论文信息 - A linearized theory method of constrained optimization for supersonic cruise wing design

A linearized theory method of constrained optimization for supersonic cruise wing design

A linearized theory wing design and optimization procedure which allows physical realism and practical considerations to be imposed as constraints on the optimum (least drag due to lift) solution is discussed and examples of application are presented. In addition to the usual constraints on lift and pitching moment, constraints are imposed on wing surface ordinates and wing upper surface pressure levels and gradients. The design procedure also provides the capability of including directly in the optimization process the effects of other aircraft components such as a fuselage, canards, and nacelles.

H. W. Carlson | D. S. Miller | W. D. Middleton | H. Carlson | D. S. Miller

[1] D. E. Fuller,et al. Supersonic aerodynamic characteristics of some simplified and complex aircraft configurations which employ highly swept twisted-and-cambered arrow-wing planforms , 1963 .

[2] O. A. Morris,et al. Experimental effects of fuselage camber on longitudinal aerodynamic characteristics of a series of wing-fuselage configurations at a Mach number of 1.41 , 1976 .

[3] H. W. Carlson,et al. Numerical methods for the design and analysis of wings at supersonic speeds , 1974 .

[4] H. W. Carlson,et al. A numerical method for the design of camber surfaces of supersonic wings with arbitrary planforms , 1964 .

[5] Harry W. Carlson,et al. Aerodynamic Characteristics at Mach Number 2.05 of a Series of Highly Swept Arrow Wings Employing Various Degrees of Twist and Camber , 1960 .

[6] R. B. Sorrells,et al. Numerical method for design of minimum-drag supersonic wing camber with constraints on pitching moment and surface deformation , 1972 .

[7] R. J. Mack. A numerical method for evaluation and utilization of supersonic nacelle-wing interference , 1969 .

[8] R. J. Mack,et al. Effects of leading edge sweep angle and design lift coefficient on performance of a modified arrow wing at a design Mach number of 2.6 , 1974 .

[9] J. C. Townsend. The role of finite-difference methods in design and analysis for supersonic cruise , 1976 .