are presented. Each technique uses multi...
Two flutter suppression control laws were synthesized, implemented, and tested on a low speed aeroel...
Three flutter suppression control law design techniques are presented. Each uses multiple control su...
The Active Flexible Wing Project is a collaborative effort between the NASA Langley Research Center ...
The synthesis and experimental validation of an active flutter suppression controller for the Active...
The benchmark active controls technology and wind tunnel test program at NASA Langley Research Cente...
Two flutter suppression control laws wre designed and tested on a low speed aeroelastic model of a D...
This paper describes the development of a new state-of-the-art large wind tunnel model for active fl...
The design of the flutter suppression system for a remotely-piloted research vehicle is described. T...
Nominal roll control laws were designed, implemented, and tested on an aeroelastically-scaled free-t...
Active flutter suppression control laws were designed, implemented, and tested on an aeroelastically...
The process is described of analysis, design, digital implementation, and subsonic testing of an act...
The synthesis and experimental validation of a control law for13; an actiqe flutter suppression syst...
The synthesis, implementation, and wind tunnel test of two flutter suppression control laws for an a...
Flutter suppression (FS) is one of the active control concepts being investigated by the AFW program...
Three control law design techniques for flutter suppression are presented. Each technique uses multi...
Two flutter suppression control laws were synthesized, implemented, and tested on a low speed aeroel...
Three flutter suppression control law design techniques are presented. Each uses multiple control su...
The Active Flexible Wing Project is a collaborative effort between the NASA Langley Research Center ...
The synthesis and experimental validation of an active flutter suppression controller for the Active...
The benchmark active controls technology and wind tunnel test program at NASA Langley Research Cente...
Two flutter suppression control laws wre designed and tested on a low speed aeroelastic model of a D...
This paper describes the development of a new state-of-the-art large wind tunnel model for active fl...
The design of the flutter suppression system for a remotely-piloted research vehicle is described. T...
Nominal roll control laws were designed, implemented, and tested on an aeroelastically-scaled free-t...