The problem of stability of steady flight of an aircraft flying at high angles of attack subject to finite-amplitude disturbances in pitch is studied using bifurcation theory, taking account of the interactions between the pitching motion and the unsteady flow. The aerodynamic responses to large-amplitude slow oscillations of the aircraft are obtained from that of infinitesimal amplitude case. Increasing the angle of attack past some critical angle for which the damping vanishes, the steady flight becomes unstable and Hopf bifurcation sets in, resulting in a periodic motion. A simple criterion in terms of the aerodynamic coefficients is given for determining the stability of the bifurcating period motion. For supersonic/hypersonic flat plate airfoils the bifurcating periodic motion is found to be unstable. This implies that when the angle of attack is increased past that of neutral damping, there will be drastic changes of the motion of the aircraft from its steady flight condition at the critical angle, including, e.g. hysteresis.
[1]
M. Tobak,et al.
Unsteady Newton-Busemann flow theory. I - Airfoils
,
1981
.
[2]
Raman K. Mehra,et al.
BIFURCATION ANALYSIS OF AIRCRAFT HIGH ANGLE-OF-ATTACK FLIGHT DYNAMICS
,
1980
.
[3]
Wai How Hui,et al.
Supersonic/hypersonic flow past an oscillating flat plate at high angles of attack
,
1978
.
[4]
W. Hui.
Large-amplitude slow oscillation of wedges in inviscid hypersonic and supersonic flows
,
1970
.
[5]
Wai How Hui,et al.
Stability of oscillating wedges and caret wings in hypersonic and supersonic flows.
,
1969
.
[6]
G. Iooss,et al.
Elementary stability and bifurcation theory
,
1980
.
[7]
L. B. Schiff,et al.
On the formulation of the aerodynamic characteristics in aircraft dynamics
,
1976
.
[8]
K. J. Orlik-Rückemann,et al.
Dynamic stability testing of aircraft—needs versus capabilities
,
1975
.