Three types of aeroelastic reduced-order models (ROMs) for flutter and gust-response analyses are examined, one of which is introduced here. One is based on the finite-state description of unsteady aerodynamics obtained through a rational-matrix approximation of the frequency-domain transcendental aerodynamic operator. Coupling this with the equations of the structural dynamics yields the aeroelastic ROM. The drawback of this approach is that some aerodynamic states have to be added to the structural states in the state-space format description of the aeroelastic system. The second model that is discussed yields directly the finite-state description of the aeroelastic operator without altering the dimensions of the state space. This model is iterative in nature, in that it requires an estimate of aeroelastic eigenvalues and eigenvectors from the original eigenproblem. Finally, an alternate ROM formulation for the gust-response problem is proposed. It combines good level of accuracy with reduction of additional aerodynamic states and thus can be conveniently used in preliminary design process and control-law synthesis.
A study of Reduced-Order Models for Gust-Response Analysis of Flexible Wings / Gennaretti, M.; Mastroddi, Franco. - In: JOURNAL OF AIRCRAFT. - ISSN 0021-8669. - STAMPA. - 41:2(2004), pp. 304-313. [10.2514/1.9325]
A study of Reduced-Order Models for Gust-Response Analysis of Flexible Wings
MASTRODDI, Franco
2004
Abstract
Three types of aeroelastic reduced-order models (ROMs) for flutter and gust-response analyses are examined, one of which is introduced here. One is based on the finite-state description of unsteady aerodynamics obtained through a rational-matrix approximation of the frequency-domain transcendental aerodynamic operator. Coupling this with the equations of the structural dynamics yields the aeroelastic ROM. The drawback of this approach is that some aerodynamic states have to be added to the structural states in the state-space format description of the aeroelastic system. The second model that is discussed yields directly the finite-state description of the aeroelastic operator without altering the dimensions of the state space. This model is iterative in nature, in that it requires an estimate of aeroelastic eigenvalues and eigenvectors from the original eigenproblem. Finally, an alternate ROM formulation for the gust-response problem is proposed. It combines good level of accuracy with reduction of additional aerodynamic states and thus can be conveniently used in preliminary design process and control-law synthesis.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.