A manned real time simulation of a conceptual vehicle, the stratoplane, was developed to study the problems associated with the flight characteristics of a large, lightweight vehicle. Mathematical models of the aerodynamics, mass properties, and propulsion system were developed in support of the simulation and are presented. The simulation was at first conducted without control augmentation to determine the needs for a control system. The unaugmented flying qualities were dominated by lightly damped dutch roll oscillations. Constant pilot workloads were needed at high altitudes. Control augmentation was studied using basic feedbacks. For the longitudinal axis, flight path angle, and pitch rate feedback were sufficient to damp the phugoid mode and to provide good flying qualities. In the lateral directional axis, bank angle, roll rate, and yaw rate feedbacks were sufficient to provide a safe vehicle with acceptable handling qualities. Intentionally stalling the stratoplane to very high angles of attack (deep stall) was studied as a means of enable safe and rapid descent. It was concluded that the deep stall maneuver is viable for this class of vehicle.
[1]
W J McCroskey,et al.
A critical assessment of wind tunnel results for the NACA 0012 airfoil
,
1987
.
[2]
Alex G. Sim.
Flight characteristics of a modified Schweizer SGS1-36 sailplane at low and very high angles of attack
,
1990
.
[3]
R. T. Whitcomb,et al.
NASA low- and medium-speed airfoil development
,
1979
.
[4]
B. B. Gloss,et al.
Subsonic aerodynamic characteristics of interacting lifting surfaces with separated flow around sharp edges predicted by a vortex-lattice method
,
1975
.
[5]
Charles A. Wagner,et al.
Simulation at Dryden Flight Research Facility from 1957 to 1982
,
1989
.
[6]
S. Miley,et al.
Catalog of low-Reynolds-number airfoil data for wind-turbine applications
,
1982
.
[7]
T. Teichmann,et al.
Dynamics of Flight: Stability and Control
,
1959
.