Add to ORKGThe method of integral relations is applied in a one-strip approximation to the perturbation equations governing small motions of an inclined, sharp-edged, flat surface about the mean supersonic steady flow. Algebraic expressions for low reduced-frequency aerodynamics are obtained and a set of ordinary differential equations are obtained for general oscillatory motion. Results are presented for low reduced-frequency aerodynamics and for the variation of the unsteady forces with frequency. The method gives accurate results for the aerodynamic forces at low reduced frequency which are in good agreement with available experimental data. However, for cases in which the aerodynamic forces vary rapidly with frequency, the results are qualitativel...
Integral relations method applied to supersonic nonequilibrium flow past wedges and cone
The paper refers to the solution of the integral equation for the acceleration (or pressure) potenti...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/90736/1/AIAA-2011-6525-438.pd
The method of integral relations is applied in a one-strip approximation to the perturbation equatio...
Several aspects of the oscillating wedge are investigated to evaluate both the resulting trends for ...
Progress in the development of computational methods for steady and unsteady aerodynamics has perenn...
A two-dimensional theory is considered for the unsteady flow disturbances caused by aeroelastic defo...
A generalized solution of the hyperbolic wave equation was further developed to relate the velocity ...
Expressions for calculation of subsonic and supersonic, steady and unsteady aerodynamic forces are d...
Details are given of a numerical solution of the integral equation which relates oscillatory or stea...
A general formulation is presented for the analysis of steady and unsteady, subsonic and supersonic ...
This report contains a new, simple method of calculating the air forces to which thin wings are subj...
This report treats the Kernel function of the integral equation that relates a known or prescribed d...
A Supersonic similitude has been used to obtain stability derivatives in pitch and roll of a delta w...
The analytical development of unsteady supersonic aerodynamic influence coefficients for isolated an...
Integral relations method applied to supersonic nonequilibrium flow past wedges and cone
The paper refers to the solution of the integral equation for the acceleration (or pressure) potenti...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/90736/1/AIAA-2011-6525-438.pd
The method of integral relations is applied in a one-strip approximation to the perturbation equatio...
Several aspects of the oscillating wedge are investigated to evaluate both the resulting trends for ...
Progress in the development of computational methods for steady and unsteady aerodynamics has perenn...
A two-dimensional theory is considered for the unsteady flow disturbances caused by aeroelastic defo...
A generalized solution of the hyperbolic wave equation was further developed to relate the velocity ...
Expressions for calculation of subsonic and supersonic, steady and unsteady aerodynamic forces are d...
Details are given of a numerical solution of the integral equation which relates oscillatory or stea...
A general formulation is presented for the analysis of steady and unsteady, subsonic and supersonic ...
This report contains a new, simple method of calculating the air forces to which thin wings are subj...
This report treats the Kernel function of the integral equation that relates a known or prescribed d...
A Supersonic similitude has been used to obtain stability derivatives in pitch and roll of a delta w...
The analytical development of unsteady supersonic aerodynamic influence coefficients for isolated an...
Integral relations method applied to supersonic nonequilibrium flow past wedges and cone
The paper refers to the solution of the integral equation for the acceleration (or pressure) potenti...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/90736/1/AIAA-2011-6525-438.pd